information asymmetry and residential mortgage …
TRANSCRIPT
The Pennsylvania State University
The Graduate School
The Mary Jean and Frank P. Smeal College of Business
INFORMATION ASYMMETRY AND RESIDENTIAL
MORTGAGE CHOICES
A Dissertation in
Business Administration
by
Xun Bian
Copyright 2011 Xun Bian
Submitted in Partial Fulfillment
of the Requirements
for the Degree of
Doctor of Philosophy
August 2011
The dissertation of Xun Bian was reviewed and approved* by the following:
Brent W. Ambrose
Smeal Professor of Real Estate
Dissertation Advisor
Chair of Committee
Austin J. Jaffe
Chair, Department of Insurance and Real Estate
Philip H. Sieg Professor of Business Administration
Jiro Yoshida
Assistant Professor of Business
N. Edward Coulson
Professor of Economics
*Signatures are on file in the Graduate School
iii
ABSTRACT
When financing real estate properties through a mortgage, borrowers often face a
variety of loan products. During the recent housing bubble the variety of mortgage
products and features proliferated. The recent mortgage foreclosure crisis leads many
commentators to point to the growth in the use of these alternative mortgage features as
being predatory. A number of academic studies provide supporting evidence to this view.
In contrast, economists have long noted that mortgage menus provide an effective
mechanism for reducing the information asymmetry that exists between borrowers and
lenders. This dissertation focuses on the screening mechanisms of mortgage features. One
of the goals is to analyze the welfare implications of allowing for a greater variety of loan
products in the residential mortgage market.
This dissertation also aims to contribute to the existing literature on mortgage
choices by incorporate multiple risk dimensions in a unified framework. Most previous
studies limit their exploration to a single risk dimension, default or prepayment risk.
While examining one risk dimension at a time substantially simplifies the analysis, it also
omits the fact that multiple sources of information asymmetry may be at work in shaping
the mortgage market equilibrium. It is well-known that a mortgage contract contains two
types of risk: default risk and prepayment risk. A single device may possess dual
screening roles.
Chapter 2 of this dissertation illustrates the screening role of prepayment penalty
on default and prepayment risks. It examines the interaction between the two screening
functions of prepayment penalty, and shows that the borrower mobility and default risks
iv
jointly determine the mortgage market equilibrium. In particular, the willingness of a
borrower to accept a prepayment penalty may stem from her low mobility risk and/or
high default risk. The choice of a higher prepayment penalty sends the lender conflicting
signals about the borrower’s mobility versus default risk type; thus rendering the
screening role of prepayment penalty ambiguous. Chapter 3 studies the dual screening
role of mortgage discount points. It shows that there exists a separating equilibrium such
that borrowers with higher (lower) transaction costs pay more (less) discount points to
obtain a lower (higher) interest rate. This theoretical prediction suggests a new screening
function of mortgage points, and it complements the conventional mobility-based theory
that suggests that the choice of discount points is a signal of the borrower’s expected
mobility. Chapter 3 also empirically examines the screening role of discount points from
the lender’s perspective. The empirical results suggest that lenders tend to securitize
loans originated by borrowers with higher transactions cost. Chapter 4 offers a theoretical
model to show that when future income uncertainty is private information, there exists a
separating equilibrium such that borrowers with higher default risk are more likely to
choose mortgage contracts with prepayment penalties. I further test the prediction of my
model using a sample of securitized mortgages that contain loans with and without a
prepayment penalty. I find that the positive correlation between prepayment penalties and
default rates is attributable to information asymmetry.
v
TABLE OF CONTENTS
List of Figures ............................................................................................................. viii
List of Tables ............................................................................................................. ix
Acknowledgements .................................................................................................... x
Chapter 1 Overview of Mortgage Choices under Information Asymmetry ....... 1
Chapter 2 The Dual Screening Role of Prepayment Penalty ................................ 8
Background on Prepayment Penalty ............................................................................ 10
The Model……………………………………………………………………………...13
Equilibrium with Full Information .............................................................................. 21
Equilibrium with Asymmetric Information ................................................................ 24
Heterogeneous Mobility ........................................................................................... 24
Heterogeneous Default Risk ..................................................................................... 27
Heterogeneous Mobility and Default Risk ............................................................... 29
Pooling Equilibrium ......................................................................................... 30
Separating Equilibrium .................................................................................... 38
Discussion and Implications .......................................................................................... 40
Chapter 3 The Screening Role of Mortgage Discount Points on Transactions
Costs .......................................................................................................................... 50
Related Literature .......................................................................................................... 54
The Model ....................................................................................................................... 58
Hypothesis Development ............................................................................................... 67
Empirical Analysis ......................................................................................................... 72
Data ......................................................................................................................... 72
vi
Excess Yield Spread and Prepayment ..................................................................... 73
Mortgage Points, Excess Yield Spread, and Securitization Decisions .................... 83
Summary of Findings ..................................................................................................... 84
Chapter 4 Bad Borrowers or Bad Loans: The Effect of Information
Asymmetry on the Choice of Prepayment Penalty ................................................ 91
Literature Review .......................................................................................................... 95
Prepayment Penalty and Subprime Lending ........................................................... 95
Mortgage Choice under Information Asymmetry ................................................... 98
Empirical Tests of Adverse Selection ...................................................................... 99
The Model ....................................................................................................................... 101
The Setup ................................................................................................................. 101
Zero-Profit Contracts ............................................................................................... 102
Borrower’s Problem ................................................................................................. 105
Equilibrium with Full Information .......................................................................... 108
Equilibrium with Asymmetric Informtion .............................................................. 109
Does Prohibiting Prepayment Penalties Benefit or Hurt Borrowers? ...................... 112
Empirical Analysis .................................................................................................... 114
Hypothesis ................................................................................................................ 114
Data ......................................................................................................................... 115
Methodology ............................................................................................................ 117
Competing-Risks Hazard Model ....................................................................... 117
Bivariate Probit Model ..................................................................................... 119
Sampling ........................................................................................................... 120
Variables Related to Default and Prepayment Options ................................... 121
vii
Variables Related to Borrower and Loan Characteristics ............................... 122
Results ............................................................................................................................. 125
Results of the Competing-Risks Hazard Model ....................................................... 125
Results of the Bivariate-Probit Model ..................................................................... 127
Summary of Findings ..................................................................................................... 129
Chapter 5 Concluding Remarks .............................................................................. 145
Bibliography ............................................................................................................... 149
Appendix A Proofs of Propositions in Chapter 2 ................................................... 156
Appendix B Proofs of Proposition 1 in Chapter 4 ................................................. 171
viii
LIST OF FIGURES
Figure 2.1: Heterogeneous Mobility. ...................................................................................... 44
Figure 2.2: Heterogeneous Default Risk. ................................................................................ 45
Figure 2.3: Heterogeneous Mobility and Default Risk (Pooling Equilibria: Scenario 1) ....... 46
Figure 2.4: Heterogeneous Mobility and Default Risk (Pooling Equilibria: Scenario 2) ....... 47
Figure 2.5: Heterogeneous Mobility and Default Risk (Separating Equilibria: Scenario 1) .. 48
Figure 2.6: Heterogeneous Mobility and Default Risk (Separating Equilibria: Scenario 2) .. 49
Figure 3.1: Mortgage-Points Choice with Asymmetric Information ...................................... 86
Figure 4.1: Separating Equilibrium with Zero Lending Profit ................................................ 131
Figure 4.2: Subsample Construction ....................................................................................... 132
ix
LIST OF TABLES
Table 2.1: Aggregate Effects of Mobility and Default............................................................ 50
Table 3.1: Descriptive Statistics (Chapter 3). ......................................................................... 87
Table 3.2: Estimation of Excess Yield Spread. ....................................................................... 88
Table 3.3: Comprting-Risks Hazard Model of Mortgage Termination Outcomes. ................ 89
Table 3.4: Mortgage Points, Excess Yield Spread, and Securitization Decisions. ................. 91
Table 4.1: Descriptive Statistics (Chapter 4). ......................................................................... 133
Table 4.2: Definition of Variables. ......................................................................................... 134
Table 4.3: Estimation Results of the First-Stage Logit Model. ............................................... 135
Table 4.4: Results of Competing-Risk Hazard Model Using the Full Sample. ...................... 136
Table 4.5: Results of Competing-Risk Hazard Model Using Subsamples 1.1 and 1.2. .......... 138
Table 4.6: Results of Competing-Risk Hazard Model Using Subsamples 2.1 and 2.2. .......... 140
Table 4.7: Results of Competing-Risk Hazard Model Using Subsamples 3.1 and 3.2. .......... 142
Table 4.8: Results of Bivariate-Probit Models. ....................................................................... 144
x
ACKNOWLEDGEMENTS
First, I would like to express my most sincere gratitude to my adviser, Professor
Brent Ambrose, who has been an exceptional mentor. He has inspired me from the
beginning with his enthusiasm for real estate research. Throughout my study in the past
several years, he gave me invaluable guidance, advice and encouragement. Without his
support, this dissertation would have been impossible.
Second, I want to thank my dissertation committee members: Professor Austin
Jaffe, Professor Ed Coulson and Professor Jiro Yoshida. Their careful reading,
constructive criticism and valuable comments greatly improved this dissertation. I also
want to thank Professor Abdullah Yavas, from whom I built my theoretical modeling
skills. My thanks also go to Professor Michael LaCour-Little, who generously provided
access to the dataset used in Chapter 3 of this dissertation. In addition, his helpful
comments significantly improved my work.
My special thanks are dedicated to my parents, Bian Bian and Heqing Huang.
Their love supported me in every stage of my life. Without them, none of my
achievements would have been possible. I also want to thank my wife Jun Zhang. Her
unconditional support and love makes me a happier person.
1
Chapter 1
Overview of Mortgage Choices under Information Asymmetry
When financing real estate properties through a mortgage, borrowers often face a
variety of loan products. Available mortgage choices include interest rate adjustment
methods (e.g. fixed rate or variable rate), time to maturity, discount points, and
prepayment penalties, among many others. During the recent housing bubble the variety
of mortgage products and features proliferated. For example, instead of offering a simple
choice of fixed-rate (FRMs) or adjustable-rate mortgages (ARMs), lenders began offering
alternative products such as interest-only mortgages (IO mortgages) and hybrid option
adjustable rate mortgages (option ARMs) that often have a variety of adjustable-rate
features and/or negative amortization. Whether the growing variety of mortgage features
has had an effect on consumer welfare is quite controversial. The recent mortgage
foreclosure crisis leads many commentators to point to the growth in the use of these
alternative features as being predatory. A number of academic studies provide supporting
evidence to this view. Complicated loan features may be strategically applied by lenders
to preserve their market power through increasing consumer confusion (Carlin, 2009). In
addition, Bond, Musto, and Yilmaz (2009) suggest that predatory lending tend to be
associated with features such as prepayment penalties and balloon payments.
In contrast, economists have long noted that mortgage menus provide an effective
mechanism for reducing the information asymmetry that exists between borrowers and
lenders. The diverse mortgage choices faced by consumers is functionally similar to the
coverage-price choices commonly observed in the insurance market. Rothschild and
2
Stiglitz (1974) illustrate that the empirically observed positive correlation between
insurance coverage and risk occurrence is attributable to adverse selection. When
information asymmetry is present, allowing for diverse choices is efficiency-enhancing
because an agent’s choice can convey private information. In light of the current financial
crisis, understanding the screening functions of various mortgage contract instruments
becomes particularly important. For example, are massive mortgage defaults exacerbated
by the increasing variety of unfair contracts? Or, do borrowers with greater expected
default risk simply prefer those mortgage features that became available in recent years?
The answers to these questions have important welfare and policy implications. This
dissertation focuses on the screening mechanisms contained in mortgage instruments.
Thus, one of the goals of this dissertation is to analyze the welfare implications of
allowing for a greater variety of loan products in the residential mortgage market.
Studies examining the screening function of mortgage instruments usually assume
that borrowers select among different mortgage products based on their risk profiles to
maximize expected utility. A borrower’s mortgage choice may reveal private information
about her risk type. Thus, lenders can design and offer different mortgage products as a
screening mechanism to separate borrowers of different risk types. Screening devices that
have been extensively studied in mortgage literature include the loan-to-value (LTV)
ratio (Brueckner, 2000, Harrison, Noordewier, and Yavas, 2004), adjustable-rate
mortgage (ARM) versus fixed rate mortgage (FRM) contracts (Brueckner, 1992, Posey
and Yavas, 2000), mortgage points (Brueckner, 1994, Stanton and Wallace 1998) and
prepayment penalty (Brueckner, 1994). This line of research often applies the Rothschild
3
and Stiglitz framework (1976) and shows that a separating equilibrium may be obtained
through borrowers’ self-selection.
This dissertation also aims to contribute to the existing literature on mortgage
choices. Most previous studies limit their exploration to a single risk dimension, default
or prepayment risk. Screening devices concerning default risk include loan-to-value
(LTV) ratio, contract types (FRM versus ARM) and mortgage duration. For example
Bruckner (2000) points out that when the cost of default (e.g. damage to one’s credit
history) is private information and heterogeneous across borrowers, low-cost borrowers
tend to select high LTV loans and pay a price premium (e.g. private mortgage insurance).
Subsequently, those borrowers are more likely to default on their loan. Harrison et al.
(2004) further emphasize the important role of default costs in determining the screening
role of LTV ratios. In their model, information asymmetry comes from expected future
income. The authors show that the correlation between greater default risk and high LTV
choice holds only when the cost of default is relatively modest. In contrast, when default
cost is high, a high-default-risk borrower will select a low LTV loan to avoid the adverse
consequence from default. In addition, the choice between ARM and FRM contracts may
also serve as a screening mechanism of default risk. Posey and Yavas (2000) show that
borrowers with low (high) expected future income tend to select the ARM (FRM)
contract.
On the other hand, choices about mortgage discount points and prepayment
penalty are traditionally considered to convey private information on borrower’s
prepayment risk (mobility). Dunn and McConnell (1981) first suggested that mortgage
points serve as a back-door prepayment penalty for the lender to charge for the embedded
4
prepayment option. In contrast, Kau and Keenan (1987) pointed out that tax
considerations may play a crucial role in determining points paid on purchase loans.1
Because discount points on purchase mortgage may be deducted all at once at origination
while the interest rate deduction is spread across the life of the loan, borrowers with high
marginal tax rates are more willing to pay points in order to receive a low interest rate.
While examining one risk dimension at a time substantially simplifies the
analysis, it also omits the fact that multiple sources of information asymmetry may be at
work in shaping the mortgage market equilibrium. It is well-known that a mortgage
contract contains two types of risk: default risk and prepayment risk. A single device may
possess dual screening roles. For instance, the choice of contract types, FRM versus
ARM, may reflect the borrower’s self-selection based on both mobility (Brueckner,
1992) and default risk (Posey and Yavas, 2001). Therefore, to fully understand borrower
mortgage choices, it is necessary to incorporate multiple screening functions
simultaneously into a unified framework. This dissertation fills this gap by exploring the
multiple screening functions of mortgage instruments. In each of the following three
chapters, more than one type of risk is considered. Collectively, the dissertation answers
two important questions. First, how do multiple sources of information asymmetry
interact with each other and jointly determine a borrower’s mortgage choice? Second, if
one screening mechanism possesses a multi-dimensional screening role, how do lenders
interpret the realized mortgage choices?
1 Points paid for purchase loan are deducted at the year of origination; points paid for refinance loan are
amortized over the life of the loan.
5
Chapter 2 illustrates the screening role of prepayment penalty on default and
prepayment risks. The screening function of prepayment penalty on default risk has been
largely ignored by previous studies. The study shows that borrowers with higher default
risk are more willing to accept prepayment penalty in exchange for a lower interest rate.
It then examines the interaction between the two screening functions of the prepayment
penalty, and shows that the borrower mobility and default risk jointly determine the
mortgage market equilibrium. In particular, the willingness of a borrower to accept
prepayment penalty may stem from her low mobility risk and/or high default risk. The
choice of a higher prepayment penalty sends the lender conflicting signals about the
borrower’s mobility versus default risk type; thus rendering the screening role of
prepayment penalty ambiguous. As a result, for certain parameter combinations, the
model also generates a pooling equilibrium where all borrower types obtain the same
contract.
Chapter 3 focuses on the dual screening role of mortgage discount points. It
proposes to show that there exists a separating equilibrium such that borrowers with
higher (lower) transaction costs pay more (less) discount points to obtain a lower (higher)
interest rate. This equilibrium is also characterized by the low-cost (higher prepayment
risk) borrower imposing a negative externality on the high-cost (lower prepayment risk)
borrower. The proposed study suggests a new screening function of mortgage points, and
it complements the conventional mobility-based theory that suggests that discount points
are a signal of the borrower’s expected mobility. Given this potential dual screening role,
it remains unclear that how lenders interpret the signals generated from realized points-
coupon choices. Thus, in contrast to previous studies that focus solely on the borrower’s
6
choice, the study empirically examines the screening role of discount points from the
lender’s perspective. The empirical results suggest that lenders are more likely to
securitize loans originated by borrowers with high cost of refinance.
Chapter 4 studies the correlation between default and prepayment risk in a
screening framework. Borrowers with different risk profiles exhibit distinct preferences
for prepayment penalties. This heterogeneity can emerge from the link between default
and prepayment risks established by common residential mortgage underwriting practice.
Typically, income level is used as one of the important criteria in residential mortgage
underwriting for determining a borrower’s qualification. However, an often overlooked
fact is that income level is also a crucial determinant of prepayment probability. A
borrower considering refinancing must qualify for a new loan first (Archer, Ling, and
McGill, 1996). Although a borrower may wish to refinance when the prepayment option
is sufficiently in the money, his ability to do so may be impeded by insufficient income.
Thus, compromised financial strength not only may trigger default but also increase the
probability that a borrower is ineligible for a new loan. When facing the penalty-coupon
trade-off, borrowers with a greater probability of experiencing future income reduction
(high-risk borrowers) would rationally choose to have prepayment penalties in their
contracts. The intuition behind this separation is that with a higher chance of being
ineligible for a new loan, the willingness to pay an interest rate premium to maintain an
unconstrained prepayment option is reduced. I first construct a theoretical model to
illustrate this intuition. I show that when future income uncertainty is private information,
there exists a separating equilibrium such that borrowers with higher default risk are
more likely to choose mortgage contracts with prepayment penalties.
7
I test the prediction of my model using a sample of securitized mortgages that
contain loans with and without a prepayment penalty. In my sample, all prepayment
penalties expire within a relatively short period of time (e.g. 1, 2, or 3 years). I find that
the positive correlation between prepayment penalties and default rates is attributable to
information asymmetry. The option-based mortgage pricing literature suggests that the
values of the prepayment option and default options are jointly determined. To eliminate
the confounding effect that prepayment penalties may increase default risk through
limiting the value of prepayment option, I examine mortgages that survive beyond the
prepayment penalties’ expiration dates. Variation on mortgage terminations after the
expiration dates are unlikely to be affected by the prepayment penalty. I then compare the
termination outcomes between loans with and without a prior prepayment penalty. I find
that loans that had a prior prepayment penalty continue to default at a higher rate even
after their prepayment penalties expired.
8
Chapter 2
The Dual Screening Role of Prepayment Penalty2
What makes the role of prepayment penalty interesting and more complicated is
that, while high-default-risk borrowers would prefer a contract with a high prepayment
penalty and a low interest rate, high-mobility borrowers would prefer a contract with a
low prepayment penalty and a high interest rate. Thus, a borrower’s contract choice could
send conflicting signals to the lender about her default and prepayment risk type.
Conventional wisdom considers adding a prepayment penalty to a mortgage
contract as a way to separate borrowers based on their expected mobility. Borrowers with
higher (lower) probability of moving would be less (more) willing to exchange
prepayment penalty for a lower interest rate (Brueckner, 1994). Another screening
instrument is mortgage points, which is the upfront fee paid by borrowers at the time of
loan origination. Previous studies on mortgage points include those by Dunn and Spatt
(1985), Chari and Jagannathan (1989), Yang (1992), Brueckner (1994), LeRoy (1996),
Stanton and Wallace (1998), and Chang and Yavas (2009). In general, borrowers who
expect to prepay soon would avoid paying points, and only borrowers with limited
prepayment risk are willing to exchange upfront points for a lower interest rate. A related
and important question is that, if both prepayment penalty and mortgage points can be
used to screen borrower mobility, why is it that the prepayment penalty is used so much
less than mortgage points? In fact, Chari and Jagannathan (1986) suggest that prepayment
2 This chapter is derived from a co-authored paper with Abdullah Yavas entitled ―Prepayment Penalty as a
screening mechanism for default and prepayment risks‖.
9
penalty and mortgage points are perfect substitutes. Brueckner (1994) qualifies this
argument by pointing out the differential welfare effects of prepayment penalty verses
mortgage points. Specifically, the introduction of prepayment penalty can either increase
or decrease welfare. Chapter 2 provides another possible explanation to the limited use of
prepayment penalty by pointing out the conflicting signaling roles of the prepayment
penalty with respect to the mobility versus default risk. The choice of points signals both
a lower mobility risk and a lower default risk. As a result, prepayment penalty is a less
effective screening mechanism than mortgage points.
A single device may possess dual screening roles. For instance, Brueckner (1992)
shows that the choice of contract types—FRM or ARM—reflects the borrower’s self-
selection based on mobility. Specifically, more mobile borrowers favor ARM, and less
mobile borrowers select FRM. Posey and Yavas (2001) suggest that the ARM-or-FRM
choice also may serve as a screening device of default risk. When the default cost is large
enough, borrowers with high (low) probability of income reduction are more likely to
choose ARM (FRM). Collectively, these studies suggest that to fully understand
borrower mortgage choices, it is necessary to incorporate multiple screening functions
simultaneously into a unified framework. Chapter 2 fills this gap by first illustrating the
screening role of prepayment penalty on default risk, which has been largely ignored by
previous studies. I show that borrowers with high default risk are more willing to accept a
prepayment penalty in exchange for a lower interest rate. I then examine the interaction
between the two screening functions of the prepayment penalty. I show that the borrower
mobility and default risk jointly determine the mortgage market equilibrium. In
particular, the willingness of a borrower to accept a prepayment penalty may stem from
10
her low mobility risk and/or high default risk. I establish the conditions under which a
separating equilibrium exists, where borrowers with certain combinations of mobility and
default risks select a mortgage with a prepayment penalty and lower interest rate, and the
remaining borrowers choose a mortgage without a prepayment penalty and a higher
interest rate. The fact that the choice of a higher prepayment penalty sends the lender
conflicting signals about the borrower’s mobility versus default risk type might render the
screening role of prepayment penalty ambiguous. As a result, for certain parameter
combinations, the model also generates a pooling equilibrium where all borrower types
obtain the same contract.
Background on Prepayment Penalty
Prepayment penalty is a charge that a lender makes when a borrower repays part
of or the entire mortgage balance before a certain period of time. Lenders often permit
partial prepayments of up to 20 percent of the mortgage balance in any one year without a
penalty. As is the case with discount points, a prepayment penalty helps the lender recoup
some or all of the expenses associated with putting a loan together, and a contract with a
prepayment penalty has a lower mortgage rate than a contract without one. Unlike points,
which become sunk costs once incurred, a prepayment penalty helps the lender
discourage prepayment and avoid realizing significant losses due to a drop in interest
rates.
Almost every commercial mortgage loan includes a prepayment penalty. The
traditional prepayment penalty is the declining balance, where the penalty is a percentage
of the loan amount, and this percentage declines over time. Another form of prepayment
11
penalty for commercial mortgage loans is yield maintenance, whereby the borrower is
required to make up the difference between the amount of interest that would be earned if
the loan were carried to maturity and the amount of interest that would be earned if the
lender reinvested the prepaid amount in U.S. Treasury securities of the same term.
According to a third type of prepayment penalty—a defeasance clause—the borrower is
required to provide the lender with Treasury securities that yield the same stream of
interest payments and the same balloon payment as the original mortgage. Prepayment
penalties on commercial mortgages may also involve a lockout period during which
prepayment is not allowed under any circumstances. The typical prepayment penalty on
residential loans is a fixed percentage of the loan balance at the time of prepayment if the
loan is prepaid within the first three to five years—although, in some cases, the
percentage amount decreases with time.
Prepayment penalties also exist in residential mortgages. In fact, the majority of
subprime mortgages contain prepayment penalties. According to Standard & Poor’s
(2004), approximately 80 percent of subprime loans contained prepayment penalties as of
2000. The substantial use of prepayment penalty is confirmed by Elliehausen, Staten, and
Steinbuks (2008) and LaCour-Little and Holmes (2008), who respectively reported that
about 60 percent and 90 percent of their subprime loan samples contained a prepayment
penalty.
Although prepayment penalties are much more common on subprime mortgages,
they also exist on prime mortgages. According to the online edition of the Wall Street
12
Journal,3 borrowers generally obtain a reduction in the interest rate of about one-eighth to
three-eighths of a point in return for accepting the prepayment penalty. According to the
same article, seventy percent of the mortgage customers of World Savings Bank in
Oakland, California, opt for a loan with a prepayment penalty, and such major lenders as
Bank of America, Countrywide, and Washington Mutual have prepayment penalties on
some of their prime mortgage loans. In recent years, the proportion of prime loans
containing prepayment penalties have declined significantly, in part because of loan
purchasing standards set by housing Government Sponsored Enterprises (Fannie Mae and
Freddie Mac) and legislative efforts restricting the use prepayment penalties.
The penalty can be applied to prepayment due to a home sale as well as
refinancing, although the latter is more common than the former. Most often, the
prepayment penalty is ―hard,‖ meaning that it is applied whether the borrower refinances
or sells the home. Sometimes, the prepayment penalty is ―soft,‖ meaning that it is applied
only when the borrower refinances.
Whether the lender can charge a prepayment penalty if the lender forces the
borrower to prepay upon the sale of the property as the result of the borrower’s violation
of the due-on-sale provision is a frequently litigated issue with residential mortgages. In
McCausland v. Bankers Life Ins. Co. (Wash. 1988), the court held that the lender should
not be allowed to charge a prepayment penalty upon the sale of the property, because it is
the lender who is requiring the prepayment of the loan. In Eyde v. Empire of America
Fed. Sav. Bank (Mich. 1988), the court held that it was irrelevant why the loan was
prepaid, because the intent of the parties in signing the contract was that the lender had
3 See http://www.realestatejournal.com/buysell/mortgages/20011218-simon.html
13
the right to collect prepayment penalty regardless of the reason for prepayment.4 Even
though federal regulators do not prohibit prepayment penalties, many states restrict the
use of prepayment penalties by state-chartered lenders. Federally chartered lenders in
those states can still charge prepayment penalties if they are adequately disclosed.
The Model
Consider a competitive lending market in which lenders offer a menu of fixed-rate
mortgage contracts with different combinations of interest rate i and prepayment penalty
s. All mortgages mature in three periods. In the first period, a borrower obtains a
mortgage with an outstanding balance of L to purchase a property with a value of P . For
the sake of simplicity, I follow Brueckner (1992) and Posey and Yavas (2001) to assume
that all loans are interest-only loans with a loan-to-value ratio of 100 percent. This
assumption implies that LP . Each borrower has an identical initial income 0y , which
qualifies a borrower for all mortgage contracts available in the menu. A random event,
which determines whether a borrower has to move, occurs in the second period. Each
borrower has a probability of 1 to relocate. A borrower does not sell her property
unless she has to relocate. I assume income uncertainty is associated with moving. If a
borrower moves, her income changes to y, which is a random variable distributed
between y and y according to a density function )( f . This variation of income captures a
4 For a more detailed discussion of these cthet cases, see dirt.umkc.edu/files/prepay.htm
14
borrower’s uncertain job prospects at the new location.5 On the other hand, if relocation
does not occur, the borrower’s second-period income remains at the same level as the
initial income 0y . I also model housing price uncertainty by assuming that there is a
probability of such that property price decreases from P to dP and triggers default in
the second period. For simplification, I assume neither relocation nor property price
change occur in the third period. Both the borrower and the lender are assumed to be risk
neutral.6
First, I examine the borrower’s objective function. It is worth emphasizing that
there exist two sources of default. First, default may be caused by a decline in property
value. Second, default can occur even with constant property price; since relocation
induces income uncertainty, default happens when the second-period income level y is
insufficient to cover the prepayment penalty s plus the interest payment i.7 Hence, the
expected utility for a borrower choosing a contract with interest rate i and prepayment
penalty s, ),( si , is
5 A borrower may lose her job and be forced to take an inferior position at a different location. In this case,
the realized value of y would be lower than y0. On the other hand, relocation may be driven by better job
opportunities and, therefore, is associated with y greater than y0.
6 I avoid prepayments driven by refinancing by assuming a constant interest rate. Allowing the possibility
of refinancing would make the model extremely difficult to track. Instead, I capture the prepayment risk for
the lender by capturing the damage to the lender’s cash flows caused by a possible drop in the borrower’s
income stream due to relocation.
7 Because property value is always equal to the loan balance, the borrower can avoid default by selling the
property in the absence of any prepayment penalty.
15
.))(1)(1(
)()()1(
)()()1(
))(1(
)()()(),(
2
1
0
0
0
j
j
y
is
is
y
y
y
hiy
dyyfisy
dyyfDy
Dy
dyyfDyhiPLysiU
(2.1)
All borrowers have an inter-temporal discount factor . The first term indicates
that a borrower obtains a loan with an outstanding balance of L to purchase a property
with a value of P. With an initial income 0y , the borrower is able to make the first
period’s interest payment i . In return, the borrower receives positive utility h from
housing services. Given the assumption that PL , the first term simplifies to
)( 0 hiy . A number of possible outcomes may occur in the second period. A drop in
property price from P to dP would cause a borrower to default regardless of whether the
borrower is moving. Default imposes a cost D on the borrower (second term and third
term). D represents non-monetary costs such as damage to the borrower’s credit history
and reputation as well as transaction, social, and psychological costs of default. Three
other possible outcomes can occur provided the property value stays at P. The borrower
has a probability of to move and incur the prepayment penalty s. Relocation results in a
change in income and hence may trigger one of two events: default or prepayment.
Default occurs if the realized income y is less than prepayment penalty s plus the interest
payment i (fourth term). On the other hand, if y is greater than s+i, the borrower is able to
avoid default (fifth term). With a probability of 1 , the borrower does not move and
16
holds the loan to maturity. In this case, her income level remains at 0y , she makes interest
payment i and receives the ownership benefit h in both period 2 and 3 (sixth term). The
loan balance is omitted from the loan termination outcomes, because (1) if the property
price drops to dP or the second-period income drops below s+i, the borrower loses the
property to the lender, and (2) if the property value remains at P=L, then P is used to pay
off the loan balance.
A couple of restrictions on the values of s and i are crucial. First, I need to ensure
that when the borrower moves, she does not choose default over prepayment in order to
avoid the prepayment penalty. For this, I will assume D is large enough so that:
Assumption 1: s+i < D.
Otherwise, a borrower is better off to always default when moving occurs.
Second, I assume that the values of y and y are such that s+i falls between y
and y . If s+i is greater than y , the borrower can never afford s+i, and hence only
default can occur upon moving. Similarly, if s+i is less than y , a borrower can always
afford to incur prepayment penalty, and hence a drop in her income would never lead to
default.
Assumption 2: yyis , .
17
This assumption ensures that both default and prepayment can occur when a
borrower moves, depending on the realization of the borrower’s second-period income.
The decision to own a house is rational only if the periodic ownership
benefit h is greater than the periodic interest payment i . For this reason, I assume h to be
large enough so that the following constraint always holds:
Assumption 3: ih .
Assumption 3 implies that the borrower would not want to give up the ownership
benefit by prepaying in the second period when she does not need to move.
All lenders have a discount rate of . I assume that lenders are more patient than
borrowers, . With risk neutrality, the lender’s objective is to maximize the expected
profits:
).)(1)(1(
)1)(1(
)()()1(
)()()1(
)()(),(
2 iL
i
dyyfisL
dyyfcP
cPiLsi
y
is
is
y
d
(2.2)
In the first period, the lender transfers the loan amount L to the borrower and
collects interest payment i (first term). If the property price declines, default occurs
regardless of whether relocation happens. The lender forecloses the property and sells it
18
for its decreased value dP and incurs the foreclosure cost of c (second term).8 If the
property value stays at P, three possible outcomes can take place. First, if the borrower
moves and the realized income of the borrower turns out to be lower than s+i, default
occurs. The lender forecloses the property and collects cP (third term). Second, if
relocation is accompanied with high income (greater than s+i), the borrower prepays. In
addition to receiving the loan amount L, The lender also collects the prepayment penalty
s and the interest payment i (fourth term). Third, if there is no relocation, the lender
receives the interest payment i in the second period and is repaid with the loan amount L
plus the earned interest i when the mortgage matures in the third period (fifth and sixth
terms).
To characterize the competitive market equilibrium, I first examine the
indifference curve of the borrower and the iso-profit curve of the lender. These curves
respectively describe the borrower’s and lender’s trade-off between prepayment penalty s
and contract rate i . To derive the slope of the borrower’s indifference curve, I implicitly
differentiate s with respect to i holding ),( siU constant. This gives us the marginal rate of
substitution between s and i .
8 Lenders incur foreclosure costs due to 1) legal costs associated with the foreclosure process, 2) negative
publicity and damage to reputation, and 3) depreciated property value. Campbell, Giglio, and Pathak (2009)
find that foreclosed properties are sold at a substantial discount as opposed to their fair market value. I
capture these costs in c.
19
.
)()()()1(
)1)(1()()()()1(12
1
y
is
j
jy
is
s
iU
dyyfisfDis
dyyfisfDis
U
U
i
sMRS
(2.3)
The numerator is positive, and the denominator is negative since is is strictly
less than D. Hence, indifference curves are downward sloping. This indicates that the
borrower’s disutility as a result of accepting greater prepayment penalty must be
compensated through a lower interest rate in order for the borrower to remain on the
same indifference curve.
To derive the slope of the lender’s iso-profit curves, s is implicitly differentiated
with respect to i holding profit constant. The slope is given by
.
)()()()1(
)1)(1()()()()1(12
1
y
is
j
jy
is
s
i
isfcisdyyf
isfcisdyyf
i
sMRS
(2.4)
Following Brueckner (2000) and Harrison et al. (2004), I simplify the analysis by
assuming uniform density for the distribution of income contingent on moving. With this
assumption, the slope of the borrower’s indifference curve and the lender’s iso-profit
curve can be obtained by substituting the uniform density function for )( f into equations
(2.3) and (2.4). It follows that
20
,1
)22)(1(
)1)(1(12
1
yDis
yy
MRSj
j
U
(2.5)
.1
)22)(1(
)1)(1(12
1
ycis
yy
MRSj
j
(2.6)
Note that the indifference curves and iso-profit curves are convex, because
assumptions 1 and 2 yield 0/ sMRSU and 0/ sMRS ; that is, as s increases,
the indifference curves and iso-profit curves become steeper (more negative).9 Both low
interest rate and low prepayment penalty are desirable from a borrower’s perspective.
Thus, indifference curves located on the lower left-hand side correspond to higher utility.
Aligned with this intuition, I have both marginal utilities, sU and iU , less than zero. In
order for an equilibrium to exist, zero-profit curves need to be downward sloping and
have a tangency point with the borrower indifference curves. That is, MRSMRSU has
a solution ),( ** si . This implies that the following must be true in equilibrium:
2/)( cyis .10
Before analyzing the mortgage market equilibrium under asymmetric information,
it is useful to first consider the equilibrium with homogeneous borrowers. When all
borrowers are identical, the equilibrium mortgage contract must lie on the zero-profit
9 Strict convexity of indifference and zero-profit curves ensure that the indifference curve of a borrower
type cannot be tangent to the zero-profit curve from below for that type at more than one point.
10 UMRS is strictly negative, and the numerator in the first term of MRS is strictly positive.
MRSMRSU implies that the denominator in the first term of MRS must be strictly negative.
Simplification yields 2/)( cyis .
21
line, defined by 0),( si . The borrower’s utility is greater on lower indifference curves
(lower penalty and lower interest rate). Thus, the point where the lowest indifference
curve is tangent to the zero-profit curve gives the equilibrium contract. The optimality
requires the zero-profit curves to be more convex than the indifference curves.11
This
requirement is satisfied with )( f being uniform.
Now that I have derived the properties of indifference curves and zero-profit
curves, I can characterize the mortgage market equilibrium. I define equilibrium as a set
of mortgage contracts such that (1) each borrower chooses the contract that maximizes
her expected utility, and (2) lenders earn nonnegative profit and have no incentive to
offer contracts outside the equilibrium set. I first consider the equilibrium under full
information.
Equilibrium with Full Information
Suppose there exist two types of borrowers—type A and type B—which are
different in mobility, , and/or default risk y . I characterize the heterogeneity of income
uncertainty using different levels of the lower bound of second-period income y .12
With
second-period income being uniformly distributed, a lower y implies a greater
probability of y falling below s+i. In other words, borrowers with lower (higher) y are
11 The slope difference between zero-profit lines and indifference curves is negative (positive) when s is
less (greater) than s*, where s* is the s value at the tangency point of the zero-profit and indifference
curves. It indicates that the zero-profit curve is flatter than the indifference curve for s < s* and steeper for
s > s*.
12 One could alternatively model the heterogeneity of default risk by having borrowers differ with respect to
y . The results are similar.
22
more (less) likely to default. The mobility-default combinations of type A and type B
borrowers are respectively ),(AA y and ),(
BB y . The full information assumption
implies that borrower types are known to the lender. The first-best contracts are those that
maximize utility for each borrower type while ensuring nonnegative lender profit. The
lender’s problem is simple. Because lenders can observe each borrower’s risk type and
because the mortgage market is competitive, each lender in equilibrium offers the
combinations of prepayment penalty and interest rate that earn zero profit for each
borrower type. These contracts can be obtained by substituting ),(AA y and ),(
BB y ,
respectively, into equations (2.1) and (2.2). For each type of borrower, the point where
the lowest indifference curve is tangent to the zero-profit curve yields the equilibrium
contract.
To illustrate, consider the cases when borrowers are heterogeneous only in one
risk dimension—mobility or default risk. Figure 1 illustrates the full information
equilibrium contract when the borrowers differ with respect to mobility risk only.
Mobility affects the relative positions of the zero-profit curves for the two borrower
groups. The difference in heights of the lender’s zero-profit curves can be obtained by
setting equation (2.2) to zero and differentiating s with respect to , which yields
s / . Because 0 s
13, this derivative is positive if 0 and negative if
0 . While is mathematically ambiguous in sign, I restrict the attention to the
13 As established earlier, 2/)( cyis is necessary for the equilibrium requirement that zero-profit
curves are downward sloping and has a tangency point with a borrower’s indifference curve. This yields
.0)22)(1( yciss
23
case that 0 to later study the interesting dynamics of mobility risk and default
having opposite effects on borrower’s preference.14
Intuitively, 0 implies that the
high-mobility borrower’s zero-profit curve is above the low-mobility borrower’s zero-
profit curve, which in turn implies that serving the high-mobility borrower is less
profitable from lender’s perspective for any given ),( si . To be more precise, I only
consider the markets where the following condition is satisfied.
yy
yyiPiisyisPyiscP
)()())(())(()1( < 0 .
(2.7)
A high enough foreclosure cost for the lender, c, for instance, will suffice to meet this
condition. The first-best contracts are shown in figure 2.1 as ),( ** hh si for the high-
mobility type and ),( ** ll si for the low-mobility type.
Figure 2.2 illustrates the full information equilibrium when the borrowers differ
with respect to default risk only. I examine the difference in heights of the lender’s zero-
profit curves between the two risk types by setting equation (2.2) to zero and
differentiating s with respect to y , which yields sy / . Because y is strictly less than
zero, this derivative is negative since the zero-profit curves are downward sloping
)0( s . It implies that the low-default-cost borrower’s zero-profit curve is located in
the lower left-hand side of the high-default-cost borrower’s zero-profit curve. The first-
14 If 0 , higher mobility corresponds to lower risk. In this case, mobility risk and default risk will
work in the same direction in affecting the borrower’s preference. Both lower mobility (higher risk) and
higher default probability will provide incentive for borrowers to accept a prepayment penalty.
24
best contracts are shown in figure 2.2 as ),( ** hh si for the high-default type and ),( ** ll si
for the low-default type.
However, the first-best contracts are often not feasible for two reasons. First,
lenders usually do not possess the information necessary to identify borrower types,
because mobility and default likelihood are private information. Second, even if lenders
can correctly infer a borrower’s type using observed borrower characteristics (e.g., age,
gender, etc.), legal restrictions against lending discrimination may prevent a lender from
imposing different contracts based on those borrower characteristics. Hence, the lender
must allow the borrower to choose among the set of offered contracts. If the lender were
to offer the two first-best contracts in the case shown in Figure 1, high-mobility
borrowers would prefer low-mobility borrowers’ first-best contract ),( ** ll si , which lies
on the southwest side of ),( ** hh si , to their own first-best contract. If both borrower types
would select the contract ),( ** ll si , the lender earns a negative profit. This outcome is
inconsistent with equilibrium. Thus, first-best contracts cannot be an equilibrium
outcome under asymmetric information.
Equilibrium with Asymmetric Information
I now turn to the dual screening role of prepayment penalty under asymmetric
information. I first hold default risk constant across borrowers and only consider the
prepayment penalty’s screening function on mobility. Then I shift focus on default risk to
examine how the mortgage market equilibrium is shaped when borrowers are
25
heterogeneous in their default risk only. Finally, I examine the case where heterogeneities
of both mobility and default risk are allowed.
Heterogeneous Mobility
I assume that all borrowers are identical in all aspects except for their probability
of moving. Suppose there exist two types of borrowers: borrowers with high mobility and
borrowers with low mobility. The probabilities of relocation are h and l for high- and
low-mobility borrowers, respectively, with hl . It is common knowledge that the
proportions of high-mobility type and low-mobility type borrowers in the population are,
respectively, and 1 . I first focus on the borrower’s indifference curve. In
particular, the relative slope of the indifference curves of the two borrower types is
critical in shaping the equilibrium. Differentiating the slope of the indifference curve with
respect to a borrower’s probability of moving for any given ),( si point yields
.0)22)(1(
)()1(1
2
2
1
isDy
yyMRS j
j
U
(2.8)
Equation (2.8) is strictly positive, since s+i is strictly less than both D and y . As
increases, the slope of the borrower’s indifference curve becomes greater (less
negative). Thus, the low-mobility borrower’s indifference curve passing through a given
),( si point is steeper than the high-mobility borrower’s indifference curve. The steeper
indifference curves of low-mobility borrowers suggest that they are more willing than
high-mobility borrowers to trade a prepayment penalty for a lower interest rate.
26
Proposition 2.1: When borrowers are different only in their mobility, there exists
a separating equilibrium such that low-mobility borrowers obtain loans with greater
prepayment penalty and lower interest rate than high-mobility borrowers.
Proof. See appendix A.
The equilibrium is illustrated in figure 2.1. The high-mobility borrower receives
her first-best contract ),( ** hh si , which corresponds to the tangency point between the
lowest indifference curve and the zero-profit curve for the high-mobility borrower. As I
have discussed previously, the low-mobility borrowers cannot be offered their first-best
contract ),( ** ll si because the lender would incur a loss by offering ),( ** hh si and ),( ** ll si
simultaneously. To satisfy the incentive compatibility constraint, the low-mobility
borrower’s contract must not be strictly preferred by high-mobility borrowers. Hence,
low-mobility borrowers receive contract ),( ll si , which is located where the low-mobility
indifference curve passing through ),( ** hh si cuts the low-mobility zero-profit curve.
Similar to the Rothschild-Stiglitz model (1976), an equilibrium does not always
exists. When the proportion of high-mobility type is sufficiently small, the separating
equilibrium described in proposition 1 is unsustainable. One can break the separation by
offering a pooling contract ),( pp si located between the two zero-profit curves but below
both indifference curves passing through ),( ll si . However, such a pooling contract would
27
not be sustainable in itself because one can simply offer an alternative contract above the
high-risk indifference curve and below the low-risk indifference curve passing this
pooling contract. Thus, to have the separating equilibrium described in proposition 1, it is
necessary that is sufficiently large, such that ),( pp si , if offered, generates negative
lending profit.
It is worth pointing out that high-mobility borrowers receive their first-best
contract ),( ** hh si , and their welfare is unaffected by asymmetric information. In contrast,
low-mobility borrowers are deprived from obtaining their first-best contract ),( ** ll si and
offered contract ),( ll si instead, which is inferior to their first-best contract. This is
consistent with the standard screening model in that the high-risk type (high-mobility
borrower) imposes a negative externality on the low-risk type (low-mobility borrower).
The difference between ),( ** ll si and ),( ll si represents the signaling cost that low-risk
borrowers would have to incur in order to signal their type to the lender.
Heterogeneous Default Risk
I now turn to the screening function of the prepayment penalty with respect to
default risk. To highlight the screening role of the prepayment penalty with respect to
default risk, I assume that borrowers are identical in all respects except for their
probability of default.
To characterize different levels of default risk, I assume borrowers are different in
their income uncertainty upon moving. Suppose there exist two types of borrowers:
28
borrowers with high default risk and borrowers with low default risk. Let h
y and l
y
represent the lower bounds of income for the high- and low-default-risk borrowers,
respectively, with hl
yy . It is common knowledge that the proportions of high-default
type and low-default type borrowers in the population are, respectively, y and y1 . To
examine how heterogeneous default risk influences the borrower’s mortgage choice, I
perform a similar analysis as I did previously for mobility. Differentiating the slope of the
borrower indifference curve in equation (2.5) with respect to y for any given ),( si yields
.0)22)(1(
)1)(1(12
1
isDyy
MRS j
j
U
(2.9)
As suggested by equation (2.9), the high-default-risk borrower’s indifference
curve passing through a given ),( si point is steeper than the low-default-risk borrower’s
indifference curve. The steeper indifference curves of high-default-risk borrowers suggest
that they are more willing than low-default-risk borrowers to trade prepayment penalty
for a lower interest rate.
Proposition 2.2: When borrowers differ in their default risk only, there exist a
separating equilibrium such that high-default-risk borrowers obtain loans with a greater
prepayment penalty and a lower interest rate than low-default-risk borrowers.
Proof. See appendix A.
29
It is necessary to assume the proportion of high-default type, y , is large enough
to rule out the no-equilibrium situation, the equilibrium is illustrated in figure 2. The
high-default borrower receives contract ),( ** hh si , which corresponds to the tangency point
between the lowest indifference curve and the zero-profit curve for the high-default
borrower type. The low-default borrower receives contract ),( ll si , which is located
where the low-default borrower’s indifference curve passing through ),( ** hh si cuts the
zero-profit curve for the low-default risk type. Again, I obtain the standard result in that
the high-risk type (high-default borrowers) imposes a negative externality on the low-risk
type (low-default borrowers), and the difference between the payoff of contract ),( ** ll si
and ),( ll si is the signaling cost that low-risk borrowers would have to incur.
Heterogeneous Mobility and Default Risk
I have shown that the screening roles of prepayment penalty differ with respect to
mobility versus default risk. I now study the role that prepayment penalty plays in
inducing self-selection when borrowers are heterogeneous in both risk attributes. It is
useful to first examine the aggregated effects of mobility and default risks on the slope of
a borrower’s indifference curves and overall risk type. As an example, consider a
borrower with high mobility and high default risk. Mobility and default risk work in
opposite directions in affecting the slope of the borrower’s indifference curve. High-
mobility borrowers are less willing to accept a prepayment penalty, while high-default
borrowers are more willing to do so. But the two risk attributes work in the same
30
direction in elevating the borrower’s risk for the lender. Therefore, a borrower with high
mobility and high default risk will be considered as very risky from the lender’s
perspective. Table 2.1 summarizes the aggregated effects on the slope of the borrower’s
indifference curves and on her overall risk type for the four combinations of mobility and
default risks.
Consider two borrower types—type A and type B—who are different in both
mobility and default risk. Let the mobility-default combinations of the two types be given
by ),(AA
y and ),(BB
y , respectively, withBA
andAA
yy .15
I assume it is
common knowledge that the proportions of type A and type B borrowers in the population
are, respectively, A and A1 . I first consider the existence of pooling equilibria. I then
discuss separating equilibria that emerge from different mobility-default combinations.
Pooling Equilibrium
I discuss two scenarios from which a pooling equilibrium can emerge. First, a
pooling equilibrium is feasible when borrowers have indifference curves with identical
slopes (identical UMRS for both types). As suggested by Table 2.1, the two risk attributes
may work in opposite directions in such a magnitude that they equalize the slopes of the
indifference curves across borrower types. In this case, prepayment penalty fails to serve
15 When
BA , the problem reduces to the case where borrowers are only heterogeneous with respect
to default risk. When BAyy , the problem reduces to the case where borrowers are heterogeneous only
with respect to mobility. When both are equal, I have trivial case where borrowers are completely
homogeneous. I do not impose restrictions on the size of A relative to B and the size of Ay relative to
By . Hence, I are able to consider all four possible combinations of ),(
AA y and ),(BB y : 1) BA and
BAyy ; 2) BA and BA
yy ; 3) BA and BAyy , and 4) BA and BA
yy .
31
as a screening device in distinguishing risk types. Second, a pooling equilibrium is
possible when the two zero-profit curves cross each other.
Scenario 1
A sufficient condition for a pooling equilibrium is that the slopes of borrowers’
indifference curves are identical across different risk types. To derive the mobility-default
combinations that fulfill this requirement, I substitute ),(AA
y and ),(BB
y ,
respectively, into equation (2.5) and set them to be equal. Thus, I have
.
)22)(1(
)1)(1(1
)22)(1(
)1)(1(12
1
2
1
yDis
yy
yDis
yy
MRSMRS
B
B
j
Bj
A
A
j
Aj
B
U
A
U
(2.10)
Simplifying yields
.
))1)(1(1
)1)(1(1
2
1
2
1
A
B
A
j
Bj
B
j
Aj
yy
yy
(2.11)
In the special case when equation (2.11) is satisfied, the indifference curves of the
two borrower types have the same slope at any ),( si point. The relative profitability of
serving each group of borrower depends on both and y . For equation (2.11) to hold, I
must have either BA and BA
yy or BA and BA
yy . In other words, high
mobility must be matched with high default risk. The intuition can be seen in table 2.1.
32
Because greater mobility reduces the slope of the indifference curves, it must be paired
with high default risk that has the opposite effect. It is clear that the borrower type with
high mobility and high default risk (H/H) must have her zero-profit curve located to the
northeast of that of the borrower type with an L/L combination.16
I define the borrower
type L/L (H/H), which has a lower (higher) zero-profit curve, as low- (high-) risk type.
When two distinct zero-profit contracts are offered to different types of borrowers, the
zero-profit contract for the low-risk type is strictly preferred by all borrowers. Because of
the identical slopes of the indifference curves of the two borrower types, the high-risk
type borrower would always imitate the low-risk borrower, which makes it impossible for
a separating equilibrium to exist.
Proposition 2.3: When the parameters of the model satisfy equation (2.11), there exists a
pooling equilibrium where both borrower types obtain the same contract.
Proof. See appendix A.
The equilibrium, which is illustrated in figure 2.3, is similar to the pooling
equilibrium characterized by Harrison et al. (2004) in the sense that the feasibility of a
separating equilibrium is eliminated by parallel indifference curves of different borrower
types. In Harrison et al. (2004), the parallel property relies on default cost satisfying
certain parameter conditions. In the model, default and prepayment risk work in opposite
16 I use the format mobility/default to denote the risk combinations where M and D stand for mobility and
default risks, and take the value of high (H) and low (L). For example, H/H indicates a borrower has
relatively high mobility and high default risk.
33
directions. When considered separately, each force may produce distinct contractual
outcomes by altering the relative slopes of indifference curves of different borrower
types. In fact, in the model, when the borrowers differ in only one dimension—that is,
when either )(BA
or )(BA
yy —then equation (2.11) would never hold. In the
special situation when the borrowers differ with respect to both risk dimensions, then it
becomes possible for the two opposing risk dimensions to exactly offset each other, in
which case the slopes of indifference curves become identical for the two borrower types
and only a pooling equilibrium exists.
Scenario 2
I now turn to the second scenario for a pooling equilibrium. When borrowers are
different in both mobility and default risk, the relative positions of the zero-profit curves
depend on the parameter combination of ),(AA
y and ),(BB
y . I have shown that both
high mobility and high default risks are undesirable from the lender’s perspective. When
both risk attributes can vary, then depending on the combinations of the two risk
attributes possessed by the borrower, the zero-profit curve of type A borrower may lie
above or below the zero-profit curve of type B borrower. The two zero-profit curves may
also intersect each other, in which case the mobility and default risks of the two borrower
types are canceling each other out, making profitability from the two types relatively
similar. Specifically, high mobility risk must be matched with low default risk and vice
versa. I denote the L/H borrowers as type A and the other (H/L borrowers) as type B.
Table 2.1 suggests that a type-A borrower must have a steeper indifference curve than a
34
type-B borrower. To formally establish this, I can write the slope differential between
type A and type B as the following:
.y
MRSyy
MRSMRSMRS UBAUBAB
U
A
U
(2.12)
From equations (2.8) and (2.9), I know both /UMRS and yMRSU / are
strictly positive. Provided BA and BA
yy , (2.12) is strictly negative. Thus, type-A
indifference curves must be steeper than type-B indifference curves.
When borrowers are heterogeneous in both mobility and default risks, the two
zero-profit curves may intersect each other. Let us denote this intersection by ),( QQ siQ
The height differential of the two zero-profit curves between type A and type B is given
by
,y
syy
s BABA
(2.13)
holding 0 BA . When there is an intersection, (2.13) must be equal to zero
for some i and s. This condition trivially holds when BA and BA
yy for any i and
s. When BA and BA
yy , the existence of Q implies there exist ),( QQ si that solves
./
/
y
yyAB
BA
(2.14)
The right-hand side of (2.14) is strictly negative because 0/ y and
0/ . If BA , B
y must be less than A
y for (2.14) to hold. In other words,
high mobility must be matched with low default risk for Q to exist. When there is a Q, it
35
is unique because type-A zero-profit curve is always steeper than type-B indifference
curve.17
Conditioned on the existence of Q, it is possible for the tangency points between
the indifference curves and the zero-profit curves to lie on the same or different sides of
Q. I show that there exists a pooling equilibrium when the two zero-profit curves
intersect each other and the two tangency points lie on different sides of Q.
As illustrated in figure 2.4, when zero-profit curves intersect and the tangency
points lie on different sides of Q, it must be the case that the tangency point of type B
borrowers, who have a steeper indifference curve, lies above Q, and the tangency point of
type A borrower lies below Q. To establish this fact, I equate the slopes expressions in
equations (2.5) and (2.6). After simplification, I obtain
.)22(
)22(
)1)(1(1
)1)(1(1
2
1
2
1
ycis
yDis
j
j
j
j
(2.15)
The left-hand side of equation (2.15) is increasing in , and the right-hand side is
increasing in s+i. Therefore, I must have 0/)( ** is at the tangency points. In
addition, *s and *i must also satisfy equation (2.2), the zero-profit condition. Thus, by
solving equation (2. 2), I can write *s in terms of *i and other parameters and have
.01
)( *
*
****
i
i
siis (2.16)
17 I can write the slope differential between type A and type B zero-profit curve as
yMRSyyMRSMRSMRSBABABA // . Both /MRS and
yMRS / are strictly positive. Provided
BA and BA
yy , BA MRSMRS is strictly
negative. Thus, type-A zero-profit curves must be steeper than type-B zero-profit curves.
36
From equation (2.6), I know that 1/ ** is . Thus, /*i must be strictly
negative for (2.16) to hold. 0/)( ** is and 0/* i collectively imply
0/* s . In addition, equation (2.15) is independent of default risk y . At a tangency
point, It must be true that 0/)( ** yis . Combine it with the zero-profit condition, I
have
.01
)( *
*
****
y
i
i
s
y
iis (2.17)
Equation (2.17) implies that 0/* yi . 0/)( ** yis and 0/* yi
collectively imply 0/* ys . Hence, when the tangency points lie on different sides of
the intercept, it must be that the tangency point of type B borrower (H/L borrower with
flatter indifference curves) lies above that of type A borrower, ** AB ss .
If there exists an intersection Q between the two zero-profit curves, it must be the
case that the type A zero-profit curve, which is steeper, is above (below) that of the type
B zero-profit curve for s values above (below) Q. If the intersection Q lies between the
two tangency points, it must be the case that, conditional on *Ass , the i value on zero-
profit curves must be smaller for type A than for type B, and, conditional on *Bss , the
i value on zero-profit curves must be greater for type A than for type B. Mathematically,
I state those two conditions as
),,(),( *** ABAA sisi (2.18)
),,(),( *** BBBA sisi (2.19)
37
where BAji j ,, denotes the zero-profit contract rates of types A and B. I use
BAkBAjsi kj ,;,),,( * to denote the i values on a zero-profit contract rate of type j
borrower when s takes the tangency-point value. I illustrate the underlining intuition in
figure 4. Expressions (2.18) and (2.19) collectively state that ),( ** BB si is located on the
left-hand side of ),( *BA si , and ),( ** AA si is located on the right-hand side of ),( *AB si .
This leads to the following proposition:
Proposition 2.4: When ),(),( *** ABAA sisi and ),(),( *** BBBA sisi , there exists a pooling
equilibrium at Q, the intersection of the zero-profit curves for the two borrower types,
where both borrower types obtain the same contract.
Proof. See appendix A.
Additional assumptions on A and A1 are necessary to rule out the no-
equilibrium situation. A pooling contract that is between the zero-profit curves and below
both indifference curves passing through Q are preferred than Q by both types of
borrowers. Such a pooling contract can be located either above or below Q. However,
such a pooling contract would not be sustainable itself, because one can offer an
alternative contract above the indifference curve of the high-risk type and below the
indifference curve of the high-risk type passing through that pooling contract. Therefore,
there is no equilibrium. Thus, the pooling equilibrium Q exists only if the population
38
shares, A and A1 , are such that contracts that are between the zero-profit curves and
below both indifference curves passing through Q generate negative lending profit.
Such a pooling equilibrium is different from the previous one because it is not
driven by borrowers having identical slopes of indifference curves. Rather, it is caused by
the relatively similar profits from both borrower types. The other crucial characteristic of
such a pooling equilibrium is that both borrower types are hurt by informational
asymmetry. As shown in figure 2.4, ),( QQ si is inferior to the first-best contracts of both
types. This is different from the previous case and from the typical pooling outcomes in
the literature, where the high-risk type benefits from information asymmetry.
Separating Equilibrium
I now discuss the existence of separating equilibria. I show that the mortgage
market is characterized by a separating equilibrium when (a) the two zero-profit curves
do not intersect each other, or (b) the two zero-profit curves intersect each other, and the
tangency points between the indifference curves and zero-profit curves lie on the same
side of the intersection of the two zero-profit curves. Notice that (a) and (b) collectively
represent the case where there is no intersection of the zero-profit curves above one of the
tangency points but below the other. That is, when either expression (2.18) or (2.19) is
violated, a separating equilibrium is feasible. Thus, I negate expressions (2.18) and (2.19)
to obtain the parameter conditions for a separating equilibrium. Specifically, I have
),(),( *** ABAA sisi or ),(),( *** BBBA sisi . Intuitively, ),(),( *** ABAA sisi implies that,
39
for all i between the two tangency points, type A borrower’s zero-profit curve is above
that of type B borrower. Similarly, ),(),( *** BBBA sisi implies that, for all i between the
two tangency points, type A borrower’s zero-profit curve is below that of type B
borrower. As a result, when either one is true, there is no intersection of the two zero-
profit curves between the tangency points.
Proposition 2.5: When borrowers differ in both mobility and default risk, the borrower
type with steeper indifference curves (type A) obtains loans with a greater prepayment
penalty and a lower interest rate than the one with flatter indifference curves (type B) if
),(),( *** ABAA sisi or ),(),( *** BBBA sisi .
Proof. See appendix A.
Several features of these equilibria are noteworthy. First, for all scenarios, the
equilibrium set of contracts exhibits a trade-off between prepayment penalty and interest
rate. In addition, regardless of which case applies, the borrower type with a steeper
indifference curve selects the high-prepayment penalty and low-interest rate contract,
while the borrower type with a flatter indifference curve chooses the contract with low
prepayment penalty and high interest rate. Second, adverse selection lowers the welfare
of one borrower type relative to the full-information case. When there is no intersection
of the zero profit curves, the low-risk type suffers from this welfare loss. When the
tangencies are above Q , type B borrowers are deprived of receiving their first-best
40
contract. Conversely, when the tangencies are below Q , type A borrowers are hurt by
information asymmetry.
Discussion and Implications
The significance of the questions studied in this paper is evident from the size of
the mortgage market. As of the end of first quarter of 2010, the outstanding volume of
residential mortgages was above 10.7 trillion dollars. It is clear that mispricing mortgage
products could lead to very large efficiency losses. However, pricing mortgage contracts
is complicated, largely because of the default and prepayment options available to
borrowers. This is primarily why all previous screening models of mortgage products
focus on either the default or prepayment behavior of the borrower, but not both.
Similarly, almost all of the previous theoretical and empirical studies of mortgage pricing
using option models focus on either the default or prepayment option available to the
borrower.18
What makes the role of prepayment penalties interesting is that they can serve as a
screening mechanism for both default and prepayment. However, propositions 1 and 2
indicate that the screening role of prepayment penalty will be complicated. On one hand,
I find in proposition 1 that, if I only consider prepayment, then in equilibrium, high-
mobility borrowers would prefer a contract with low prepayment penalty and high
interest rate, while low-mobility borrowers would prefer a contract with high prepayment
penalty and low interest rate. On the other hand, I find in proposition 2 that if I only
18 Exceptions include Kau, Keenan, Muller, and Epperson (1992, 1995), Kau and Keenan (1996), Titman
and Torous (1989), Foster and Van Order (1985), Schwartz and Torous (1993) and Deng, Quigley, and Van
Order (1996).
41
consider default risk, then in equilibrium, high-default-risk borrowers would prefer a
contract with high prepayment penalty and low interest rate, while low-default-risk
borrowers would prefer a contract with low prepayment penalty and high interest rate.
Both of these results are intuitive and confirm the conventional wisdom. The
complication arises when I consider the screening role of prepayment penalty for both
prepayment and default risks, because the borrower’s choice of a mortgage contract with
a prepayment penalty would send conflicting signals to the lender about that borrower’s
default and prepayment risk type. In particular, the willingness of a borrower to accept
prepayment penalty may stem from her low mobility risk and/or high default risk.
One outcome of the conflicting role of the prepayment penalty in screening
prepayment and default risk is the possibility of a pooling equilibrium. If the negative
correlation between prepayment penalty and prepayment risk is completely offset by the
positive correlation between prepayment penalty and default risk, then all borrower types
would have identical preferences over contract choices; hence, the prepayment penalty
choice of the borrower would have no informational value to the lender about that
borrower’s prepayment or default risk. This gives rise to a pooling equilibrium as the
unique outcome. Proposition 3 characterizes the conditions under which such an
equilibrium outcome emerges. Proposition 4 states that a pooling equilibrium can exist
even if the two opposing screening roles of prepayment penalty for prepayment and
default risk do not completely offset each other—that is, even if different borrower types
will prefer different mortgage contracts. This possibility arises when there is a contract
that yields the same expected profits to the lenders, regardless of the borrower’s type that
chooses that contract. Proposition 4 states the conditions under which, when such a
42
contract exists, it becomes the pooling equilibrium contract. As stated above, what is
interesting about this pooling equilibrium is that it is inferior to the first-best contract of
both types. This is in contrast to a typical pooling equilibrium, in which only one
borrower type receives less utility than her first-best contract, while the other borrower
type receives the same utility as her first-best contract.
It is worth noting that pooling equilibrium does not exist in Rothschild and
Stiglitz’s (1976) and other similar screening models. Firms in Rothschild and Stiglitz’s
study (1974) have an incentive and the ability to offer a contract that attracts low-risk
customers only, hence breaking any pooling outcome. However, pooling equilibria were
shown to exist in a recent screening model of mortgage markets by Posey and Yavas
(2001). The difference is due to the fact that, while the insurance firms in Rothschild and
Stiglitz (1974) have a continuum of contract types to offer (because they can offer a
continuum of coverage levels), lenders in Posey and Yavas’s model (2001) have only two
contract types to offer: ARMs and FRMs. The discreetness of the offer space for lenders
restricts a deviating lender’s ability to offer a contract that breaks a pooling outcome.
The source of pooling equilibrium in the model is very different than that of
Posey and Yavas (2001). The pooling equilibrium arises in the current model because of
the two different risk attributes of the borrower and the fact that the prepayment penalty
choice of the borrower can send conflicting signals to the lender about the two risk
attributes of the borrower.
When the conditions for a pooling equilibrium are not satisfied, I explore the
conditions for a separating equilibrium. As stated earlier, incorporating both default risk
and prepayment risk poses a challenge in characterizing the separating equilibria in such
43
models. I overcome this by combining the default and prepayment risks of the borrower
to determine that borrower’s type. The relative magnitudes of the default and prepayment
risks of a borrower will dictate the preferences of the borrower and the expected profits
of the lender from that borrower for different mortgage contracts. In Proposition 5, I
establish the conditions for an intuitive separating equilibrium. Borrowers whose default
risk is bigger relative to their prepayment risk will choose a contract with a larger
prepayment penalty and a smaller interest rate compared to borrowers whose prepayment
risk is more significant relative to their default risk. Therefore, a prepayment penalty can
have a separating role of dividing borrowers according to their (prepayment, default) risk
combination types and serve the lenders as a screening mechanism, despite the fact that
prepayment penalty serves opposing signals for prepayment and default risks.
44
Figure 2.1: Heterogeneous Mobility
This figure illustrates the mortgage market equilibrium with information
asymmetry regarding mobility. Solid lines show zero-profit curves of the lender for the
high-mobility borrower (type h) and low-mobility borrower (type l). Dashed lines are
borrower indifference curves. ),( ** hh si and ),( ** ll si represent the first-best contracts for
high- and low-mobility borrowers, respectively. The high-mobility borrower receives
contract ),( ** hh si , which corresponds to the tangency point between the lowest
indifference curve and the zero-profit curve; the low-mobility borrower receives contract
),( ll si , which is located where the high-mobility indifference curve passing through
),( ** hh si cuts the low-mobility zero-profit curve.
45
Figure 2.2: Heterogeneous Default Risk
This figure illustrates the mortgage market equilibrium with information
asymmetry regarding default risk. Solid lines show zero-profit curves of the lender for the
high-default borrower (type h) and the low-default borrower (type l). Dashed lines are
borrower indifference curves. ),( ** hh si and ),( ** ll si represent the first-best contract for
high- and low-default borrowers, respectively. The high-default borrower receives
contract ),( ** hh si , which corresponds to the tangency point between the lowest
indifference curve and the zero-profit curve; the low-default borrower receives contract
),( ll si , which is located where the high-default indifference curve passing through
),( ** hh si cuts the low-default zero-profit curve.
46
Figure 2.3: Heterogeneous Mobility and Default Risk (Pooling Equilibrium: Scenario 1)
This figure illustrates the pooling equilibrium with information asymmetry
regarding both mobility and default risk. Solid lines show zero-profit curves of the lender
for the high-default borrower (type h) and the low-default borrower (type l). Dashed lines
are borrower indifference curves. ),( ** AA si and ),( ** BB si represent the first-best contract
for type A and type B borrowers, respectively. Both type A borrowers and type B
borrowers receive the same contract ),(),( BBAA sisi .
47
Figure 2.4: Heterogeneous Mobility and Default Risk (Pooling Equilibrium: Scenario 2)
This figure illustrates the pooling equilibrium with information asymmetry
regarding both mobility and default risk when the two tangency points lie on different
sides of Q. Solid lines show zero-profit curves of the lender for the high-default borrower
(type h) and the low-default borrower (type l). Dashed lines are borrower indifference
curves. ),( ** AA si and ),( ** BB si represent the first-best contract for type A and type B
borrowers, respectively. Both type A borrowers and type B borrowers receive the same
contract Qsisi BBAA ),(),( .
48
Figure 2.5: Heterogeneous Mobility and Default Risk (Separating Equilibrium)
This figure illustrates the pooling equilibrium with information asymmetry
regarding both mobility and default risk when the two tangency points are above Q .
Solid lines show zero-profit curves of the lender for the high-default borrower (type h)
and the low-default borrower (type l). Dashed lines are borrower indifference curves.
),( ** AA si and ),( ** BB si represent the first-best contract for type A and type B borrowers,
respectively. A type A borrower receives contract ),( ** AA si , which corresponds to the
tangency point between the lowest indifference curve and the zero-profit curve; a type B
borrower receives contract ),( BB si , which is located where the type A indifference curve
passing through ),( ** AA si cuts the type B zero-profit curve.
49
Figure 2.6: Heterogeneous Mobility and Default Risk (Separating Equilibrium)
This figure illustrates the pooling equilibrium with information asymmetry
regarding both mobility and default risk when the two tangency points are below Q .
Solid lines show zero-profit curves of the lender for the high-default borrower (type h)
and the low-default borrower (type l). Dashed lines are borrower indifference curves.
),( ** AA si and ),( ** BB si represent the first-best contract for type A and type B borrowers,
respectively. A type B borrower receives contract ),( ** BB si , which corresponds to the
tangency point between the lowest indifference curve and the zero-profit curve; a type A
borrower receives contract ),( AA si , which is located where the type B indifference curve
passing through ),( ** BB si cuts the type A zero-profit curve.
50
Table 2.1: Aggregated Effects of Mobility and Default
This table summarizes the aggregated effects of mobility and default risks. High
(low) mobility corresponds to flatter (steeper) indifference curves, and high (low) default
risk corresponds to steeper (flatter) indifference curves. From the lender’s perspective,
high (low) mobility corresponds to high (low) risk, and high (low) default corresponds to
high (low) risk. When borrowers are heterogeneous on both mobility and default risk, the
effects are combined. For instance, when a borrower is characterized by high mobility
and high default risk, we expect her indifference curves to be of medium slope. This
borrower is also very risky from the lender’s perspective.
DEFAULT
HIGH LOW
Steep/Risky Flat/Safe
MOBILITY
HIGH Medium Slope/Very Risky Very Flat/Medium Risk
Flat/Risky
LOW Very Steep/Medium Risk Medium Slope/Very Safe
Steep/Safe
51
Chapter 3
The Screening Roel of Mortgage Discount Points on
Transaction Costs19
The U.S. residential mortgage market is dominated by fixed-rate mortgages
(FRMs). One of the important benefits of the FRM is the borrowers’ prepayment option.
It allows a borrower to take advantage of lower rates through refinance. However, this
valuable feature requires monitoring by the borrower. To realize the benefit of the
prepayment option, a borrower must make correct refinancing decisions. In fact, properly
―maintaining‖ a FRM is far from a trivial task. Knowledge of interest rate trends and tax
rules is essential to gauge the potential benefit from refinancing. In addition,
sophisticated calculations are necessary to determine the right time to refinance.20
Moreover, refinancing itself is often costly and time-consuming. The substantial amount
of time and effort needed to search and bargain for refinancing opportunities is a
transaction cost, which is defined by Stanton and Wallace (1998) as ―a cost incurred by
the borrower but not received by the lender‖ (Stanton and Wallace 1998). The transaction
costs associated with refinance are different across borrowers for at least three reasons.
First, it may be less costly for a financially savvy borrower to exercise the prepayment
19 This chapter is derived from a co-authored paper with Brent Ambrose and Michael LaCour-Little entitled
―Do Mortgage Points Signal Mobility or Transactions Cost: Evidence from Securitization‖.
20 The complexity of optimal mortgage refinancing is reflected in the vast literature on option-based
mortgage pricing theory. Examples from this stream of literature include Kau, Keenan, Muller, and
Epperson (1992, 1993), Ambrose and Buttimer (2000).
52
option than for a naïve borrower. While some borrowers are equipped with superior
knowledge and quantitative skills to identify and take advantage of refinancing
opportunities, others may find it more costly to gather and mentally process the
information necessary to correctly refinance. Diversity of cognitive skills and financial
literacy has been extensively documented in economic literature. Older and less educated
individuals appear to have lower cognitive abilities and are more likely to make mistakes
on financial calculations.21
Limited financial literacy appears to be correlated with low
income, less education, older age and minority status.22
Second, borrowers may also
differ with respect to their search costs. High search costs may be attributable to the lack
of access to valuable information sources such as the internet, newspaper, and financially
savvy relatives and friends. Highlighting the importance of information sources and
search skills, Brown and Goolsbee (2002) find that lower life insurance premiums are
associated with greater internet usage. A similar pattern was also identified in the
residential housing markets. First-time and out-of-town buyers, who normally have
limited experience and information, appear to pay a substantial and persistent price
premium.23
Analogously, one could expect better information and search skills may
reduce the cost of refinancing. Finally, borrowers may differ in their opportunity costs.
Given the time-consuming nature of the refinancing process, individuals with greater
21 See Agarwal, Driscoll, Gabaix and Laibson (2007), Christelis, Tullio, and Padula (2006), Korniotis and
Kumar (2008a, 2008b).
22 See Hogarth and Hilgert (2002), Lusardi and Mitchell (2007), Lusardi and Tufano (2008), Bucks and
Pence (2008).
23 See Myer, He and Webb (1992), Turnbull and Sirmans (1993), Watkins (1998), and Lambson, McQueen
and Slade (2004).
53
opportunity costs would deem refinance more costly than others. I sketch a simple model
to show that when the transaction costs associated with refinance are heterogeneous
across borrowers and are unobservable, the mortgage market resembles the insurance
market delineated by Rothschild and Stiglitz (1976). I show that there exists a separating
equilibrium such that borrowers with higher (lower) transaction costs pay more (less)
discount points to obtain a lower (higher) interest rate.24
This equilibrium is also
characterized by the low-cost (high-prepayment-risk) borrower imposing a negative
externality on the high-cost (low-prepayment-risk) borrower.
The theory indicates that borrowers with high transaction cost, those who are
slower to refinance in the face of declining interest rates, tend to select more discount
points. In contrast, conventional mobility theory suggests that discount points are a signal
of the borrower’s expected mobility.25
Specifically, borrowers with smaller (greater)
expected probability of relocation select more (fewer) points. It is possible that the
borrower’s points-coupon choice is jointly determined by his transaction costs and
mobility. Given this potential dual screening role, it remains unclear that how lenders
interpret the signals generated from realized points-coupon choices. Thus, in contrast to
previous studies that focus solely on the borrower’s choice, I empirically study the
screening role of discount points from the lender’s perspective. I ask the question: Is the
empirically observed points-coupon tradeoff intended for screening mobility or
transaction costs? If discount points signal unobserved borrower characteristics,
24 Henceforth, high-cost borrowers and low-cost borrowers.
25 See Dunn and Spatt (1988), Chari and Jagannathan (1989), Yang (1992), Brueckner (1994), LeRoy
(1996) and Stanton and Wallace (1998).
54
transaction costs, or mobility, then I expect originators to use this information in making
securitization decisions. Thus, I investigate the relation between transaction costs and
securitization decisions to infer if mortgage originators sort loans based on transaction
costs.
As suggested by the model, paying points signals greater transaction costs. One
could then use discount points to measure transaction costs and examine whether they are
correlated with securitization decisions. However, discount points can also be correlated
with expected mobility, which lenders may also deem important. This mixed screening
function prevents a clear-cut interpretation on what discount points signal even if loans
are securitized based on how many points were paid at the origination. Thus, to achieve a
more informative test, I first separate the two effects by constructing an alternative
measure of transaction cost called excess yield spread, which is based on the
―overvaluedness‖ of a loan. A borrower is more likely to hold an overvalued loan if she is
subject to high transaction costs, that discourage her from searching and bargaining for
better mortgage contracts. Therefore, I expect this group of borrowers to also face
relatively high costs at the time of refinance. More importantly, the ―overvaluedness‖ of a
loan is unlikely correlated with low mobility. In fact, a longer expected holding period is
likely to induce more extensive search and bargaining. To establish the validity of the
measurement, I examine the connection between excess yield spread and prepayment
patterns. I find that borrowers holding overvalued mortgages are less likely to prepay,
and this reduced tendency is attributable to their sluggish response to declining market
interest rate. These results support the conjecture that excess yield spread serves as a
valid measurement of borrower transaction costs.
55
Equipped with a clearer measure of transaction costs, I can infer what discount
points signal from the mortgage originator’s perspective. I compare the effects of excess
yield spread and the amount of discount points on the likelihood of a loan being
securitized. I find that overvalued mortgages and ones with more discount points are both
more likely to be retained in originator’s portfolio (not securitized). This result indicates
that lenders are more likely to securitize loans originated by borrowers with higher cost
of refinance.
Related Literature
Mortgage-points choice has stimulated research interest from economists for
decades. For example, Dunn and McConnell (1981) first suggested that mortgage points
serve as a backdoor prepayment penalty for the lender to charge for the embedded
prepayment option. In contrast, Kau and Keenan (1987) pointed out that tax
considerations may play a crucial role in determining points paid on purchase loans.26
Because discount points may be deducted all at once at origination while the interest rate
deduction is spread across the life of the loan, borrowers with high marginal tax rates are
more willing to pay points in order to receive a low interest rate.
However, the majority of the mortgage-points literature focuses on borrower
mobility as the primary determinant. Pioneered by Dunn and Spatt (1988), an array of
studies followed this mobility tradition in explaining the widely observed points-coupon
menu. The basic intuition proposed by Dunn and Spatt (1988) is that borrowers who
26 Points paid for purchase loan are deducted at the year of origination, points paid for refinance loan are
amortized over the life of the loan.
56
expect to move soon benefit less from discount points. When offered a points-coupon
menu, high-mobility borrowers will self-select into mortgages with low points and high
coupons. This intuition was further modeled by Chari and Jagannathan (1989), Yang
(1992), and Brueckner (1994). To explain the observed points-coupon trade-off, Chari
and Jagannathan (1986) appeal to income uncertainty. In their model, relocation is
associated with favorable future income. Thus, paying discount points is viewed as
insuring against the low-income state. When the good state (relocation) occurs, the
benefit from points (low interest rate) is forfeited. Their model predicts that mobile
borrowers select loans with high points, a result contradicting other mobility-based
theories and empirically observed correlation between discount points and mobility
(Brueckner 1994, and Clapp, Goldberg, Harding, and LaCour-Little 2001). Allowing for
an arbitrarily large lender profit, Yang (1992) shows that it is possible to achieve a
separating equilibrium where borrowers with longer (shorter) expected residence in their
houses pay more (less) points. Brueckner (1994) constructs a two-period model to
consider the effect of information asymmetry on borrower mobility. In a competitive
market, when borrowers differ only in their probability of moving midway through the
term his mortgage, there exists a separating equilibrium such that high-mobility
borrowers choose low-points/high-coupon contracts from the available menu.
While mobility remains the theme, more recent studies by LeRoy (1996) and
Stanton and Wallace (1998) elevate the sophistication of the mortgage-points analysis by
incorporating the idea of financially motivated prepayment. LeRoy (1996) incorporates
both mobility- and interest-rate-motivated prepayments. The model achieves a semi-
pooling equilibrium, where the least mobile borrowers are separated from the rest of the
57
pool. Stanton and Wallace (1998) emphasize the transaction costs of refinancing, which
is defined as the costs incurred by borrowers but not received by the lender. They show
that with information asymmetry regarding borrower mobility, such costs are essential to
construct a separating equilibrium. Consequently, borrowers are fully separated based on
their mobility. Sedentary (mobile) borrowers select higher (lower) points and lower
(higher) interest rates.
A number of studies have supplied empirical support to the mobility-based
explanation. Brueckner (1994) constructs a mobility measure using a linear combination
of borrower characteristics (e.g. age, marital status, etc.) and shows that high mobility is
associated with taking loans with more discount points. As one of the few studies that
uses data that can distinguish between mobility related payoffs and refinancing, Clapp, et
al. (2001) find that paying discount points is associated with a reduced probability of
moving.
Nevertheless, transaction costs are often assumed to be homogeneous. (e.g.
Stanton and Wallace 1998). Although the influence of heterogeneous costs of refinancing
has not been theoretically acknowledged, some studies have explored its effect
empirically. Pavlov (2001) approximates transaction costs using refinancing history, loan
documentation, and discount points selection. He finds that higher transaction costs are
associated with lower refinancing probability. Using a data set containing both points and
loan termination information, Chang and Yavas (2008) find that borrowers who choose to
pay more points are less likely to refinance in the future, and when they do, they
refinance later than borrowers who choose to pay fewer points. On the other hand, they
58
find no correlation between paying discount points and the probability of moving. The
authors interpret their findings as evidence supporting heterogeneous transaction costs.
The use of loan ―overvaluedness‖ to measure transaction costs is inspired by the
literature on price premium in the real estate market. A number of studies have shown
that residential mortgages may not be uniformly priced. Carlin (2009) argues that despite
the large number of firms in the retail financial market, a firm can preserve market power
and charge a price above marginal cost by strategically increasing the complexity of their
price structure. As a result, naïve consumers pay a higher price than the informed ones.
Carlin (2009) shows that price dispersion can persist and even enlarge as the market
becomes more competitive. Woodward (2003, 2008) finds that households tend to pay
higher broker fees on mortgages with points, and that college education is associated with
a substantial reduction in average broker fees.
The existence of price premium has also been extensively documented in
residential property transactions. First-time and out-of-town buyers appear to pay a
substantial and persistent price premium, which may be attributable to buyer
characteristics such as experience, search costs, and bargaining power (Myer, et al. 1992,
Turnbull and Sirmans 1993, Watkins 1998, and Lambson, et al. 2004). Another stream of
literature complements these findings by showing that overpaid properties are associated
with a greater likelihood of mortgage delinquency (Calem and Wachter 1999), default
(LaCour-Little and Malpezzi 2003, Noordewier, Harrison and Ramagopal 2001), and
foreclosure (Ong, Neo, and Spieler 2006). Since households make both home purchase
and financing decisions, it is reasonable to believe the disadvantaged consumer group is
59
more likely to overpay, and such mortgages are associated with adverse outcomes (e.g.
slower refinance and higher default probability).
This study is also related to the literature on securitization. The incentive of
securitization may be attributable to information asymmetry (DeMarzo and Duffie 1999)
and regulatory arbitrage (Calem and LaCour-Little 2004). DeMarzo and Duffie (1999)
suggest that to overcome asymmetric information, it may be optimal for a better-
informed lender to retain loans with high degree of information asymmetry. Calem and
LaCour-Little (2004) argue that the required level of regulatory capital imposes a burden
on banks and creates incentive for securitizing mortgages with limited default risk.
Consistent with this view, Ambrose, LaCour-Little, and Sanders (2005) find that loans
retained in originator’s portfolio are more likely to default but less likely to prepay. I
compliment the securitization literature by showing how transaction features, such as
discount points, may provide useful signals to lenders making portfolio decisions.
The Model
In this section, I present a simple model to illustrate the role of discount points as
a screening device for the cost of refinancing. Consider a competitive lending market, in
which lenders offer a menu of fixed rate mortgage (FRM) contracts with a variety of
combinations of initial interest rate 0i , and discount points s. In the first period, the
borrower obtains a mortgage of size L to purchase a house of value LP . To make the
model tractable, I suppress property price variation by assuming constant property value
over time, and normalize the loan amount L to $1 so that the term ―interest rate‖ and
60
―interest payment‖ can be used interchangeably. More importantly, s can then be
interpreted as the percentage of loan amount, which is consistent with how mortgage
points are assessed. The mortgage matures in the second period when the borrower is
required to repay the principal plus interest. Second-period interest rate i is assumed to be
stochastic. The density function of i is denoted by )( f , and its support is given by ],[ ii .
I assume borrowers are identical in all aspects except for the direct monetary and non-
monetary costs of refinancing (e.g. appraisal fees, title search time and inconvenience
etc.), denoted by c. A borrower may prepay the mortgage if the realized value of i is
sufficiently less than his contract rate 0i . The critical value of i, below which refinancing
is optimal, depends on individual’s transaction costs. A borrower optimally prepays when
i satisfies
cii 0 (3.1)
The left-hand side of (3.1) equals the savings obtained via refinancing. Equation (3.1)
indicates that optimal refinancing occurs when the benefit exceeds the cost. Rearranging
terms leads to the following rule of refinancing:
ciii 0
~ (3.2)
where i~
represents the critical interest rate that triggers refinancing.
The optimality of this refinancing rule can be verified directly from borrower’s
objective function. Borrowers are risk-neutral and discount future cash flows by a factor
of 1 . Y denotes the exogenous component of wealth, which equals the borrower’s
initial endowment and discounted future income. Given risk-neutrality, the borrower’s
utility equals the expected discounted value of wealth
61
i
i
i
idiifiLPdiifciLPsLPY ~ 0
~
)()()()()( . (3.3)
In the first period, a borrower incurs down payment )( LP and discount points s. If the
second-period realized interest rate is between i~
and i , the borrower prepays to obtain
the favorable interest rate. However, refinancing comes with a cost c. If the second-
period realized interest rate is between i and i~
, the borrower repays the original loan
with principal and interest 0iL . To verify the refinancing rule (3.2) is optimal, (3.3) is
differentiated with respect to i~
. The first-order condition yields cii 0 , which implies
the optimal threshold for refinancing is cii 0
~. Substituting ci 0 for i
~ in (3.3), the
borrower’s utility can be written as
i
ci
ci
idiifiLPdiifciLPsLPYisu
0
0
)()()()()(),( 00 . (3.4)
The lender is also assumed to be risk-neutral and has a discount rate of 1 .
Hence, lender’s objective function is the expected discounted value of profit from the
mortgage loan.
i
ci
ci
idiifiLdiifiLsLis
0
0
)()()()(),( 00 (3.5)
In the first period, the lender transfers the loan amount minus the discount points to
borrower. If second-period interest rate falls below ci 0 the lender earns the current
market interest rate, which is less than the contract rate. Alternatively, if second-period
interest rate is above ci 0 , the lender earns the contract rate 0i .
To characterize the competitive market equilibrium, I first examine the
indifference curve of the borrower and the iso-profit curve of the lender. These curves
62
describe the borrower’s and lender’s trade-offs between discount points s and contract
rate 0i , respectively. To derive the slope of borrower’s indifference curve, I implicitly
differentiate 0i with respect to s holding ),( 0isu constant. Thus, it follows that
0
)(
1
0
0
0
i
ci
i
su
diifu
u
s
iMRS
. (3.6)
Hence, the indifference curves are downward sloping. This indicates that, from the
borrower’s perspective, the disutility resulting from paying points must be compensated
through a lower contract rate in order to remain on the same indifference curve. It is also
clear that uMRS is horizontal parallel indicating that the borrower’s indifference curves
have the same slope for a given 0i .27
In addition, the indifference curves are convex
because 00 iMRSu , that is, as 0i increases, the slope of indifference curves become
smaller (more negative). To focus on the influence of refinancing costs on a borrower’s
choice of discount points, (3.6) is differentiated with respect to c, and it follows that
0 cMRSu . In other words, as c increases, uMRS becomes larger (less negative).
Intuitively, a larger refinancing cost c induces a decline in the optimal threshold of
refinancing. With reduced probability of refinancing, the borrower is more willing to
trade discount points for a low contract rate. Thus, the indifference curves become flatter
as c increases.
To derive the slope of lender’s iso-profit curves, 0i is implicitly differentiated
with respect to s holding profit constant. The slope is given by
27 To see this, notice that (3.6) is independent of s.
63
)()(
1
00
0 cicfdiif
MRSi
ci
i
s
. (3.7)
Following Brueckner (2000) and Harrison, Noordewier, and Yavas (2004), I make the
simplifying assumption that the second-period interest rate is uniformly distributed. With
)( f being uniform, the slope of iso-profit curves become
)( 0ii
iiMRS
(3.8)
(3.8) is negative for ii 0 , but the iso-profit curve becomes positively sloped if ii 0 .
To focus on more realistic situations when MRS is downward sloping, I further impose
the restriction that 0i must be strictly less than i . The slope of borrower’s indifference
curves in the uniform case can be obtained via substituting for )( f in (3.6). It follows
that
)]([ 0 cii
iiMRSu
(3.9)
I first consider the situation when all borrowers share an identical level of
transaction costs. The assumption of a competitive market implies that the equilibrium
mortgage contract must lie on the zero-profit line, defined by 0),( 0 is . Borrower
utility is greater on lower indifference curves (fewer points and lower interest rate). Thus,
the point where the lowest indifference curve is tangent to the zero-profit curve gives the
equilibrium contract. The value of 0i at the tangency point can be solved via equating
(3.8) and (3.9). It follows that
64
cii*
0 (3.10)
With the restriction that ii 0 , must hold for this solution to be admissible. The
optimality requires that the zero-profit curve is more convex than the indifference curves.
This requirement is satisfied with )( f being uniform.28
I now study the situation when borrowers are different with respect to their costs
of refinancing. Suppose there exist two types of borrowers: borrowers with high
refinancing costs and borrowers with low refinancing costs. The costs of refinancing are
hc and hl cc respectively for high- and low-cost borrowers. Substituting hc and lc in
(3.5) yields two utility functions that are different in slope. Because 0 cMRSu , the
high-cost borrower’s indifference curve passing through a given ),( 0is point is flatter
than the low-cost borrower’s indifference curve. This fact is critical in deriving
equilibrium contracts. The flatter indifference curves of high-cost borrowers suggest that
they are more willing to trade discount points for a lower interest rate.
Heterogeneous refinancing costs also alter the relative position of the zero-profit
curves. The difference in the heights of the lender’s zero-profit curves can be obtained by
setting (3.5) to zero and differentiating, yielding 0
//0 icci . Since 0c , this
derivative is negative when the zero-profit curves are downward sloping )0(0i ,
implying that the high-cost borrower’s zero profit curve is always lower than the low-cost
28 The slope difference between iso-profit lines and indifference curves is negative (positive) when 0i is
less (greater) than *
0i . It indicates that the zero-profit curve is flatter than the indifference curve for *
00 ii
and steeper for *
00 ii .
65
borrower’s curve. The intuition is that the low-cost borrower is more likely to prepay,
thus a higher interest rate has to be charged to them for any given level of s to maintain
zero profit.
The first-best contracts are those that would be offered by a lender with perfect
information on borrower’s transaction costs. These contracts ensure that the lender makes
zero profit and each borrower’s utility is maximized. They are obtained by solving the
utility maximization problem of each borrower subject to their respective lender’s zero-
profit conditions. However, the first-best contracts are not always feasible for two reasons.
First, a lender usually does not possess perfect information on each borrower’s
refinancing cost. Second, even when individual characteristics (e.g. age, gender, and
education) are correlated with the borrower’s cost of refinancing and may be used to
obtain estimates of c, legal restrictions may prevent lenders from practicing price
discrimination based on such characteristics. In this case, all borrowers must be presented
with a menu of loans with the same points-coupon combinations.
To identify the mortgage market equilibrium under asymmetric information, I
follow the standard argument of Rothschild and Stiglitz (1976), who define an
equilibrium as a set of contracts satisfying two conditions. First, the lender earns zero
profit on all contracts. Second, no contract outside the given set attracts borrowers while
making a non-negative profit. I argue that there exist a separating equilibrium that
satisfies these conditions, and this equilibrium is characterized by borrowers with high
transaction costs paying more points to obtain a lower interest rate, and borrowers with
low transaction costs paying fewer points and receiving a higher interest rate.
66
To establish the argument, I first rule out the existence of a pooling equilibrium,
where both borrower types are offered the same contract. The zero-profit condition
implies that a pooling contract ),( 0
pp is must lie between the zero-profit curves in Figure 1.
In this case, the lender must make negative profit on low-cost borrowers and offset it
using positive profit made from high-cost borrowers. Such a contract does not represent
an equilibrium because there exist alternative contracts that attract high-cost borrowers
while making positive profit. Such contracts, located to the southeast of ),( 0
pp is , lie
above the low-cost indifference curve but below the high-cost curve passing through
),( 0
pp is . These contracts will attract only high-cost borrowers and earn a positive profit.
The existence of such contracts is ensured by the flatter slope of the high-cost
indifference curve.
The only remaining possibility is to have a separating equilibrium, where distinct
contracts are assigned to different borrower types. Market competitiveness implies that
the zero-profit conditions for both borrower types must be satisfied. In addition, the
equilibrium contracts must separate the two types of borrower by satisfying the revelation
principle. Collectively, these imply the following conditions.
,0),( lll si
(3.11)
,0),( hhh si
(3.12)
),,(),( hhllll siUsiU
(3.13)
),,(),( llhhhh siUsiU
(3.14)
67
(3.11) and (3.12) imply that the equilibrium contract for each type must lie on their
respective zero-profit curve. (3.13) and (3.14) state that the mortgage contract intended
for a given borrower type is chosen by that type. In other words, no borrower type has an
incentive to imitate the other in order to obtain greater utility. Since the low-cost, zero-
profit curve lies above the high-cost, zero-profit curve, it must be the case that (3.13) is
binding and (3.14) is not. Hence, the lender can offer low-cost borrowers their first-best
contract ),( *
0
* ll is without attracting high-cost borrowers. ),( *
0
* ll is corresponds to the
tangency points between the lowest indifference curve and the zero-profit curve. On the
other hand, the high-cost, first-best contract ),( *
0
* hh is if offered, will attract both types
and result in negative lending profit. Thus, the equilibrium contract received by the high-
cost borrower is located where the low-cost indifference curve passes through ),( *
0
* ll is
and cuts the high-cost zero-profit curve. This contract, which is denoted ),( *
0
* hh is , is
shown in figure 3.1. In this case, low cost borrowers are indifferent between ),( *
0
* ll is and
),( 0
hh is . The simultaneous offering of ),( *
0
* ll is and ),( 0
hh is satisfies the zero-profit
conditions and the incentive compatibility constraints.
It is clear that in equilibrium, high-cost borrowers select a contract with greater
mortgage points than low-cost borrowers. This differentiated mortgage choice arises from
the negative externality generated by information asymmetry. It is clear that low-cost
borrowers receive their first-best contract ),( *
0
* ll is , and their welfare is unaffected by
asymmetric information. In contrast, high-cost borrowers are deprived from obtaining
their first-best contract ),( *
0
* hh is and offered contract ),( 0
hh is , which is inferior to the
68
outcome under full information. This is consistent with the standard screening model that
high-risk types (low-cost borrowers) impose a negative externality on low-risk types
(high-cost borrowers).
Hypotheses Development
In this section, I develop hypotheses that are used in my empirical investigation.
The main challenge comes from the fact that my transaction-costs based theory is not the
only possible explanation for why borrowers pay discount points. In fact, previous
literature posits the heterogeneity of expected mobility as the reason for the observed
coupon-points trade-offs. Ambiguity arises from the fact that prepayment may come from
moving or refinancing. For instance, the model implies that borrowers with relatively
greater transaction costs rationally pay more discount points, and loans held by this group
of borrowers are characterized by delayed refinance. Thus, one could test whether or not
the amount of discount points paid at origination leads to a reduced probability of
prepayment. Unfortunately, such evidence is circumstantial at best, because discount
points may also signal mobility. Mobility theory suggests that low-mobility borrowers
should pay more discount points. Because prepayments resulted from refinance and
relocation are indistinguishable in the data, it is inconclusive which factor, mobility or
transaction costs, causes the reduced likelihood of prepayment. Furthermore, with this
mixed screening role of discount points, examining its effect on securitization decisions
will not be fruitful because I do not know whether such an impact is attributable to
transaction costs or mobility.
To distinguish the effects of mobility from transaction costs, I carry out a two-step
process. In the first step, I construct an alternative measure, excess yield spread, to gauge
69
borrower’s cost of refinancing. I provide empirical evidence that this measure indeed
captures borrower transaction costs. More importantly, this new measure is not subject to
the ambiguity caused by mobility and transaction costs working in the same direction.
Thus, in the second step, I determine whether or not lender securitization decisions are
impacted similarly by excess yield spread and discount points. Because excess yield
spread is a cleaner measure of transaction costs, juxtaposing it with discount points will
provide evidence for the motivation of offering the coupon-points menu.
I discuss the method of constructing excess yield spread in the next section.
However, the rationale behind such a measure is rather straightforward. Excess yield
spread gauges the relative ―overvaluedness‖ (or ―undervaluedness‖) of a loan. Greater
excess yield spread indicates that a borrower paid a relatively higher premium in terms of
interest rate for his mortgage. Because this higher premium is unexplained by standard
underwriting criteria (e.g. credit score, income, and LTV ratio) and discount points, it is
likely to reflect unobserved heterogeneity in transaction costs. I draw an analogy from the
well documented price premium phenomenon in the residential property market. First-
time and out-of-town buyers usually pays a substantial and persistent price premium,
which may be attributable to buyer characteristics such as experience, search costs, and
bargaining power.29
Because households make both home purchasing and financing
decisions, it is reasonable to expect borrowers with greater search costs and information
disadvantage also search less extensively for mortgages. As a result, these borrowers are
more likely to overpay for their loan. Similarly, borrowers with greater opportunity costs
29 See Myer, et al. (1992), Turnbull and Sirmans (1993), Watkins (1998), and Lambson, et al. (2004).
70
would also search and bargain less and pay a larger interest premium. Provided
transaction costs continue to influence future financial decisions, excess yield spread can
serve as a priori measure of the borrower’s cost of refinancing.
The model assumes that the interest-coupon trade-off at the wholesale level is
competitively priced. To maintain simplicity, I do not model the role of financial
intermediaries. In reality, the price premium may arise from the fact that mortgages are
originated through distinct channels (e.g. mortgage brokers verses retail lenders). While
mortgage funds are homogeneous and supplied in a competitive national market, the
service on obtaining it may be a local good and tends to be heterogeneous. I view the
price premium in the mortgage market primarily as a result of compensating financial
intermediaries for performing their market function. Thus, the existence of a price
premium does not contradict the assumption that the mortgage market is competitive at
the wholesale level. For instance, a mortgage broker who is connected to multiple lenders
may be able to search more efficiently on behalf of his customer. Such ―match-making‖
functions must be compensated and may take the form of a greater interest premium. On
the other hand, a mortgage broker may also have an incentive to steer borrowers to loans
that offer greater compensation.30
A loan officer paid on commission would be subject to
a similar agency problem. While the role of financial intermediaries is not the subject of
this study, I believe superior financial sophistication, better search skills, and greater
information reduce direct and indirect costs associated with financial intermediaries.
30 See Jackson and Barry (2001), LaCour-Little (2009), and Woodward (2008).
71
Obviously, the validity of using excess yield spread to measure transaction costs
requires empirical justification. If higher excess yield spread captures transaction costs, it
should be correlated with a lower likelihood of prepayment. More importantly, this
reduced tendency of prepayment should stem from increasingly slower refinance. This
rationale can be viewed from equation (3.2). Larger refinancing cost c lead to a decline of
the threshold interest rate i~
, which implies that high-cost borrowers will wait for a larger
rate reduction before they refinance. This translates to a reduced sensitivity of
prepayment to interest rate reduction. Hence, I construct the following hypothesis to test
the validity of excess yield spread as a measure of transaction costs:
H1: Loans with greater excess yield spread are less likely to prepay, and this reduced
tendency of prepayment is attributable to a lower sensitivity of prepayment to
interest rate reduction.
I are aware that the likelihood of holding overvalued loans may not be
independent from expected mobility. However the effects of mobility and transaction
costs on excess yield spread are likely to be in opposite directions. If borrowers differ in
their mobility but are relatively homogeneous in transaction costs, high-mobility
borrowers, who are more likely to prepay, would also be more likely to hold overvalued
loans. This is precisely the opposite of the hypothesis that loan ―overvaluedness‖ is
negatively related to the tendency to prepay. Having a shorter expected holding period,
high-mobility borrowers would gain less from costly search and bargaining. In other
words, expecting to relocate soon, high-mobility borrowers are less bothered by paying a
72
greater interest premium. Therefore, even if mobility also affects excess yield spread, it
strengthens the power or my test by making the hypothesized relation less evident.
The second step involves studying the connection between transaction costs and
securitization decisions. Securitization transforms heterogeneous and illiquid individual
loans into liquid and marketable securities. The securitization of residential mortgages
usually involves the originator retaining a portion of their originated loans and selling the
rest to the secondary market. Because mortgage originators are sophisticated financial
institutions and, more importantly, the designers and the user of the coupon-points menu,
they are able to interpret realized points-coupon combinations and identify otherwise
unobserved borrower characteristics (e.g. mobility or transaction costs). Therefore,
analyzing securitization decisions helps understand what information is conveyed by
discount points to mortgage originators. I expect the originator to sort loans based on
excess yield spread and the amount of discount points paid if 1) transaction costs are
important in determining whether or not a particular mortgage is securitized; and 2) the
points-coupon combinations serves effectively as a screening device of borrower
transaction costs.
I first examine whether overvalued loans are more or less likely to be retained. I
do not impose an expected sign on this correlation. As long as loans are sorted based on
excess yield spread, transaction costs must be important in making securitization
decisions. I then see if discount points have a similar effect. If transaction cost is an
important consideration for making securitization decisions, then discount points and
excess yield spread should have a consistent effect on securitization decisions, as they are
alternative measures of transaction costs. On the other hand, if the originator emphasizes
73
mobility and sorts mortgage points based on it, discount points and excess yield spread
should exhibit opposite effects on the securitization decision. This is because paying
greater discount points signals lower mobility but high ―overvaluedness‖ is likely
associated with high mobility. It is unlikely the originator makes securitization decisions
based on mobility yet treats loans with more points and greater excess yield spread in a
similar manner. Such a behavior lacks logical consistency. Thus, I formulate the
following hypothesis:
H2: Securitization decisions made on loans originated with more discount points and
loans with greater excess yield spread are consistent.
Empirical Analysis
Data
The data comes from Ambrose, et al. (2005), and consist of event histories of
25,520 conventional fixed rate mortgages originated between January 1995 and
December 1997 and followed through October 2000. The data includes loans for
refinancing as well as loans for home purchase. For each mortgage in the sample, I have
relatively complete micro-level loan information and borrower characteristics. Available
loan information include the time and state of origination, loan amount, coupon rate,
loan-to-value (LTV) ratio, and, most importantly, discount points paid at the time of
origination. The data set also contains information on borrower characteristics such as
credit score, age, and income. Finally, the data set also has information on whether the
loan was subsequently retained in the originator’s portfolio, sold to the GSEs, or sold as
74
private label MBS. Table 3.1 reports the summary statistics on the loan characteristics of
the sample. A rather noticeable pattern is that the average discount points are consistently
higher for loans that are not securitized. The difference is quite substantial in 1996 (0.979
for retained verses 0.556 for securitized) and in 1997 (0.799 for retained verses 0.422 for
securitized). Both are significant at 1% level. Securitized loans appear to consistently
have to have relatively low LTV and higher borrower credit scores as compared to
portfolio loans (significant at 1% for all years). Borrower income is also greater on
average for securitized loans (significant at 1% for year 2005 and 10% for year 2007).
Excess Yield Spread and Prepayment
The available coupon-points combinations emerge from the mortgage market
equilibrium. Todd (2001) uses a simultaneous equation model to capture the fact that
mortgage rate and discount points schedule are jointly determined. I apply a similar
methodology and estimate the following simultaneous equations in order to determine
whether or not a particular loan is undervalued or overvalued.
sDISCPTSPREAD 1Xa')ln( 10 (3.15)
dSPREADDISCPT 2Xb')ln(10 (3.16)
SPREAD is the mortgage yield spread. Following Merton (1974) I define the mortgage
yield spread as the difference between the yield and the risk-free rate. Accordingly, I
proxy the yield spread using the effective mortgage yield calculated over a 10-year
holding period less the 10-year treasury rate, and DISCPT is the discount points recorded
as a percentage of original outstanding balance. a is a row vector of coefficients, and X1
75
is a vector of determinants of mortgage yield. Similarly, b is a row vector of coefficients,
and X2 is a vector of variables that explains the borrower’s selection of mortgage points.
s and d are respectively the standard errors from equation (3.15) and (3.16). All
variables are measured at loan origination.
I follow Ambrose, LaCour-Little, and Sanders (2004) to specify equation (3.15).
Merton (1974) suggests that the yield spread is a function of the volatility of state
variables (interest rate and housing values) as well as the LTV ratio at origination.
Therefore, I include in a the interest rate volatility (MORTVOL) and housing price
volatility (HPIVOL). MORTVOL is defined as the standard deviation of the monthly 30-
year conventional mortgage rate over the previous 24 months.31
(HPIVOL) is defined as
the standard deviation of OFHEO state-level quarterly housing price index over the
previous two years. I also control for LTV ratio at origination (LTV), and the market
expectation of future interest rates as measured by the term structure (YLDCURVE),
which is defined as the 10-year Treasury bond rate minus the 1-year Treasury bond rate. I
also include in the set of explanatory variables an array of loan-specific characteristics at
origination including borrower’s credit score (FICO), borrower’s income (INCOME), and
conforming loan status (CONFORM).32
Following Ambrose and Pennington-Cross (2000)
and Ambrose, et al. (2004), I control for differences in state law regarding mortgage
default and foreclosure by including a set of dummy variables that classify states based
31 I obtain the 30-year conventional mortgage rate from the Federal Reserve Bank of St. Louis.
32 Following Ambrose, et al. (2005), I classify a mortgage as conforming if it was sold to the agencies, or if
the borrower’s FICO score is above 660 and the loan amount was below the conforming loan limit in place
at time of origination and the LTV is either less than 80 percent or the loan has private mortgage insurance
if the LTV is greater than 80 percent.
76
on judicial versus non-judicial foreclosure laws and deficiency versus non-deficiency
judgment states. q1 indicates states that have nonjudicial foreclosure available and allow
lenders to obtain deficiency judgments; q2 indicates states that have nonjudicial
foreclosure available but do not allow deficiency judgments; q3 indicates states that
require judicial foreclosure and allow deficiency judgments; and finally q4 indicates
states that require judicial foreclosure and do not allow deficiency judgments. Finally, I
also control for time and geographic related variations. To capture seasonal market
changes of mortgage origination, I include year and month indicator variables, which
respectively denote the year and month of origination. I also control for regional fixed
effect by a set of indicator variables constructed based on HUD 10-region classification.33
I include in X2 variables that are influential on borrower’s selection of mortgage
points. First, borrowers make contract choices based on market conditions. Therefore, it
is reasonable to control for macroeconomic variables such as interest rate volatility
(MORTVOL), housing price volatility (HPIVOL) and yield curve (Y LDCURV E). Second,
the decision of paying discount depends on a borrower’s cash availability. Thus, I use
borrower’s income (INCOME) and the loan-to-value (LTV) ratio to control for the
availability of financial resource at the time of origination. Third, because conforming
loans are subject to a lower cost of borrowing, one would expect conforming loans are
less likely to be prepaid. Thus, I control for the conforming loan status (CONFORM).
Finally, Brueckner (1994) shows that the borrower’s age and income, property value, and
geographical location are significantly correlated with mobility. Hence, I control for
33 The ten regions are New England, New York/New Jersey, Mid-Atlantic, Southeast, Midwest, Southwest,
Great Plains, Rocky Mountain, Pacific/Hawaii, and Northwest/Alaska.
77
borrower’s age (BWRAGE) and regional dummy variables. I also include the square of
BWRAGE to control for potential non-linear effects. Similar to the SPREAD equation, we
control for time fixed effects. I identify equation (15) using borrower’s age (BWRAGE)
and its square term (BWRAGE2), because lenders are prohibited by the Fair Housing Act
of 1968 to impose different conditions on mortgages based on age.34
We identify (16)
using borrower’s credit score FICO, because borrowers with difference credit scores are
provided with the same coupon-points menu.35
Notice that the borrower’s desired amount of discount points may not always be
positive.36
In the data, I observe non-zero value of DISCPT only if the borrower demand
positive points, and demand for negative points are censored. To overcome this problem,
I estimate equation (3.15) and (3.16) via two-stage procedure. In step one, the reduced
form of equation (3.15) is estimated by ordinary least squares, and the reduced form of
equation (3.16) is estimated with a tobit specification. In step two, the structural
estimation of equation (3.15) and (3.16) is performed using the predicted values of
SPREAD and DISCPT from the first step.
Table 3.2 reports the estimated results. The negative and statistically significant
coefficients of DISCPT in equation (3.15) and ln(SPREAD) in equation (3.16) confirm
34 The validity of our instruments is strengthened by the results from the overidentification tests. For both
versions of Sargan’s (1958) and Basmann’s (1960) tests of overidentifying restrictions, we fail to reject the
null hypothesis that BWRAGE and BWRAGE2 are valid instruments.
35 We conduct the test proposed by Stock and Yogo (2001) to guard against weak instrument problem. Our
instrumental variables appear to be strongly correlated with the endogenous variables. The F-statistics of
the correlations between the endogenous independent variable and the instrumental variables are 24.24 and
360.43 respectively for equation (15) and equation (16), which suggest that the weak instrument problem is
unlikely to be a concern.
36 Lenders may help pay for the entire or a part of closing cost using yield spread premiums (YSP). This
can be viewed as one way for borrowers to take negative discount points.
78
the inverse correlation between interest rate and discount points. This result is consistent
with Brueckner (1994), who also finds evidence for the points-coupon tradeoff. I denote
the prediction error of (3.15) as excess yield spread (EXSPD), and propose it as a
measure of borrower search cost. A larger (smaller) value of EXSPD indicates the loan is
relatively overvalued (undervalued) and the borrower is likely to have high (low)
transaction costs.
To check the validity of EXSPD as a measure of transaction costs, I empirically
examine the correlation between excess yield spread and prepayment. As stated in
hypothesis 1, EXSPD can be a valid measure of transaction costs, only if it exhibits a
negative correlation with the likelihood of prepayment. I estimate a competing risk
hazard model following the methodology used in Ambrose and Sanders (2003). A
borrower has the option to prepay, default, or remain current for any given period. I treat
mortgages that are still current at the end of the observation period as censored. Thus, I
define )3,2,1( jT j as the latent duration for each mortgage to be terminated during the
observation period by prepaying, defaulting, or remaining current (censored). Thus, the
observed duration, , is the minimum of the jT .
Conditional on a set of explanatory variables, jx , which may include static loan
characteristics at the time of loan origination as well as time-varying economic conditions,
and parameters, j , the probability density function (pdf) and cumulative density
function (cdf) for jT are
));|(exp();|();|( jjjjjjjjjjjj xrIxThxTf (3.17)
79
);|(exp(1);|( jjjjjjjj xrIxTF (3.18)
where r is an integer variable taking values in the set {1, 2, 3} representing the three
possible outcomes, jI is the integrated hazard for outcome j:
jT
jjjjjjj xshxTI0
);|();|( (3.19)
where jh is the hazard function.
The joint distribution of the duration and outcome is
));|(exp();|();|( 0 jjjjjjjjjjj xIxhxf (3.20)
where ),,( 321 xxxx and ),,( 321 and
3
1
0
j
jII is the aggregated
integrated hazard. Thus, the conditional probability of an outcome is
3
1
);|(
);|();,|Pr(
j
jj
jj
xh
xhxj
(3.21)
I assume a separate exponential hazard function for each mortgage outcome and estimate
(3.21) under a multinomial logit framework.
I include in the competing risk hazard model other factors that may impact
mortgage default and prepayment. In the contingent claim framework, the FRM contract
contains a prepayment option and a default option. A borrower minimizes the market
value of his outstanding loan via strategically exercising these two options. To capture
how much the prepayment option is ―in-the-money‖, I include in jx a variable, tRATE ,
which is defined as
m
t
m
t
c
tt
r
rrRATE
(22)
80
Where c
tr is contract rate at time t, and m
tr is the 30-year conventional mortgage rate at
time t. A relative increase in tRATE increases the likelihood of prepayment.
Theoretical mortgage literature indicates that the intrinsic values of the default
and prepayment options are jointly determined. The relative position of the default option
affects borrower refinancing strategy. Specifically, declines in property values increase
the probability of default and reduce the probability of prepayment. To account for the
competing nature of default and prepayment risk, I control for contemporary loan-to-
value (LTV) ratio, CLTV, which is computed as the ratio of the market value of the loan
to the market value of the property.
As suggested by Kau, et al. (1992, 1993), interest rate volatility also plays a
critical role in determining the value of the prepayment option. Hence, I account for
interest rate volatility by including the variable MORTVOL.I also control for housing
price volatility by include the variable HPIVOL. Following Ambrose and Sanders (2003),
I control for market expectation on future interest rate by including the slope of yield
curve (YLDCURVE).
I also control for array of loan and borrower characteristics at loan origination,
such as discount points (DISCPT), the loan-to-value ratio (LTV), borrower’s age
(BRWAGE), income (INCOME) and credit score (FICO) at origination. I include the set
of legal variables (q1-q4), constructed based on judicial versus non-judicial foreclosure
laws and deficiency versus non-deficiency judgment states, to control for differences in
legal environment. Finally, I control for time and regional fixed effects.
81
Table 3.3 presents the results of the competing risk hazard model. Consistent with
the first hypothesis, I observe a negative correlation between EXSPD and the probability
of prepay (significant at 1% level). This result shows that the effect of transaction costs in
determining EXSPD is likely dominating that of mobility, which tends to weaken the
observed association. The other interesting finding is that EXSPD increases the likelihood
of default (significant at 1% level). This result echoes previous studies that find that
borrowers with overpriced properties are more likely to become delinquent, default, or
experience foreclosure.37
It is consistent with the intuition that borrowers with less
experience, information, and bargaining power tend to pay a price premium in both
property and financial markets.
I further test my measurement by investigating the sensitivity of prepayment to
market interest rate fluctuations. The model predicts that borrowers with higher
transaction cost require greater rate reductions to cover their high cost of refinancing
before interest-rate motivated prepayment takes place. Hence, the prepayment behavior
of loans with greater EXSPD should be less sensitive to declining interest rate.
Operationally, I modify the competing risk hazard model by including an interaction term
of EXSPD and ΔRATE to capture the sensitivity of prepayment to interest rate. ΔRATE
indicates how much the prepayment option is ―in-the-money‖, which is positively related
to likelihood of refinance increases. This property is theoretically shown by option-based
mortgage models and also extensively documented by empirical studies on mortgage
termination. I are, however, interested in how this dependence varies across mortgages
37 See Calem and Wachter (1999), LaCour-Little and Malpezzi (2003), Noordewier, Harrison and
Ramagopal (2001), and Ong, Neo, and Spieler (2006).
82
with distinct ―overvaluedness‖. Specifically, I expect that mortgages with greater EXSPD
should have a smaller marginal change in the likelihood of refinance. Because borrowers
who overpaid for their loans have higher refinancing costs, they should wait for a
relatively larger interest rate reduction before they refinance. To capture this sensitivity, I
modify the original competing risk hazard model by creating an interaction term between
EXSPD and ΔRATE. The estimated coefficient of RATEEXSPD pinpoints this
differential marginal effect, and the model is supported if this coefficient is negative. To
examine other potential effects of transaction costs on the default and prepayment options,
I also include in the model interaction terms between EXSPD and the default option
)( CLTVEXSPD , interest rate volatility )( MORTVOLEXSPD , and housing price
volatility )( HPIVOLEXSPD .
Column 3 and 4 of Table 3.3 presents the results of the competing risk hazard
model investigating the sensitivity of refinance to interest rate. Consistent with the
hypothesis, the coefficient of RATEEXSPD is significantly negative (significant at 1
percent level). It shows that high-cost borrowers (the ones with overvalued mortgages)
are in fact less responsive to market interest rate reduction. This result is consistent with
Chang and Yavas (2009), who argue that the points-coupon trade-off is a viable screening
device for asymmetric transaction costs. They show that high-cost borrowers are less
likely to refinance, and when they do, they wait for a relative larger interest reduction as
opposed to others who did not pay points.
Consistent with empirical mortgage literature, I find support for the ―jointness‖ of
prepayment and default option. A larger interest rate reduction )( tRATE increases the
83
probability of prepayment but reduces the probability of default (both significant at 1%
level). Contemporary LTV (CLTV) reduces the likelihood of prepay (significant at 1%
level) but fails to exhibit a significant effect on default. I also find that loan and borrower
characteristics play an important role in determining default and prepayment risk.
Consistent with previous literature, I find that discount points (DISCPT) lead to reduced
probability of prepayment (significant at 1% level). Mortgages with high LTV ratios are
more likely to default and less likely to prepay (both significant at 1% level). Not
surprisingly, borrowers with better credit scores are more likely to prepay and less likely
to default (both significant at 1% level). Older borrowers are less likely to prepay
(significant at 1% level). High-income borrowers are more likely to prepay (significant at
1% level) and less likely to default (significant at 10% level). Finally, conforming loans
are associated with reduced probabilities of both default and prepayment (both significant
at 1% level).
Mortgage Points, Excess Yield Spread and Securitization Decisions
I now turn to testing the second hypothesis. To determine the probability that a
mortgage will be retained by the originator, I estimate the following logit model:
ZC ')1Pr( 110 DISCPTDISCPTPortfolio (3.23)
where DISCPT and EXSPD are the two measures of borrower transaction costs, and Z is
a set of control variables. If mortgages are sorted by the originator based on transaction
costs, one would expect 1 and 2 to have the same sign. A positive (negative)
correlation indicates that the originator tends to retain loans held by borrowers with high
84
(low) transaction costs. On the other hand, it may also be the case that 1 and 2 are
insignificant or having opposite signs. In this case, I would fail to find support to the
hypothesis that securitizations are made based on transaction costs.
Following Ambrose, et al. (2005), I also control for other factors that may have
impact on securitization decisions. I include in equation (3.23) macroeconomic variables
such as slope of the yield curve (YLDCURVE), interest rate volatility (MORTVOL), and
housing price volatility (HPIVOL). I also control for loan and borrower characteristics
including LTV ratio (LTV ), borrower’s credit quality (FICO), age (BWRAGE), income
(INCOME) and conforming loan status (CONFORM). I control for legal environment
using a set of legal variables (q1-q4), constructed based on judicial versus non-judicial
foreclosure laws and deficiency versus non-deficiency judgment states. Finally, I also
include regional and year dummy variables to control for time and regional fixed effects
(not reported).
Dionne, Gouriéroux, and Vanasse (2001) suggest that empirical evidence of
adverse selection takes the form of ―conditional dependence.‖ It would be preferable to
control for expected contractual choices in order to address potential problems of
misspecification. Thus, I include the predicted discount points PTCDIS ˆ estimated from
(3.15) and (3.16) as a control variable when estimating (3.23).
I find strong evidence that securitization decisions are made based on borrower’s
transaction costs. Both of the transaction costs measures EXSPD and DISCPT are highly
significant when included separately (column 1 and 2) and jointly (column 3) to explain
securitization decisions (all significant at 1% level). The positive association between
85
being retained in the originator’s portfolio and the transaction costs measures suggests
that the originator prefers loans held by high-cost borrowers. This result is also consistent
with Ambrose et al. (2005) who find that loans being retained are less likely to prepay. In
addition, I find that loans with high LTV and low borrower income are more likely to be
retained (both at 1% level). Not surprisingly, conforming loans are more likely to be
securitized.
Summary of Findings
I develop a theoretical model to show that transaction costs play an important role in
shaping mortgage market equilibrium. Specifically, when borrowers are different in their
cost of refinancing, there exists a separating equilibrium such that high-cost borrowers
pay more points to obtain a lower interest rate, and low-cost borrowers pay fewer points.
I further examine the empirical importance of heterogeneous refinancing cost. I find that
overvalued mortgages are less likely to be prepaid, and the prepayment pattern appears to
be less responsive to market interest rate reductions. This result suggests that borrower
costs of refinancing plays more critical role than expected mobility in determining the
likelihood of overpaying for a mortgage. Hence, loan overvaluedness can be valid
measure of refinancing costs. Furthermore, I find that mortgages with more points and
overvalued loans are both more likely to be retained in the originator’s portfolio. This
result indicates that the consideration of refinancing costs appear to have a greater impact
than mobility in determining the originator’s securitization decisions.
86
Figure 3.1: Mortgage-Points Choice with Asymmetric Information
This figure illustrates the mortgage market equilibrium with information
asymmetry regarding refinancing cost. Solid lines show zero-profit curves of the lender
for high-cost borrower (type h) and low-cost borrower (type l). Dashed lines are borrower
indifference curves. Low-cost borrower receives contract ),( *
0
* ll is , which corresponds to
the tangency points between the lowest indifference curve and the zero-profit curve;
high-cost borrower receives contract ),( 0
hh is which is located where the low-cost
indifference curve passing through ),( *
0
* ll is cuts the high-cost zero-profit curve.
87
Table 3.1: Descriptive Statistics
This table presents the descriptive statistics of our sample. DISCPT is discount points paid at
origination. LTV is the loan-to-value ratio. FICO is borrower’s credit score. BRWAGE is borrower’s age.
INCOME is borrower’s income. We compare portfolio loans and securitized loans. Panel 1, 2, and 3
respectively show the comparison for loans originated in year 1995, 1996, and 1997. t-statistics and the
corresponding p-value on mean differences between portfolio loans and securitized loans are shown in
column 6 and 7.
Year of Origination: 1995
Portfolio Securitized
Mean Std. Dev Mean Std. Dev t-stat. p-value
DISCP T 0.643 0.799 0.604 0.852 -0.841 0.400
LT V 88.933 13.029 77.62 17.146 -
12.202 0.000 F ICO 694.362 62.774 717.405 58.598 7.156 0.000 BRW AGE 35.763 9.682 40.584 11.348 7.823 0.000 INCOME 52.574 55.267 63.609 59.034 3.428 0.000
% of Prepay 60.71% 43.73% % of Default 12.09% 4.20%
% of Still Current 27.20% 52.07% # of Observation 364 5875
Year of Origination: 1996
Portfolio Securitized
Mean Std. Dev Mean Std. Dev t-stat. p-value
DISCP T 0.979 0.842 0.556 0.8 -6.747 0.000 LT V 82.526 16.355 74.244 15.784 -5.97 0.000 F ICO 708.167 60.9 722.572 55.183 3.326 0.000 BRW AGE 40.421 11.448 41.757 11.315 1.491 0.136 INCOME 73.222 177.083 80.444 84.703 1.042 0.298
% of Prepay 39.29% 47.61% % of Default 9.52% 3.23%
% of Still Current 51.19% 48.39% # of Observation 168 5830
Year of Origination: 1997
Portfolio Securitized
Mean Std. Dev Mean Std. Dev t-stat. p-value
DISCP T 0.799 0.846 0.422 0.733 -7.44 0.000 LTV 79.177 16.808 74.244 15.784 -4.521 0.000 F ICO 696.906 67.227 722.724 55.305 6.735 0.000 BRW AGE 42.829 12.934 41.998 11.208 -1.062 0.288 INCOME 75.762 74.694 89.385 118.291 1.675 0.094
% of Prepay 33.33% 32.84% % of Default 10.33% 4.36%
% of Still Current 56.34% 62.79% # of Observation 213 13358
88
Table 3.2: Estimation of Excess Yield Spread
This table reports the two-stage regression estimates of the following system of equations.
sDISCPTSPREAD 1Xa')ln( 10
dSPREADDISCPT 2Xb')ln(10
SPREAD is the effective mortgage yield calculated over a 10-year holding period less the 10-year treasury.
DISCPT is discount points paid at origination. MORTVOL is the standard deviation of the monthly 30-year
conventional mortgage rate over the previous 24 months. HPIVOL is the standard deviation of OFHEO
state-level housing price index over the previous 24 months. LTV is the loan-to-value ratio. YLDCURVE
measures market expectation of future interest rate, which is defined as the 10-year Treasury bond rate
minus the 1-year Treasury bond rate. FICO is borrower’s credit score. INCOME is borrower’s income.
CONFORM is a dummy variable indicating conforming loan status (1 = Yes, 0 = No). BRWAGE is
borrower’s age. PROPVAL is the value of property at origination. q1-q4 are dummy variables constructed
based on judicial versus non-judicial foreclosure laws and deficiency versus non-deficiency judgment states.
Variable Estimate Std. Err. t-stat P > t
SPREAD Equation
DISCPT -0.620 0.087 -7.100 0.000
MORTVOL 0.177 0.155 1.150 0.252
HPIVOL 0.008 0.002 3.350 0.001
LTV -0.001 0.000 -4.340 0.000
YLDCURVE -0.115 0.042 -2.720 0.006
FICO 0.000 0.000 0.640 0.519
INCOME 0.000 0.000 -4.940 0.000
CONFORM -0.107 0.011 -9.650 0.000
q2 0.028 0.014 2.000 0.046
q3 0.104 0.020 5.090 0.000
q4 0.239 0.043 5.620 0.000
Intercept 0.690 0.103 6.720 0.000
DISCPT Equation
ln(SPREAD) -1.302 0.338 -3.850 0.000
MORTVOL 1.357 0.337 4.030 0.000
HPIVOL 0.015 0.005 3.040 0.002
LTV -0.005 0.001 -8.970 0.000
YLDCURVE -0.211 0.118 -1.790 0.074
INCOME -0.001 0.000 -9.450 0.000
CONFORM -0.205 0.026 -7.840 0.000
BRWAGE 0.016 0.004 3.880 0.000
BRW AGE2 0.000 0.000 -3.360 0.001
q2 0.135 0.030 4.440 0.000
q3 0.283 0.025 11.130 0.000
q4 0.638 0.066 9.710 0.000
Intercept -0.132 0.333 -0.390 0.693
89
Table 3.3: Competing-Risks Hazard Model of Mortgage Termination Outcomes
The competing risks model is estimated as a multinomial logit model assuming a quadratic
baseline hazard function. EXSPD is excess yield spread estimated from (3.15) and (3.16). ΔRATE is
defined as the mortgage rate reduction as a percentage of current market rate. CLTV is the ratio of the
market value of the loan to the market value of the property. MORTVOL is the standard deviation of the
monthly 30-year conventional mortgage rate over the previous 24 months. HPIVOL is the standard
deviation of OFHEO state-level housing price index over the previous 24 months. DISCPT is discount
points paid at origination. YLDCURVE measures market expectation of future interest rate, which is
defined as the 10-year Treasury bond rate minus the 1-year Treasury bond rate. LTV is the loan-to-value
ratio. FICO is borrower’s credit score. BRWAGE is borrower’s age. INCOME is borrower’s income.
CONFORM is a dummy variable indicating conforming loan status (1 = Yes, 0 = No). q1-q4 are dummy
variables constructed based on judicial versus non-judicial foreclosure laws and deficiency versus non-
deficiency judgment states. MONTH is the number of month since origination. Standard errors are shown in
parentheses below each regression coefficient. One, two, and three asterisks respectively denote
significance at 10%, 5%, and 1% level.
(1) (2)
Variable Prepay Default Prepay Default
EXSPD -0.198 1.136 1.518 0.152
(0.070)*** (0.207)*** (0.348)*** (0.820)
ΔRAT E 5.662 -1.264 5.817 -1.337
(0.130)*** (0.365)*** (0.133)*** (0.369)***
CLTV -0.604 0.428 -0.439 0.009
(0.224)*** (0.596) (0.245)* (0.871)
MORTVOL -3.325 -4.925 -3.213 -4.967
(0.156)*** (0.524)*** (0.158)*** (0.524)***
HPIVOL 0.044 0.097 0.046 0.096
(0.005)*** (0.015)*** (0.005)*** (0.015)***
EXSPD × ΔRAT E
-2.676 1.968
(0.596) (1.575)
EXSPD × CL V
-1.683 3.492
(1.309)*** (3.771)
EXSPD × MORTVOL
-3.073 1.477
(0.798)* (1.904)
EXSPD × HP IVOL
-0.044 0.059
(0.023)*** (0.058)
DISCPT -0.158 -0.081 -0.149 -0.086
(0.016)*** (0.042)* (0.016)*** (0.042)**
YLDCURVE -0.979 -1.272 -0.966 -1.281***
(0.045)*** (0.155)*** (0.045)*** (0.155)
90
Table 3.3: Competing-Risks Hazard Model of Mortgage Termination Outcomes (Cont.)
The competing risks model is estimated as a multinomial logit model assuming a quadratic
baseline hazard function. EXSPD is excess yield spread estimated from (3.15) and (3.16). ΔRATE is
defined as the mortgage rate reduction as a percentage of current market rate. CLTV is the ratio of the
market value of the loan to the market value of the property. MORTVOL is the standard deviation of the
monthly 30-year conventional mortgage rate over the previous 24 months. HPIVOL is the standard
deviation of OFHEO state-level housing price index over the previous 24 months. DISCPT is discount
points paid at origination. YLDCURVE measures market expectation of future interest rate, which is
defined as the 10-year Treasury bond rate minus the 1-year Treasury bond rate. LTV is the loan-to-value
ratio. FICO is borrower’s credit score. BRWAGE is borrower’s age. INCOME is borrower’s income.
CONFORM is a dummy variable indicating conforming loan status (1 = Yes, 0 = No). q1-q4 are dummy
variables constructed based on judicial versus non-judicial foreclosure laws and deficiency versus non-
deficiency judgment states. MONTH is the number of month since origination. Standard errors are shown in
parentheses below each regression coefficient. One, two, and three asterisks respectively denote
significance at 10%, 5%, and 1% level.
(1) (2)
Variable Prepay Default Prepay Default
LTV -0.006 0.007 -0.006 0.007
(0.001)*** (0.002)*** (0.001)*** (0.002)***
FICO 0.002 -0.010 0.002 -0.010
(0.000)*** (0.000)*** (0.000)*** (0.000)***
BRWAGE -0.014 0.000 -0.014 0.000
(0.001)*** (0.003) (0.001)*** (0.003)
INCOME 0.000 -0.002 0.000 -0.002
(0.000)*** (0.001)*** (0.000)*** (0.001)***
CONFORM -0.231 -0.318 -0.229 -0.318
(0.024)*** (0.075)*** (0.024)*** (0.075)***
q2 0.287 -0.041 0.285 -0.041
(0.042)*** (0.147) (0.042)*** (0.147)
q3 -0.187 0.075 -0.184 0.073
(0.036)*** (0.113) (0.036)*** (0.113)
q4 -0.366 0.540 -0.368 0.539
(0.097)*** (0.268)** (0.097)*** (0.269)**
MONTH 0.066 0.109 0.066 0.110
(0.003)*** (0.009)*** (0.003)*** (0.009)***
MONTH2 -0.001 -0.001 -0.001 -0.001
(0.000)*** (0.000)*** (0.000)*** (0.000)***
Intercept -4.594 0.455 -4.641 0.464
(0.193)*** (0.571) (0.194)*** (0.572)
91
Table 3.4: Mortgage Points, Excess Yield Spread, and Securitization Decisions
This table presents the estimates of the logit regression examining the relation between securitization decision
and discount points structures. The dependent variable is whether or not a mortgage was retained in the originator’s
portfolio (1 = Yes, 0 = No). EXSPD is excess yield spread estimated from (3.15) and (3.16). DISCPT is discount points
paid at origination. MORTVOL is the standard deviation of the monthly 30-year conventional mortgage rate over the
previous 24 months. HPIVOL is the standard deviation of OFHEO state-level housing price index over the previous 24
months. LTV is the loan-to-value ratio. FICO is borrower’s credit score. YLDCURVE measures market expectation of
future interest rate, which is defined as the 10-year Treasury bond rate minus the 1-year Treasury bond rate. BRWAGE
is borrower’s age. INCOME is borrower’s income. CONFORM is a dummy variable indicating conforming loan status
(1 = Yes, 0 = No). q1-q4 are dummy variables constructed based on judicial versus non-judicial foreclosure laws and
deficiency versus non-deficiency judgment states. Standard errors are shown in parentheses below each regression
coefficient. One, two, and three asterisks respectively denote significance at 10%, 5%, and 1% level.
Variable (1) (2) (3)
EXSPD 2.002 2.435
(0.242)*** (0.251)***
DISCPT 0.280 0.383
(0.044)*** (0.045)***
MORTVOL -0.187 0.902 -0.155
(1.595) (1.621) (1.637)
HPIVOL 0.040 0.042 0.038
(0.029) (0.030) (0.030)
LTV 0.018 0.020 0.019
(0.004)*** (0.004)*** (0.004)***
FICO -0.002 -0.002 -0.002
(0.001)** (0.001)* (0.001)**
YLDCURVE 1.051 0.987 1.078
(0.341)*** (0.339)*** (0.347)***
BRWAGE 0.007 0.007 0.007
(0.005) (0.005) (0.005)
INCOME -0.009 -0.008 -0.008
(0.001)*** (0.001)*** (0.001)***
CONFORM -2.357 -2.292 -2.304
(0.135)*** (0.137)*** (0.140)***
DÎCSPT -0.830 -0.902 -0.878
(1.060) (1.080) (1.108)
q2 -0.858 -0.825 -0.849
(0.236)*** (0.234)*** (0.244)***
q3 -0.577 -0.539 -0.600
(0.284)** (0.288)* (0.295)**
q4 0.606 0.448 0.472
(0.562) (0.567) (0.583)
Intercept -2.841 -3.644 -2.959
(0.787)*** (0.807)*** (0.806)***
N 25,808 25,520 25,520
Pseudo R2 0.221 0.214 0.225
92
Chapter 4
Bad Borrowers or Bad Loans? The Effect of Information
Asymmetry on the Choice of Prepayment Penalty
A mortgage contract often involves restrictions on prepayment. One such
restriction is the prepayment penalty. A prepayment penalty is a charge that a lender
makes when a borrower prepays the entire or a significant part of loan balance.
Conventional wisdom considers charging prepayment penalties as a way to reduce the
likelihood that lenders will have to reinvest the prepaid mortgage balance at a lower rate
(Ling and Archer, 2008). While commercial mortgage contracts in the United States
usually stipulate some form of restriction on prepayment, prepayment penalties on
residential mortgages have been a much more controversial topic. Extensive debate has
focused on the economic fairness of prepayment penalties. In other words, do borrowers
who accept prepayment penalties receive commensurate benefit? A prepayment penalty
reduces the value of a borrower’s prepayment option. As a trade-off, a mortgage with a
prepayment penalty usually has a lower interest rate than a contract without one.38
A
number of previous studies suggest that the offsetting economic benefit (e.g., lower
interest rate) is generally not sufficient to compensate the loss from the inability to
refinance.39
Other studies document that loans that have a prepayment penalty are
associated with more delinquencies, defaults, and property foreclosures.40
As a result,
38 See DeMong and Burroughs (2005) and LaCour-Little and Holmes (2008).
39 See Goldstein and Son (2003) and LaCour-Little and Holmes (2008).
40 See Danis and Pennington-Cross (2007) and Quercia, Stegman, and Davis (2007).
93
prepayment penalties have been viewed by many housing and consumer activists as being
―predatory‖ in nature. In light of the current housing crisis, prepayment penalties appear
to be extremely disturbing because predatory loans, such as the ones with prepayment
penalties, not only erode household wealth but also exacerbate foreclosure risk (Quercia
et al. 2007). In this study, I refer to the view that prepayment penalties increase default
risk as the predation hypothesis.
However, some economists argue that prepayment penalties may be welfare-
enhancing. For example, Chomsisengphet and Pennington-Cross (2006) point out that
prepayment penalties extend the duration of loans, reduce the loan-to-value (LTV) ratios,
and mitigate default risk. Mayers, Piskorski and Tchistyi (2009) show that prepayment
penalties improve welfare by ensuring longer-term lending contracts. In an environment
where borrowers’ creditworthiness stochastically evolves over time, longer-term
contracts help lenders insure against the risk that mortgage pools become
disproportionately composed of risky borrowers. The authors show that prepayment
penalties are particularly beneficial to risky borrowers by reducing default risk and the
cost of borrowing. Both studies suggest that prepayment penalties may help borrowers
reduce costs of borrowing and default risk. Of course, this view contradicts the
empirically observed positive correlation between prepayment penalties and default risk.
I reconcile these two opposite views by considering borrowers’ choice of
prepayment penalties under information asymmetry. I formulate the information
asymmetry hypothesis that borrowers with different risk profiles make separate choices
regarding prepayment penalties. Specifically, when income uncertainty is private
information known only to the borrower, I show that there exists a separating equilibrium
94
such that borrowers with high default risk select mortgage contracts with a prepayment
penalty and receive a low contract rate, and vice versa. Thus, the positive correlation
between prepayment penalties and mortgage delinquencies, defaults, and foreclosures
does not necessarily imply that prepayment penalties elevate default risk. It may simply
reflect the fact that borrowers who are intrinsically riskier tend to select loans with a
prepayment penalty. The model predicts a positive correlation between default risk and
prepayment penalties, which is consistent with empirical evidence. Furthermore, the
welfare implications of the model align with Chomsisengphet and Pennington-Cross
(2006) and Mayers, et al., (2009). Prepayment penalties can improve consumer welfare
by serving as a screening device of borrowers’ default and prepayment risks.
Borrowers with distinct risk profiles may value the prepayment option differently.
This heterogeneity can emerge from common residential mortgage underwriting practices.
Typically, borrower income levels are used as one of the important criteria in residential
mortgage underwriting for determining a borrower’s qualification. The ability to afford
periodic payments depends on earning capability. For example, the Federal Home Loan
Mortgage Corporation (FHLMC) guidelines require housing expenses to be less than 25
percent of annual stabilized income. Although the ―25-percent rule‖ ensures affordability
based on current income, future income may be unpredictable. Previous studies have
considered mortgage defaults triggered by reduced future income (Posey and Yavas,
2000, Harrison, Noordewier and Yavas, 2004). However, an often overlooked fact is that
income levels are also a crucial determinant of prepayment probabilities. A borrower
considering refinancing must first qualify for a new loan. Although a borrower may wish
to refinance when the prepayment option is sufficiently ―in-the-money,‖ his ability to do
95
so may be impeded by insufficient income (Archer, Ling, and McGill, 1996). Thus,
compromised financial strength may not only trigger defaults, it can also undermine the
qualification for obtaining a refinance loan. In other words, mortgage underwriting based
on borrower income essentially ties default and prepayment together. When facing the
penalty-coupon trade-off, borrowers with a greater probability of suffering future income
reduction (high-risk borrowers) would rationally accept a prepayment penalty and benefit
from a lower contract rate. The intuition is that with a greater chance of being ineligible
for a new loan, the borrower is less willing to pay an interest rate premium to maintain an
unconstrained prepayment option. Because of this self-selection mechanism, mortgages
with prepayment penalties tend to default more frequently.
I test the prediction of my model using a sample of securitized subprime
mortgages, which contains both loans with and without a prepayment penalty. In the
sample, all prepayment penalties expire within a relatively short period of time (e.g., one,
two, or three years). I find that the positive correlation between prepayment penalties and
default rates is attributable to information asymmetry. The option-based mortgage pricing
literature suggests that the values of the prepayment option and default options are jointly
determined. To eliminate the confounding effect that prepayment penalties may increase
default risk through limiting the value of prepayment option, I examine mortgages that
survive beyond the prepayment penalties’ expiration dates. Variation on mortgage
terminations after the expiration dates are unlikely to be affected by the prepayment
penalty. I then compare the termination outcomes between loans with and without a prior
prepayment penalty. I find that loans that had a prior prepayment penalty continue to
96
default at a higher rate even after their prepayment penalties expired. This result supports
the information asymmetry hypothesis.
Literature Review
The current study relates to three streams of literature: 1) prepayment penalty and
subprime lending, 2) mortgage choice under information asymmetry, and 3) empirical
tests for adverse selection. In this section, I review relevant previous literature in these
three areas and discuss how the current study contributes to each of them.
Prepayment Penalty and Subprime Lending
This study joins the growing body of literature on subprime mortgage lending.
Since the majority of subprime loans contain prepayment penalties, it is important to
examine the effects of prepayment penalties on loan performance and consumer
welfare.41
Through simple calculation, Goldstein and Son (2003) assert that the costs of
prepayment penalties substantially outweigh benefits over a two- to three-year period.
Using Monte Carlo simulation, LaCour-Little and Holmes (2008) confirm this result by
showing that the interest rate reduction associated with prepayment penalties is
significant, but in general, not large enough to compensate borrowers’ losses from
foregone refinancing opportunities. A potential shortcoming of these studies is to assume
all borrowers are able to refinance at will. Archer, Ling, and McGill (1996) find that
41 Standard & Poor’s (2004) reports that about 80 percent of subprime loans contain prepayment penalties
as of 2000. The substantial use of prepayment penalty is also confirmed by Elliehausen, Staten, and
Steinbuks (2008), who reported 60 percent of subprime loans in their sample contain prepayment penalty.
97
household income and collateral constraints undermine a borrower’s ability to exercise
the prepayment option. Overlooking those constraints fact may result in overestimating
the costs of prepayment penalties and lead to the conclusion that prepayment penalties
are unreasonably expansive. Indeed, my model indicates that borrowers who anticipate
being constrained by insufficient future income will select prepayment penalties. Because
they are less likely to qualify for a refinance loan in the first place, the cost of accepting a
prepayment penalty is low.
Danis and Pennington-Cross (2007) find that prepayment penalties tend to reduce
prepayment rates and, at the same time, are associated with higher likelihood of
delinquencies and defaults. The linkage between prepayment penalties and high credit
risk is confirmed by Quercia et al. (2007), which shows residential properties financed
through mortgages with a prepayment penalty are significantly more likely to experience
foreclosures. The authors view prepayment penalties as predatory in nature and argue that
they have the potential not only to erode household wealth but also to heighten the
negative impacts on individuals, households, and communities associated with
foreclosure (Quercia et al. 2007). The authors further suggest that the Home Ownership
and Equity Protection Act of 1994 (HOEPA), which allows for prepayment penalties up
to five years, may not be stringent enough to protect home owners. This desire for
intensified regulation, such as prohibiting or limiting prepayment penalties, was echoed
by many housing and consumer activists.42
42 See LaCour-Little and Holmes (2008) for a summary.
98
If prepayment penalties significantly increase the odds of mortgage delinquencies,
defaults and property foreclosures, the wide use of prepayment penalties in the subprime
mortgage market would appear to be extremely disturbing. First, property foreclosures
dampen homeownership rates. Many previous studies have shown that greater
homeownership rates benefit society through at least three channels. Homeownership, as
opposed to renting, facilitates the supply of public goods (e.g. lower crime rates,
neighborhood aesthetics etc.), encourages civic participation, and improves attainments
of children.43
Second, concerns about massive mortgage defaults are further escalated by
recent the empirical finding that mortgage defaults and property foreclosures tend to be
―contagious‖.44
If so, a causal relation between a prepayment penalty and higher default
rates would potentially imply additional negative externalities on nearby properties. Does
prohibiting prepayment penalties help reduce the default rate? This is one of the
questions I explore in this Chapter.
Although prepayment penalties may be abused by lenders in some occasions,
there are good reasons why they exist. There are two possible channels through which
prepayment penalties may be welfare-enhancing. First, by ensuring longer-term lending
relations, prepayment penalties reduce mortgage rates and extend credits to a greater
number of borrowers (Chomsisengphet and Pennington-Cross 2006, and Mayers, et al.
2009). Second, similar to many other contractual features, prepayment penalties can
mitigate information asymmetry by serving as a screening device. In corporate finance
43 Green (2001) provides an excellent summary on empirical evidence supporting the beneficial effects of
homeownership.
44 See Lin, Rosenblatt, and Yao (2008), Schuetz, Been, and Ellen (2008), and Agarwal, Ambrose,
Chomsisengphet, and Sanders (2011).
99
literature, the choice of callable debts has been considered as a positive signal of better
firm perspective (Robin and Schatzberg, 1986). One could view avoiding a prepayment
penalty as being analogous to choosing callable debt. I emphasize the beneficial effect of
prepayment penalties in reducing information asymmetry by deriving a separating
equilibrium that emerges from borrowers’ self-selection. This result suggests that the
positive correlation between prepayment penalties and mortgage delinquencies, defaults,
and property foreclosures should not be taken as supporting evidence for limiting or
prohibiting prepayment penalties. I show that prepayment penalties are welfare-
enhancing in reducing information asymmetry in the mortgage market.
Mortgage Choice under Information Asymmetry
The current study is also directly related to the mortgage-choice literature that
examines the screening roles of mortgage products. Many contractual features have been
extensively studied under the Rothschild and Stiglitz framework (1976) for their
screening functions of default and prepayment risk. For example, screening devices for
default risk include the loan-to-value (LTV) ratio (Brueckner 2000, Harrison, Noordewier,
and Yavas 2004), the ARM-FRM choice (Posey and Yavas, 2000), and loan maturity
(Ben-Shahar, 2006). Discount points (Dunn and Spatt 1985, Chari and Jagannathan 1986,
Yang 1992, Brueckner 1994, LeRoy 1996, and Stanton and Wallace 1998), and the
ARM-FRM choice (Brueckner 1992) are studied for their role of inducing self-selection
based on expected mobility.
100
Previous studies in this area often examine a single risk dimension: prepayment
risk or default risk. However, one borrower characteristic, such as expected future
income, can affect both prepayment and default risks. While income reduction is often
viewed as one of the important ―trigger events‖ of mortgage defaults, its impact on
prepayment risk has received little attention. I extend the mortgage-choice literature by
examining the effects of expected income uncertainty on both prepayment and default
risks within a unified framework.
Empirical Tests for Adverse Selection
This study also relates to literature that empirically tests adverse selection. One
critical implication of Rothschild and Stiglitz (1976) is that the insurance coverage choice
should be positively correlated with ex post risk occurrences. Based on this prediction,
numerous studies test for information asymmetry by implementing the ―positive
correlation‖ test.45
Most of these studies concentrate on insurance markets and examine
data on coverage choices and subsequent claims. For example, evidence of information
asymmetry has been identified in the health insurance market (Cutler and Zeckhauser,
2000), automobile insurance market (Cohen, 2005), and annuity market (Finkelstein and
Poterba, 2002). The current study contributes to this area of literature by examining
information asymmetry in the residential mortgage market.
45 The term was first used in Chiappori et al. (2006); it refers to the test of a positive correlation between
contractual choices and risk occurrences.
101
One potential limitation of the ―positive correlation‖ test is its inability to
distinguish adverse selection from moral hazard. Adverse selection indicates that
heterogeneous risk profiles induce different contract choices. In contrast, moral hazard
posits an exactly opposite causal relation: contractual features, such as a greater insurance
coverage, cause riskier behaviors. Unfortunately, a positive correlation between insurance
coverage and risk occurrences is consistent with both adverse selection and moral hazard.
Only a handful of studies focus on distinguishing adverse selection from moral hazard.
For example, Abbring, Chiappori, and Pinquest (2003) and Israel (2004) find evidence of
moral hazard by exploiting dynamic panel data with exogenous changes in insurance
prices. Karan and Zinman (2005) design a field experiment to disentangle adverse
selection and moral hazard.
The current study confronts a rather similar challenge. While I argue that hidden
risk types determine mortgage choices, it is also possible that a prepayment penalty, if
chosen, may increase the likelihood of default. According to the option-based mortgage
pricing literature, the values of a borrower’s default and prepayment options are ―jointly‖
determined (Kau, Keenan, Mueller, and Epperson, 1992 and 1993). Because the exercise
of one option inevitably eliminates the other, limiting the value of the prepayment option
via a prepayment penalty increases the default probability. On this ground, one could
argue that prepayment penalties can elevate default risk. To show the presence of
information asymmetry, I exploit the fact that loan performance is still observable after
prepayment penalties expire. To rule out the potential causal effect of prepayment
penalties on loan performance, I focus on loan terminations in time periods when
prepayment penalties are no longer effective.
102
The Model
The Setup
Consider a competitive lending market in which lenders offer fixed-rate mortgage
contracts with a prepayment penalty and without a prepayment penalty.46
Both contracts
mature in two periods. The contracts with and without a penalty are originated,
respectively, with contract rates pi and ni . If the contract with a penalty is chosen, a
prepayment penalty of the amount s is effective for the entire loan term.47
In the first
period, a borrower obtains a mortgage with an outstanding balance of L to purchase a
property with a value of V. For the sake of simplicity, I follow Brueckner (1992) and
Posey and Yavas (2000) to make two assumptions: 1) property price stays constant over
time, and 2) all loans have a loan-to-value ratio of 100 percent. These two assumptions
collectively imply L = V at all times.48
All borrowers have an identical first-period
income 0y . A borrower can refinance her loan in the second period conditioned on
maintaining the income level 0y . The second-period income y is a random variable. I
46 Henceforth, I denote the contract with a prepayment penalty by p and the contract without a prepayment
penalty by n. I model the inclusion of a prepayment penalty in a mortgage contract as a dichotomous-
choice problem because lender price sheets typically contain two sets of interest rates: one for loans that
have prepayment penalties and the other for loans that do not (LaCour-Little and Holmes, 2008).
47 In most cases, a prepayment penalty is effective during a specified time period and expires afterwards.
After its expiration, a borrower’s ability to refinance is unconstrained. One could easily incorporate the
transitoriness of a prepayment penalty by extending the current model beyond two periods and allow a
prepayment penalty to expire before maturity.
48 It is well-known that the change of property value plays a vital role in affecting default rate. However, it
is less relevant in a model of information asymmetry because it is unlikely borrowers are more informed
than the lender about future property value movement. Therefore, I suppress the property price variation in
the model to focus on the cross-individual difference in expected future income.
103
assume that a borrower has a probability of 10, of experiencing an income
decline. When that occurs, the reduced income is uniformly distributed between 0 and 0y .
The income reduction disqualifies the borrower from obtaining a refinance loan. A
borrower may default if the realized income is too low, such that it is insufficient to cover
the interest payment. To characterize information asymmetry, I assume there exists two
types of borrower who differ only in their value of . The high-risk borrower (type H) is
characterized by having a greater LHH , than the low-risk borrower (type L). The
proportions of high-risk type and low-risk type borrowers in the population are,
respectively, and 1 .
The second-period market interest rate i is assumed to be stochastic, and it follows
a two-point distribution. Market interest rate takes a low value of siii pn , with a
probability of 10, and takes a high value of siii pn , with a probability of
1 . This assumption simply states that i is low enough such that refinancing is
optimal even with a prepayment penalty.49
Thus, all borrowers refinance whenever the
realized interest rate is low.50
Both borrowers and lenders are assumed to be risk-neutral.
Zero-Profit Contracts
I assume all lenders have a discount rate of . With risk neutrality, a typical
lender’s objective function is the expected discounted value of profit. Without a 49 One could alternatively assume np iisi . In this case, refinancing is eliminated entirely by
prepayment penalty, and borrowers will prepay to obtain i only if they hold a contract without prepayment
penalty. Implications of the model do not change with this alternative assumption.
50 This assumption of costless refinancing is inconsequential in deriving the equilibrium.
104
prepayment penalty, a borrower can take advantage of a lower interest rate and refinance
at no cost. Of course, the feasibility of refinancing is conditioned on having sufficient
second-period income. The zero-profit condition of contract n is given by equation (4.1):
0)(
)()()()1(
))(1)(1()(
0
0
n
n
i
y
in
nnn
dyyVf
dyyfiLiL
iLiL
(4.1)
In the first period, the lender transfers the loan amount L to the borrower and collects
interest payment ni (first term). If income stays high and the realized interest rate is i, no
refinancing occurs. The lender receives loan amount L plus ni . This happens with a
probability of )1)(1( (second term). When income stays high and the realized
interest rate is i , a borrower refinances. The lender then has to originate a new loan at the
prevailing market rate i (third term). When income declines, the refinance option is no
longer available. The borrower will repay the loan if the reduced income is above the
interest payment ni (fourth term). Otherwise, the borrower defaults, and the lender
forecloses the property by collecting the property value V (fifth term).
Similarly, the zero-profit condition for the contract with a prepayment penalty is
shown by equation (4.2):
0)()(
)()()()1(
))(1)(1()(
0
0
p
p
i
y
ip
ppp
dyyfV
dyyfiLsiL
iLiL
(4.2)
105
Note there are two critical differences between equations (4.1) and (4.2). First, instead of
charging ni , the lender charges pi as the contract rate. Second, when a borrower prepays,
the lender collects the prepayment penalty s (third term).
Solving (4.1) and (4.2) yields *
pi and *
ni that satisfy the zero-profit conditions. A
number of properties of zero-profit contracts are important. First, a smaller value of i
increases *
pi and *
ni . Because a smaller i makes reinvesting the refinanced loan more
costly, it must be compensated by greater contract rates. This can be verified by
implicitly differentiating *
pi and *
ni with respect to i and obtaining 0/* iip and
0/* iip . Second, both p and n depend on . It is noteworthy that the increase of
has two opposing effects on lending profit. First, it enhances profitability by
eliminating the refinance option. Second, it adversely affects lender’s payoff by possibly
triggering default. The signs of /n and /p , which are given by equation (4.3)
and (4.4), are ambiguous.
0
2
0
2
)(2
y
iiiy nnn
(4.3)
0
2
0
2
)(2
y
isiiy ppp
(4.4)
I restrict attention to the case where 0/ n and 0/ p , that is, the increased
default risk dominates.
A pooling contract is characterized by the lender offering a single contract and
charging a uniform rate. Possible pooling contracts are of two kinds: pooling penalty
106
contracts and pooling non-penalty contracts. If the lender offers only contracts with a
penalty, the rate that ensures zero lending profit is *** )1( L
p
H
pp iii , where and
1 are, respectively, the proportions of high-risk type and low-risk type borrowers in
the population. Similarly, the zero-profit pooling rate of contracts without a penalty is
*** )1( L
n
H
nn iii .
Borrower’s Problem
I now turn to the borrower’s objective functions. I assume all borrowers have a
discount rate of . Given the model setup, a borrower would want to refinance if the
realized interest rate is low. However, refinancing may be infeasible if the second-period
income is reduced. Hence, the borrower’s expected payoff from choosing a contract n is
n
n
i
y
in
nnn
dyyfDy
dyyfhiyhiy
hiyhiyU
0
0
00
)()(
)()()()1(
))(1)(1()(
0
. (4.5)
The first term indicates that a borrower with an initial income level 0y incurs an interest
payment of ni in the first period, and ownership is accompanied by positive utility h from
housing services (first term). The decision to own a house is rational only if the
ownership benefit h is greater than the periodical interest payment. For this reason, I
assume siih pn , . In the second period, when the borrower’s income stays at 0y and
the second-period market interest rate is high, the borrower does not refinance. In this
case, the borrower repays the loan and obtains h (second term). Refinancing occurs when
107
income stays high, and the second-period interest rate decreases. Instead of ni , refinance
enables the borrower to pay the lower interest rate i (third term). When income declines,
a borrower continues with the loan by paying ni when realized income is above ni (fourth
term). When realized income is below ni , default occurs. In this case, the borrower loses
the property and incurs a default cost D (fifth term).
The expected utility for a borrower choosing the contract with a prepayment
penalty is
p
p
i
y
ip
ppp
dyyfDy
dyyfhiyhsiy
hiyhiyU
0
0
00
)()(
)()()()1(
))(1)(1()(
0
(4.6)
Two differences exist between equations (4.5) and (4.6). First, instead of paying ni , the
borrower pays pi as the contract rate. Second, refinancing is accompanied by the
prepayment penalty s (third term).
To characterize a borrower’s preference between the two contracts, I define ΔU as
the utility differential between contracts n and p.
pn
pn
ii
y
ip
y
in
npnp
pn
dyyfDydyyfDy
dyyfhiydyyfhiy
siiii
UUU
00)()()()(
)()()()(
)1())(1)(1()(
00
(4.7)
Equation (4.7) highlights the trade-off faced by a borrower in selecting between contracts
n and p. The first two terms represent a cost of selecting contract n. When pn ii , a
108
borrower pays an interest premium by selecting contract n. Given ni is less affordable, an
additional cost associated with contract n is the increased probability of default. In return,
the borrower enjoys a greater benefit when refinancing, because no penalty needs to be
paid with a contract n. The borrower selects contract n if its benefit outweighs the cost.
To rule out the trivial outcome that contract p dominates contract n at all times, I impose
the restriction that pn iis .51
It is also clear that the utility differential increases with
ni and deceases with pi , 0/ piU and 0/ niU .
The borrower’s choice of prepayment penalty depends on his income uncertainty.
Differentiating ΔU with respect to , we have
02
))(()(2
0
0
y
iiiisiiyU pnpnpn
(4.8)
Equation (4.8) is strictly negative. This suggests that as becomes greater, contract p
becomes increasingly attractive as compared to the contract n. The intuition underlying
equation (4.8) is critical. Because reduced income level deprives the borrower of the
option to refinance, a large translates to a lower expected payoff from contract n. As a
result, the incentive to pay an interest premium to eliminate the prepayment penalty is
lessened.
51 Given pn ii , the first term is strictly negative. In addition, the third-line and fourth-line expressions of
(6) are strictly negative. Intuitively, contract p always provides greater utility when income is reduced.
When the reduction is moderate, contract p is cheaper due to pn ii . Furthermore, the lower contract rate
of contract p also reduces the probability of default. Hence, sii nl )1())(1)(1( must
be strictly positive to allow for possible coexistence of the two contracts. Otherwise, I yield a trivial
outcome that that contract p dominates contract n. Simplification yields ln iis .
109
I further characterize the borrower’s indifference curve, which is a set of ),( pn ii
that makes a borrower indifferent between contracts n and p. Setting ΔU = 0, and
implicitly differentiating ni with respect to pi , I have:
0)()1(
)()1(
000
000
yiyy
yiyy
iU
iU
i
i
n
p
n
p
p
n
(4.9)
Not surprisingly, equation (4.9) indicates that the indifference curve is upward sloping. It
reflects the simple fact that when ni increases, pi must also rise for a borrower to remain
indifferent. To determine how alters the relative position of the indifference curve, I
implicitly differentiate ni with respect to holding ΔU = 0. Equation (4.8) and
0/ niU collectively imply that 0/ ni , which suggests that a greater shifts
the indifference curve downward.
Equilibrium with Full Information
With the framework developed above, I now turn to the derivation of mortgage
market equilibria. I define an equilibrium as a set of mortgage contracts such that 1) each
borrower type makes contract choices based on utility maximization, and 2) the lender
earns nonnegative profit, and no other lenders have an incentive to enter the market by
offering contracts outside the equilibrium set.
I first consider the equilibrium under full information. Suppose there exist two
types of borrowers who are identical in all aspects except for their expected income
uncertainty. High-risk borrowers (type H) are characterized by having a greater
110
LHH , than low-risk borrowers (type L).52
Under full information, the lender’s
problem is simple. Since a borrower’s risk type is observable to the lender and the
mortgage market is competitive, the lender offers the zero-profit rates of either contract n
or p that correspond to the borrower type. To obtain the zero-profit penalty contract rates
of each borrower type, I substitute H and L , respectively, into (4.1) and (4.2) and
solve for *
ni and *
pi . 0/ n and 0/ p , respectively, implies that ** L
n
H
n ii
and ** L
p
H
p ii . Intuitively, the borrower type with a greater probability of an income
decline will be charged higher interest rates.
In reality, designating separate contracts to different borrower types may not be
feasible. First, borrowers are normally better in assessing their future income uncertainty
than the lender. Second, even when observable, lenders are prevented from using certain
borrower characteristics (e.g. age, gender, and race) to price mortgages. When the lender
is at an informational disadvantage and borrower types cannot be credibly identified, free
choice between contracts n and p must be allowed.
Equilibrium with Asymmetric Information
When there is information asymmetry, borrowers’ risk types are unobservable to
the lender. As a result, lenders are unable to offer contracts contingent on risk types. In
general, mortgage market equilibria under information asymmetry could be of two types:
a pooling equilibrium or a separating equilibrium. A pooling equilibrium is characterized
52 I define risk types based on default probability. High (low) risk indicates a greater (smaller) likelihood of
default.
111
by lenders offering a single type of contract, either with or without a prepayment penalty,
at a uniform rate to all borrowers. On the other hand, a separating equilibrium is a market
outcome in which borrowers of different risk types obtain distinct contracts. Because the
choice of prepayment penalty analyzed here is considered dichotomous, it is possible to
derive pooling equilibria from the model (Posey and Yavas, 2001). However, given the
observed coexistence of contracts with and without a prepayment penalty in the U.S.
mortgage market, I focus exclusively on the properties of a separating equilibrium that
are empirically relevant. I denote by LHjii jpn ,),,( the no-penalty rate ni that makes
a borrower of risk type j indifferent to a choice between a contract n and a contract p
charging pi .
Proposition 1. There exists a separating equilibrium where the high-risk borrowers
obtain contract p with the rate *H
pi , the low-risk borrowers obtain contract n with the rate
*L
ni , and the lenders earn zero expected profits, if and only if );(),( ***
Lpn
L
nH
H
pn iiiii .
Proof. See Appendix B
Here, I briefly discuss the underlining intuition. As shown previously, borrower
indifference curves are upward-sloping. In addition, the indifference curve of the high-
risk type lies below that of the low-risk type. Recall that 0/ ni . The parameter
conditions specified in proposition 1 ensure that the contract combination ),( ** H
p
L
n ii is
located above the indifference curve of the high-risk type but below that of the low-risk
112
type. When both *L
ni and *H
pi are offered, high-risk borrowers prefer contract p to contract
n. This can be verified by referring to figure 4.1. The vertical line passing through point
),( ** H
p
L
n ii intercepts high-risk indifference curve at the point )),;(( ** H
pH
H
pn iii . This
indicates that high-risk borrowers are indifferent between a contract p priced at *H
pi and a
contract n charging );( *
H
H
pn ii , which is cheaper than *L
ni . Thus, high-risk borrowers will
choose contract p over contract n. Turning to low-risk borrowers, the vertical line passing
through the point ),( ** H
p
L
n ii intercepts low-risk indifference curve at point
)),;(( ** H
pH
H
pn iii . This indicates that high-risk borrowers are indifferent between a
contract p priced *H
pi at and a contract n charging );( *
L
H
pn ii , which is more expansive
than *L
ni . Thus, low-risk borrowers will choose contract n over contract p.
For the separating equilibrium to be feasible, another necessary condition is that
no other lenders can make a positive profit by offering alternative contracts when
),( ** H
p
L
n ii is offered. Because both *L
ni and *H
pi yield zero-profit lending profit, it is
impossible for other lenders to offer a set of alternative separating contracts and make a
positive profit. The question becomes whether it is possible for other lenders to profit by
offering pooling contracts. First, offering a pooling no-penalty contract is infeasible. In
the presence of *L
ni , the pooling no-penalty rate *
ni is greater than *L
ni and attracts no
borrowers. Second, the parameter condition that );( **
Lpn
L
n iii ensures that a pooling
penalty contract is less preferable to low-risk borrowers than a contract n priced at *L
ni .
When simultaneously offered with ),( ** H
p
L
n ii , *
pi would only attract high-risk borrowers
113
and generate a negative profit. Because no lender has an incentive to deviate, ),( ** H
p
L
n ii is
indeed a separating equilibrium.
Does the Prohibition of Prepayment Penalties Benefit or Hurt Borrowers?
Before moving to the empirical analysis, it is important to discuss the welfare
implications of prohibiting prepayment penalties. Such a prohibition is equivalent to
imposing a pooling equilibrium in which lenders offer only contracts without a penalty
and charge the pooling no-penalty rate *
ni . Such a pooling equilibrium imposes welfare
losses on both types of borrowers.
Proposition 2. If );();( ***
Lpn
L
nH
H
pn iiiii , a forced pooling equilibrium where
contract n is offered at the rate *
ni to all borrowers is welfare-reducing as compared to the
separating equilibrium where the high-risk borrowers obtain contract p with the rate *H
pi ,
the low-risk borrowers obtain contract n with the rate *L
ni .
Proof. First, low-risk borrowers are worse off because they now pay a higher mortgage
rate, ** L
nn ii . The pooling equilibrium is also welfare-reducing to high-risk borrowers.
Because high-risk borrowers would have selected a contract with a prepayment penalty
when *L
ni is offered, it must be the case that )()( ** L
n
H
n
H
p
H
p iUiU . If prepayment penalties
are prohibited, high-risk borrowers must pay the pooling no-penalty rate *
ni , which is
even higher than *L
ni . It must be the case that )()( **
n
H
n
H
p
H
p iUiU .
114
Figure 4.1 illustrates the welfare reduction to each type of borrower caused by the
prohibition of prepayment penalties. Recall that the pooling no-penalty rate
*** )1( L
n
H
nn iii is strictly greater than *L
ni . Thus, the welfare loss to a low-risk
borrower is represented by the vertical distance between *
ni and *L
ni . Under the separating
equilibrium, a high-risk borrower would have selected contract p and paid *H
pi , which
generates the same level of utility as a contract n charging );( *
H
H
Pn ii . The welfare loss
to high-a risk borrower is represented by the vertical distance between *
ni and );( *
H
H
Pn ii .
It is also straight forward to see that the prohibition of prepayment penalties can
increase the likelihood of mortgage defaults. Because the pooling no-penalty rate *
ni is
strictly greater than *L
ni and *H
pi , the chance of having the second-period income y below
the interest payment becomes greater. Thus, a mortgage default becomes more likely. Of
course, this clear-cut implication is predicated on the assumption of constant property
prices. The occurrences of strategic defaults, which may be increased by prepayment
penalties, become relevant if that assumption is relaxed. As a result, the net effect of
prohibiting prepayment penalty on default rate is, at best, ambiguous. The model also
explains the empirical finding that the rate reduction associated with a prepayment
penalty is, in general, insufficient to compensate the value of the option to prepay.53
Because riskier borrowers tend to select loans with a prepayment penalty, the rate
reduction must be offset by a risk premium charged on this group of borrowers.
53 See Goldstein and Son (2003) and LaCour-Little and Holmes (2008).
115
Empirical Analysis
Hypothesis
Proposition 1 generates three testable predictions. First, under information
asymmetry, observationally equivalent borrowers are likely to be faced with the choice of
loans with and without a prepayment penalty. The first prediction is corroborated by the
coexistence of both types of contracts in the U.S. residential mortgage market. The
second prediction is that contracts with a prepayment penalty originate at a lower rate.
Several studies document that mortgages with a prepayment penalty are associated with
lower cost of credit, such as reduced annual percentage rates (APRs) and note rates, after
controlling for other risk factors.54
Finally, the third prediction is that riskier borrowers
choose contracts with a prepayment penalty. This prediction mirrors the standard positive
correlation between contractual choices and risk occurrences, which is the focus of most
empirical tests of adverse selection.55
The remaining part of this paper follows this
tradition and examines the link between prepayment penalty and mortgage termination
outcomes.
The information asymmetry hypothesis predicts a positive correlation between
expected default probabilities and prepayment penalty choices. Although the ex ante
default probabilities are not directly observable, given a large sample, these probabilities
can be approximated using ex post default outcomes. Thus, a positive correlation between
the choice of a prepayment penalty and default rate is consistent with the information
54 See DeMong and Burroughs (2005) and LaCour-Little and Holmes (2008).
55 See Dionne, Gouriéroux, and Vanasse (2001) for a discussion on the advantages of testing the positive
correlation as opposed to testing other predictions.
116
asymmetry hypothesis. However, inference drawn from this simple test could be
ambiguous due to an alternative explanation. Option-based mortgage pricing literature
suggests that the values of prepayment and default options are jointly determined. A
prepayment penalty, which constrains the prepayment option, tends to increase the
likelihood of default. A positive correlation between the choices of a prepayment penalty
and default rates is uninformative in distinguishing between these two effects. To identify
the direction of the causal relationship, I exploit the fact that many prepayment penalties
expire within a relatively short period of time (e.g. one, two, or three years) after loan
origination. Elevated default risk, if caused by prepayment penalties, should disappear
after the expiration. On the other hand, the intrinsic riskiness of borrower is likely to
persist beyond prepayment penalty terms. If loans with a prepayment penalty continue to
exhibit higher default rates after the expiration of penalties, the choices of prepayment
penalty must be a result of self-selection. I formulate the following hypothesis:
H1: Mortgages originated with a prepayment penalty are more likely to default as
compared to mortgages without a prepayment penalty, and this correlation persists even
after prepayment penalties expire.
Empirical support to H1 is consistent with the information asymmetry hypothesis.
Data
The primary data used for this study comes from mortgage origination and
servicing histories provided by New Century Financial Corporation. I focus on a sample
117
of first-lien 30-year fixed-rate mortgages. The full sample consists of 51,923 FRMs
originated between January 2002 and December 2005. The loan performance of this
sample is subsequently tracked until February 2007. Table 4.1 summarizes the basic
characteristics of this sample. The average loan size is $167,744 with an average loan-to-
value (LTV) ratio of 78 percent. The average note rate is 7.30 percent. Not surprisingly,
the data exhibit patterns consistent with a subprime sample. Approximately 79.72 percent
of loans contain a prepayment penalty. The average borrower’s FICO score is 624, and
30 percent of loans originated with limited or no documentation. In addition, 82 percent
of the sample originated through mortgage brokers (wholesale loans).
Examining loans with and without prepayment penalties reveals interesting
differences between these two groups. For example, loans with a prepayment penalty
have an average contract rate of 7.16 percent, which is 74 basis points lower than the
average note rate of loans without a prepayment penalty. This is consistent with the
notion that prepayment penalties are associated with lower mortgage rates. However, this
rate differential may also be attributable to the fact that borrowers who accept
prepayment penalties have a higher average FICO score than those that do not. It also
appears that loans with a prepayment penalty have a higher debt-to-income (DTI) ratio,
which suggests that borrowers who accepted a prepayment penalty tend to borrow more
against current income. In addition, a much smaller portion of loans with prepayment
penalties are originated with mortgage discount points. Finally, mortgages with
prepayment penalties are more likely to be low-doc/ no-doc loans and loans originated
through a mortgage broker.
118
Methodology
Dionne, Gouriéroux, and Vanasse (2001) suggest that empirical evidence of
adverse selection takes the form of ―conditional dependence.‖ Let us denote by D the
probabilities of mortgage defaults, by X the set of observable risk factors that affecting
mortgage termination, and by P the choice of prepayment penalty. Variable P supplies no
additional information if and only if the predicted default probabilities, D̂ , conditioned
on X and P jointly is identical to D̂ conditioned on X alone. Formally speaking, there is
no information asymmetry is absent if and only if )|(),|( XDlPXDl ), where .).,|(.l
denotes a conditional probability density function. On the other hand, conditional
dependence, which implies )|(),|( XDlPXDl , is consistent with information
asymmetry. I test the conditional dependence using two methods: a competing-risks
hazard model and a bivariate-probit model.
Competing-Risks Hazard Model
A key prediction of the model constructed in this paper is that high-risk borrowers
tend to select contracts with a prepayment penalty. Hence, a natural way to test the
conditional dependence is to regress D on both X and P, and examine if P can explain the
variation of D in the presence of X. I conduct this test by first estimating a competing-
risks hazard model following the methodology used in Ambrose and Sanders (2003).56
56 Kau, Keenan, Lyubimov, and Slawson (2010) use a similar framework to test the existence of adverse
selection in residential mortgage origination by estimating a proportional hazard model controlling for
observable borrower and loan characteristics.
119
A borrower has the option to prepay, default, or remain current for any given
period. I define mortgages that are still current at the end of the observation period as
censored. Thus, I define )3,2,1( jT j as the latent duration for each mortgage to be
terminated during the observation period by prepaying, defaulting, or remaining current
(censored). Thus, the observed duration, , is the minimum of the jT . Conditional on a
set of explanatory variables, jX , which may include static loan characteristics at the time
of loan origination as well as time-varying economic conditions, and parameters, j , the
probability density function (pdf) and cumulative density function (cdf) for jT are
));|(exp();|();|( jjjjjjjjjjjj XrIXThXTf (4.10)
);|(exp(1);|( jjjjjjjj XrIXTF (4.11)
where r is an integer variable taking values in the set {1, 2, 3} representing the three
possible outcomes, jI is the integrated hazard for outcome j:
jT
jjjjjjj XshXTI0
);|();|( (4.12)
where jh is the hazard function.
The joint distribution of the duration and outcome is
));|(exp();|();|( 0 jjjjjjjjjjj XIXhXf (4.13)
where ),,( 321 XXXX and ),,( 321 and
3
1
0
j
jII is the aggregated integrated
hazard. Thus, the conditional probability of an outcome is
3
1
);|(
);|();,|Pr(
j
jj
jj
Xh
XhXj
(4.14)
120
I assume a separate exponential hazard function for each mortgage outcome and estimate (4.14)
using multinomial logit.
Dionne, et al., (2001) note that it would be preferable to add expected contractual
choices in (4.14) in order to address potential problems of misspecification. Expected
contractual choices can be obtained by estimating the following logit model for the
choice of prepayment.
iiii XXPENALTY )'()|1Pr( (15)
Where iX is a set of borrower and loan characteristics of mortgage i observable to the
lender, and i is the standard error. Λ is the logistic cumulative distribution function.
Because the predicted choice of prepayment penalty )ˆ( iLTYAPEN is, by construction, a
function of observable variables, it must be irrelevant to information asymmetry.
Following Dionne et al., (2001), I including iLTYAPEN ˆ as a control variable.
Bivariate-Probit Model
I also perform the version of positive correlation test as proposed by Chiappori
and Salanié (2001). The test involves estimating the following bivariate-probit model
with the choices of prepayment penalties, iP , and subsequent loan performance outcomes,
iD , as the two dependent variables.
P
iiii XXP )'()|1Pr( (4.16)
D
iiii XXD )'()|1Pr( (4.17)
121
)( denotes the standard normal distribution. iX is a vector of borrower and loan
characteristics that are observable to the lender. P
i and D
i are, respectively, the
normally distributed error terms of equation (4.16) and (4.17), which have a correlation
coefficient . A significantly positive is consistent with the conditional dependence.
Sampling
Distinguishing between adverse selection and moral hazard has been a difficult
task, because a positive correlation between contractual choices and risk occurrences is
consistent with both arguments. However, the distinction is extremely important in
determining the welfare impacts of prepayment penalties. To separate adverse selection
from the confounding effect that prepayment penalties may increase the likelihood of
mortgage default, I exploit the fact that prepayment penalties often expire in a short
period of time (e.g. one, two, or three years). I first group loans that have a prepayment
penalty by the length of their penalty terms. Then, three subsamples are constructed to
compare mortgages with no penalty, respective, to loans with one, two, and three years.
Subsample 1.1 contains mortgages with no prepayment penalty and ones with an one-
year penalty; subsample 2.1 contains mortgages with no prepayment penalty and ones
with a two-year penalty, and subsample 3.1 contains mortgages with no prepayment
penalty and ones with a three-year penalty. Tests of positive correlation are conducted
using the full sample as well as the three subsamples to ensure results are consistent
across prepayment penalties with different terms.
122
I further construct three subsamples containing only loans surviving beyond
prepayment penalty expirations to identify the effect of adverse selection. Subsample 1.2
contains mortgages without a penalty and with a one-year-penalty that have survived
beyond the first year; subsample 2.2 contains mortgages without a penalty and with a
two-year-penalty that have survived beyond two years, and subsample 3.2 contains
mortgages without a penalty and with a three-year-penalty that have survived beyond
three years. The detection of positive correlations using subsamples 1.2, 2.2, and 3.2
unequivocally support the information asymmetry hypothesis. Figure 4.2 illustrates the
construction of the six subsamples.
Variables Related to Default and Prepayment Options
In the competing risks hazard model, I include factors that may impact mortgage
default and prepayment. In the contingent claim framework, the FRM contract contains a
prepayment option and a default option. A borrower minimizes the market value of his
outstanding loan via strategically exercising these two options. To capture how much the
prepayment option is ―in-the-money,‖ I include in X a variable, ΔRATE, which is defined
as
m
t
m
t
m
it
r
rrRATE
(4.18)
where m
ir is the 30-year conventional mortgage rate at the origination of loan i, and m
tr is
the 30-year conventional mortgage rate at time t. A relative increase in ΔRATE indicates
that the market interest rate has declined, and this increases the likelihood of prepayment.
123
The theoretical mortgage literature indicates that the intrinsic values of the default
and prepayment options are jointly determined. The relative position of the default option
affects borrower refinancing strategy. Specifically, declines in property values increase
the probability of default and reduce the probability of prepayment. To account for the
competing nature of default and prepayment risk, I control for contemporary loan-to-
value (LTV) ratio, CLTV , which is computed as the ratio of the market value of the loan
to the market value of the property.
As suggested by Kau et al. (1992, 1993), interest rate volatility also plays a
critical role in determining the value of the prepayment option. Hence, I account for
interest rate volatility by including the variable MORTVOL. MORTVOL is calculated as
the standard deviation of the monthly 30-year conventional mortgage rate over the
previous 24 months. I also control for housing price volatility by including the variable
HPIVOL, which is calculated as the standard deviation of the Office of Federal Housing
Enterprise Oversight (OFHEO) state-level quarterly housing price index over the
previous two years. Following Ambrose and Sanders (2003), I control for the market’s
expectation on future interest rate by including the slope of yield curve (YLDCURVE),
which is measured as the 10-year Treasury bond rate minus the 1-year Treasury bond rate.
Variables Related to Borrower and Loan Characteristics
I control for borrower and loan characteristics in both the competing-risks hazard
model and the bivariate-probit model. Affordability and credit score are commonly used
in residential mortgage underwriting to determine a borrower’s qualification. Borrowers
with greater financial resources relative to debt level and with a superior credit history
124
should be less likely to default. Hence, I include FICO score (FICO) and the debt-to-
income (DTI) ratio (DTI), which is the monthly mortgage payment as a fraction of a
borrower’s monthly income, in the regression model to respectively control for
affordability. In addition, a significant portion of loans in the sample are originated with
limited or no documentation on income and/or assets, which possibly indicates limited
financial strength. Therefore, I include a dummy variable, DOC, to denote documentation
status. Many other borrower characteristics are shown in the literature to have influence
on loan performance. For instance, Brueckner (1992) shows that older age and high
property purchase price are associated with low mobility, which leads to reduced
propensity of prepayment. To control for borrower mobility, I control for borrower’s age
(AGE) and the appraised value reported at the time of loan origination (PROPVAL).
Mortgage choices may be correlated with unobserved borrower characteristics.
Similar to the choice of prepayment penalty, other mortgage choices, such as loan-to-
value (LTV) ratio and discount points, may also convey information regarding a
borrower’s risk profile. Brueckner (2000) shows that when the costs of default (e.g.,
damage to credit history or reputation) are private information and heterogeneous across
borrowers, high-default-risk borrowers tend to choose a higher LTV ratio. Harrison et al.
(2004) derive a similar result under the scenario when information asymmetry exists on
future income uncertainty, and default cost is relatively small. However, Harrison et al.
(2004) also show that when default cost is large, riskier borrowers tend to borrow less.
On the other hand, loans originated with greater discount points should exhibit a reduced
propensity of prepayment, because paying discount points signals either low mobility
(Dunn and Spatt 1985, Chari and Jagannathan 1986, Yang 1992, Brueckner 1994, LeRoy
125
1996, and Stanton and Wallace 1998) or high transactions costs of refinancing (Pavlov
2001, and Chang and Yavas 2009). Therefore, I include in the set of control variables the
loan-to-value ratio (LTV) and discount points (DISCPT), which is a dummy variable
equal to one if the loan is originate with discount points. In addition, the benefit from
refinancing may also depend on the outstanding balance. Assuming there are fixed costs
associated with refinancing (e.g., appraisal fees, title search time, and inconvenience etc.),
refinancing a larger-sized loan usually creates a greater benefit. Hence, I control the
principal balance at origination (LOANSIZE).
Coulibaly and Li (2009) document that risk aversion plays an important role in
determining mortgage choices. It is possible that risk aversion simultaneously determines
the choice of prepayment penalty and loan performance outcomes. I employ a dummy
variable to denote whether or not a borrower is self-employed (SELFEMP) to control for
the effects of risk aversion.20 I also include a set of dummy variables to distinguish
between purchase loans versus refinance loans (REFI), loans collateralized by a primary
residence versus ones collateralized by a non-primary residence (NONPRIMRES), and
wholesale loans versus retail loans (WHOLESALE).
Finally, I control for time and geographic-related variations in both (14) and (15).
To capture seasonal market changes of mortgage origination, I include a set of indicator
variables representing the year of origination. I control for regional fixed effects by a set
of indicator variables constructed based on in which state the property is located. The set
of indicator variables controls for differences in state laws regarding mortgage default
and foreclosure (Ambrose and Pennington-Cross, 2000) and potential impacts of different
state predatory lending laws on the choice of prepayment penalty. To further control for
126
unobserved heterogeneity and to correct for any dependence among observations drawn
from the same loan, I use robust standard errors allowing for loan-level clustering when
estimate (14). Definitions of variables are summarized in table 4.2.
Results
Results of the Competing-Risk Hazard Model
Table 4.3 presents the results from a logit regression of equation (4.15). It appears
that the choice of prepayment penalties is correlated with a number of borrower and loan
characteristics. Because those characteristics are also observable to the lender, predicted
choice on prepayment penalties using those characteristics is unrelated to information
asymmetry and must be controlled for. Following Dionne, Gouriéroux, and Vanasse
(2001), I collect the predicted probability of selecting a prepayment penalty LTYAPEN ˆ ,
and use it as a control variable in the competing-risks hazard model. Table 4.4 presents
the results from the competing-risk hazard model using the full sample. After controlling
for time-varying option-related variables, observable borrower characteristics, and
LTYAPEN ˆ from estimating equation (4.15), I find that loans with a prepayment penalty
are less likely to prepay (significant at 1 percent level), but have a greater default rate
(significant at 5 percent level). The odds ratios are calculated to gauge the marginal
effects of having a prepayment penalty on loan performance. It indicates that mortgages
with a prepayment penalty are 11.9 percent less likely to prepay and 13.9 percent more
likely to default.
127
Although it is not the main focus of this paper, the estimated coefficients of
control variables exhibit patterns largely consistent with previous mortgage termination
literature. Consistent with empirical mortgage literature, I find support for the ―jointness‖
of prepayment and default option. A larger interest rate reduction )( RATE increases the
probability of prepayment (significant at 1% level). However, it fails to exhibit a
significant effect on default. Contemporary LTV (CLTV) increases the default rate and
reduces the likelihood of prepay (both significant at 1% level). As expected, the
expectation of a raising interest rate increases mortgage prepayment and reduces default
(both significant at 1% level). Turning to borrower and loan characteristics, I find loans
with a lower FICO score, high debt-to-income ratio, and limited or no documentation are
considerably more likely to default. On the other hand, loans originated with mortgage
points are less likely to prepay.
One of the limitations of the standard ―positive correlation‖ test is its inability to
distinguish adverse selection and moral hazard. As discussed previously, prepayment
penalties often expire in a relatively short period of time and examine loan performance
after the expiration date. Model 1.1 is a competing-risks hazard model estimated using
subsample 1.1. Similar to the results obtained using the full sample, loans with a
prepayment penalty are less likely to prepay (significant at 1 percent level), but those
loans fail to exhibit a greater default rate like in the results obtained using the full sample.
To examine loan performance after prepayment penalty expiration, I re-estimate the
competing-risks hazard model using subsample 1.2, which contains loans surviving
beyond their one-year penalty expiration date. Results from model 1.2 indicate that loans
with an one-year penalty continue to exhibit a lower propensity to prepay (significant at 1
128
percent level) and a higher default rate after prepayment penalties expire (significant at 5
percent level). Loans that previously had a one-year penalty appear 38.9 percent more
likely to default after prepayment penalties expire. Table 4.6 presents the results of the
competing-risks hazard model estimated using subsamples 2.1 and 2.2. Table 4.7 presents
the results of the competing-risks hazard model estimated using subsamples 3.1 and 3.2.
The results are qualitatively similar. Estimating using sample 2.1, loans with a two-year
prepayment penalty are approximately 15.8 percent less likely to prepay as compared to
no-penalty loans. However, I fail to reject the null hypothesis that these two groups of
loans are equally likely to enter default. Estimating using only loans that have survived
beyond two years, loans that previously had a two-year penalty appear 137.7 percent
more likely to default. Overall, loans with a three-year prepayment penalty are
approximately 13.5 percent less likely to prepay (significant at 1 percent level) and 14.2
percent more likely to default (significant at 10 percent level) as compared to no-penalty
loans. Using only loans survived beyond three years, I find loans that previously had a 3-
year penalty appear to be 160.7 percent more likely to default after three years
(significant at 1 percent level). In summary, the empirical results support the information
asymmetry hypothesis. Mortgages with a prior prepayment penalty continue to have a
greater default rate than the ones without a prepayment penalty.
Results of the Bivariate-Probit Model
Estimation results of the bivariate-probit model are summarized in table 4.8.
Because the main focus of this study is to test for adverse selection, the estimated
regression is of less interest. I restrict attention only to the estimated correlations of the
129
error terms. The left-hand column shows the estimated from the default model, in
which Di is defined as a dummy variable equal to one if mortgage i enters default. Using
the full sample, the estimated correlation between the error terms is 0.087, which is
significant at 1 percent level according to the likelihood ratio test. These results suggest
that after controlling for observable characteristics, borrowers who took loans with a
prepayment penalty are still more likely to default. I further estimate the bivariate-probit
model using restricted samples to compare loans with no prepayment penalty respectively
to the ones that have an one-, two-, and three-year prepayment penalty. The results are
similar, consistently appears to be significantly positive (all at 1% level). However,
this greater default risk could be due to both adverse selection and moral hazard. To rule
out the alternative explanation that prepayment penalties increase default risk, I estimate
using only mortgages survived beyond the penalty expiration date. Consistent with
previous results from the competing-risks hazard model, continues to be significantly
positive (all at 1% level). The bivariate-probit results are consistent with the presence of
adverse selection regarding the choice of prepayment penalties.
For completeness, I also estimate the prepayment model, in which iD is redefined
as a dummy variable equal to one if mortgage i is subsequently prepaid. Prepayment
penalties appear to be negatively correlated with a lower probability of prepayment. As
shown in table 4.8, are significantly negative when looking at the entire survival
period. However, I find no similar correlation when examining the subsamples of loans
that have survived beyond the penalty expiration.
130
Summary of Findings
In this Chapter, I investigate the effects of information asymmetry on borrower
choice of prepayment penalties. I construct a theoretical model to show that under
information asymmetry, there exists a separating equilibrium such that borrowers with
high (low) default risk select loans with (without) a prepayment penalty. The model
explains the empirical fact that prepayment penalties are associated with higher default
rates. To rule out the confounding predation hypothesis, I examine a sample of FRM
surviving beyond their prepayment penalty terms. Mortgages with prior prepayment
penalties are more likely to default even after prepayment penalties expire. In contrast to
the view that prepayment penalties are predatory and trigger mortgage default, this study
suggests a distinct causal relation: high default risk induces borrowers to accept
prepayment penalties. Regulations prohibiting prepayment penalties may, in fact,
increase mortgage default rates and reduce consumer welfare.
131
Figure 4.1: Separating Equilibrium with Zero Lending Profit
This graph illustrates the separating equilibrium with zero lending profit. In this
case, high-risk borrowers obtain contract p with rate *H
pi , low-risk borrowers obtain
contract n with rate *L
ni .
133
Table 4.1: Descriptive Statistics
This table presents the descriptive statistics of the sample. RATE is the mortgage note rate. FICO
is borrower’s credit score. DOC is a dummy variable indicating whether or not the loan was
originated with limited or no documentation of borrower’s income and/or asset (1=low-doc/no-
doc loan). AGE is borrower’s age at origination. PROPVAL is the appraised value of the property.
LOANSIZE is the total loan amount borrowed (measured in thousands of dollars). LTV is the loan-
to-value ratio. DISCPT is a dummy variable equal to 1 if the loan is originated with discount
points. SELFEMP is a dummy variable equal to 1 if the primary borrower is self-employed. REFI
is a dummy variable equal to 1 if the loan is a refinance loan. NONPRIMRES is a dummy variable
equal to 1 if the property is not the primary residence of the borrower. WHOLESALE is a dummy
variable equal to 1 if the loan is a wholesale loan.
Full Sample Without PP With PP
Mean Std. Dev. Mean Std. Dev. Mean Std. Dev. t-stat.
RATE 7.309 1.190 7.897 1.280 7.160 1.117 58.650***
FICO 623.611 63.186 604.026 61.499 628.593 62.639 -36.067***
DTI 0.220 0.090 0.197 0.086 0.225 0.091 -28.884***
DOC 0.305 0.460 0.271 0.445 0.314 0.464 -8.453***
AGE 46.077 12.009 47.278 12.008 45.771 11.991 11.510***
PROPVAL 229.203 159.321 172.206 124.004 243.703 163.989 -41.802***
LOANSIZE 167.744 105.590 128.724 87.790 177.670 107.421 -43.228***
LTV 78.029 14.670 78.082 12.715 78.015 15.127 0.418
DISCPT 0.275 0.447 0.489 0.500 0.221 0.415 56.738***
SELFEMP 0.153 0.360 0.143 0.350 0.156 0.363 -3.190***
REFI 0.846 0.361 0.887 0.317 0.835 0.371 13.124***
NONPRIMRES 0.079 0.270 0.051 0.221 0.086 0.281 -11.937***
WHOLESALE 0.830 0.375 0.713 0.452 0.860 0.347 -36.192***
# of Obs. 51,923 10,530 41,393
134
Table 4.2: Definition of Variables
VARIABLE DEFINITIONS
PENALTY Dummy variable equal to 1 if the loan has a prepayment penalty
ΔRAT E Mortgage rate reduction
CLTV Contemporary loan-to-value ratio calculated as the ratio of the market
value of the loan to the market value of the property
YLDCURVE Slope of yield curve calculated as the 10-year Treasury bond rate
minus the 1-year Treasury bond rate
MORTVOL Standard deviation of the monthly 30-year conventional mortgage rate
over the previous 24 months
HPIVOL Standard deviation of OFHEO state-level quarterly housing price index
over the previous two years
FICO Credit score of the primary borrower
DTI Debt-to-income ratio calculated as the monthly mortgage payment as a
fraction of a borrower’s monthly income
DOC Dummy variable equal to 1 if the loan is originated with limited or
no documentation
AGE Age of the primary borrower
PROPVAL Appraised value of the property
LTV Combined loan-to-value ratio at origination
DISCPT Dummy variable equal to 1 if the loan is originated with discount points
LOANSIZE Principal balance at origination
SELFEMP Dummy variable equal to 1 if the primary borrower is self-employed
REFI Dummy variable equal to 1 if the loan is a refinance loan
NONPRIMRES Dummy variable equal to 1 if the property is not the primary residence of
the borrower
WHOLESALE Dummy variable equal to 1 if the loan is a wholesale loan
135
Table 4.3: Estimation Results of the First-Stage Logit Model
This table presents the result from a logit regression of equation (4.15). Variable
definitions are in table 4.2. Standard errors are shown in parentheses below each regression
coefficient. One, two, and three asterisks respectively denote significance at 10%, 5%, and 1%
levels.
Variable Estimates Odds Ratio
FICO 0.004 1.004
(0.000)***
DTI 1.563 4.773
(0.209)***
DOC -0.094 0.91
(0.040)**
AGE -0.021 0.979
(0.008)***
AGE2 0.000 1.000
(0.000)
PROPVAL 0.004 1.004
(0.001)***
LTV 0.021 1.021
(0.003)***
DISCPT -1.399 0.247
(0.036)***
LOANSIZE -0.004 0.996
(0.001)***
SELFEMP -0.116 0.891
(0.051)**
REFI -0.348 0.706
(0.054)***
NONPRIMRES 0.967 2.63
(0.081)***
WHOLESALE -0.133 0.876
(0.040)***
Intercept -2.21 (0.328)***
Year Fixed-Effect YES
State Fixed-Effect YES
Number of Obs. 51,923
Pseudo R2 0.434
136
Table 4.4: Results of Competing-Risks Hazard Model Using the Full Sample
This table presents the result from the competing-risk hazard model using the full sample.
It assumes a quadratic baseline hazard function. Variable definitions are in table 4.2. Robust
standard errors with loan-level clustering are shown in parentheses below each regression
coefficient. One, two, and three asterisks respectively denote significance at 10%, 5%, and 1%
levels.
Prepayment Default
Estimates Odds Ratio Estimates Odds Ratio
PENALTY -0.127 0.881 0.130 1.139
(0.019)***
(0.066)**
ΔRAT E 1.302 3.675 -0.023 0.977
(0.098)***
(0.259)
CLTV -0.588 0.555 1.213 3.365
(0.108)***
(0.330)***
YLDCURVE 0.689 1.991 -0.229 0.795
(0.009)***
(0.034)***
MORTVOL -0.926 0.396 -0.214 0.807
(0.081)***
(0.367)
HPIVOL 0.002 1.002 -0.001 0.999
(0.001)***
(0.002)
FICO -0.002 0.998 -0.009 0.991
(0.000)***
(0.000)***
DTI 0.199 1.220 1.904 6.712
(0.071)***
(0.212)***
DOC 0.077 1.081 0.446 1.562
(0.014)***
(0.044)***
AGE 0.003 1.003 -0.040 0.961
(0.003)
(0.008)***
AGE2 -0.000 1.000 0.000 1.000
(0.000)
(0.000)***
PROPVAL -0.001 0.999 -0.001 0.999
(0.000)***
(0.001)*
LTV 0.003 1.003 -0.001 0.999
(0.001)* (0.004)
137
Table 4.4: Results of Competing-Risks Hazard Model Using the Full Sample (Cont.)
This table presents the result from the competing-risk hazard model using the full sample.
It assumes a quadratic baseline hazard function. Variable definitions are in table 4.2. Robust
standard errors with loan-level clustering are shown in parentheses below each regression
coefficient. One, two, and three asterisks respectively denote significance at 10%, 5%, and 1%
levels.
Prepayment Default
Estimates Odds Ratio Estimates Odds Ratio
DISCPT -0.034 0.967 -0.169 0.845
(0.018)*
(0.059)***
LOANSIZE 0.001 1.001 -0.000 1.000
(0.000)***
(0.001)
SELFEMP -0.045 0.956 -0.045 0.956
(0.018)**
(0.056)
REFI -0.006 0.994 -0.160 0.852
(0.017)
(0.053)***
NONPRIMRES -0.050 0.951 0.098 1.103
(0.022)**
(0.071)
WHOLESALE -0.049 0.952 -0.046 0.955
(0.017)***
(0.058)
PENÂLTY 0.525 1.691 -0.007 0.993
(0.071)***
(0.224)
month -0.037 0.964 0.044 1.045
(0.003)***
(0.007)***
month2 0.000 1.000 0.000 1.000
(0.000)
(0.000)
Intercept -2.674
0.473 (0.120)*** (0.385)
Year Fixed-Effect YES
State Fixed-Effect YES
Number of Obs. 565,358
Pseudo R2 0.090
138
Table 4.3: Results of Competing-Risk Hazard Model Using Subsamples 1.1 and 1.2
MODEL 1.1 MODEL 1.2
Prepayment Default Prepayment Default
Estimates Odds Ratio Estimates Odds Ratio Estimates Odds Ratio Estimates Odds Ratio
PENALTY -0.158 0.854 0.162 1.176 -0.367 0.693 0.328 1.389
(0.032)***
(0.120)
(0.085)***
(0.158)**
ΔRATE 1.665 5.284 -0.627 0.534 -1.225 0.294 0.178 1.194
(0.186)***
(0.562)
(0.446)***
(0.707)
CLTV -0.168 0.845 2.255 9.536 0.778 2.177 2.234 9.335
(0.246)
(0.663)***
(0.630)
(0.890)**
YLDCURVE 0.697 2.007 -0.172 0.842 0.043 1.044 -0.086 0.917
(0.017)***
(0.062)***
(0.050)
(0.080)
MORTVOL 0.315 1.371 -0.765 0.465 -0.095 0.910 2.634 13.932
(0.159)**
(0.705)
(0.666)
(0.974)***
HPIVOL 0.005 1.005 0.004 1.004 0.021 1.021 0.006 1.006
(0.002)***
(0.005)
(0.004)***
(0.006)
FICO -0.002 0.998 -0.010 0.990 -0.003 0.997 -0.008 0.992
(0.000)***
(0.001)***
(0.001)***
(0.001)***
DTI 0.051 1.052 2.109 8.237 1.997 7.369 1.663 5.277
(0.147)
(0.466)***
(0.372)***
(0.600)***
DOC 0.065 1.067 0.558 1.748 0.203 1.225 0.554 1.741
(0.026)**
(0.090)***
(0.071)***
(0.111)***
AGE 0.006 1.006 -0.033 0.968 0.015 1.015 -0.018 0.982
(0.006)
(0.018)*
(0.016)
(0.023)
AGE2 -0.000 1.000 0.000 1.000 -0.000 1.000 0.000 1.000
(0.000)
(0.000)
(0.000)
(0.000)
PROPVAL -0.001 0.999 0.001 1.001 -0.003 0.997 0.001 1.001
(0.001)*
(0.000)**
(0.001)**
(0.000)*
LTV -0.002 0.998 -0.000 1.000 -0.010 0.991 0.000 1.000
(0.003) (0.006) (0.007) (0.008)
139
Table 4.3: Results of Competing-Risk Hazard Model Using Subsamples 1.1 and 1.2 (Cont.)
MODEL 1.1 MODEL 1.2
Prepayment Default Prepayment Default
Estimates Odds Ratio Estimates Odds Ratio Estimates Odds Ratio Estimates Odds Ratio
DISCPT 0.188 1.207 -0.585 0.557 -0.348 0.706 -0.545 0.580
(0.050)***
(0.185)***
(0.132)***
(0.223)**
LOANSIZE 0.001 1.001 -0.003 0.997 0.004 1.004 -0.003 0.997
(0.001)*
(0.001)***
(0.001)***
(0.001)***
SELFEMP 0.008 1.008 -0.139 0.870 -0.082 0.921 -0.191 0.826
(0.034)
(0.117)
(0.096)
(0.146)
REFI 0.026 1.026 -0.276 0.759 -0.175 0.839 -0.237 0.789
(0.035)
(0.126)**
(0.095)*
(0.165)
NONPRIMRES -0.071 0.931 0.173 1.189 0.215 1.240 -0.040 0.961
(0.050)
(0.191)
(0.125)*
(0.244)
WHOLESALE 0.004 1.004 -0.011 0.989 -0.109 0.897 -0.021 0.980
(0.031)
(0.100)
(0.090)
(0.130)
PENÂLTY 1.069 2.913 -1.495 0.224 -0.475 0.622 -1.561 0.210
(0.169)***
(0.542)***
(0.422)
(0.670)**
month -0.009 0.991 0.088 1.092 0.348 1.416 0.220 1.246
(0.005)*
(0.013)***
(0.019)***
(0.019)***
month2 -0.001 0.999 -0.001 0.999 -0.007 0.993 -0.003 0.997
(0.000)***
(0.000)***
(0.000)***
(0.000)***
Intercept -2.999
0.474
-6.641
-3.454 (0.256)*** (0.744) (0.714)*** (0.931)***
Year Fixed-Effect YES YES
State Fixed-Effect YES YES
Number of Obs. 156,167 116,433
Pseudo R2 0.100 0.192
140
Table 4.4: Results of Competing-Risk Hazard Model Using Subsamples 2.1 and 2.2
MODEL 2.1 MODEL 2.2
Prepayment Default Prepayment Default
Estimates Odds Ratio Estimates
Odds Ratio Estimates
Odds Ratio Estimates
Odds Ratio
PENALTY -0.171 0.842 -0.051 0.951 0.229 1.258 0.866 2.377
(0.043)***
(0.154)
(0.245)
(0.338)**
ΔRATE 2.121 8.335 -1.022 0.360 -1.890 0.151 -0.993 0.371
(0.199)***
(0.595)*
(0.855)**
(1.022)
CLTV -0.206 0.814 1.092 2.981 0.711 2.036 0.937 2.553
(0.250)
(0.769)
(1.563)
(2.339)
YLDCURVE 0.703 2.021 -0.194 0.823 0.069 1.071 -0.324 0.724
(0.018)***
(0.066)***
(0.118)
(0.183)*
MORTVOL 0.437 1.548 -0.121 0.886 0.134 1.143 5.692 296.603
(0.171)**
(0.727)
(1.508)
(2.100)***
HPIVOL 0.007 1.007 0.001 1.001 0.008 1.008 -0.013 0.987
(0.002)***
(0.005)
(0.009)
(0.015)
FICO -0.002 0.998 -0.009 0.991 -0.003 0.997 -0.007 0.993
(0.000)***
(0.001)***
(0.001)***
(0.001)***
DTI -0.058 0.944 1.902 6.700 0.029 1.030 0.531 1.700
(0.157)
(0.490)***
(0.835)
(1.087)
DOC 0.098 1.103 0.459 1.583 0.246 1.279 0.586 1.796
(0.030)***
(0.102)***
(0.142)*
(0.187)***
AGE 0.005 1.005 -0.030 0.971 0.016 1.016 -0.038 0.963
(0.006)
(0.019)
(0.032)
(0.036)
AGE2 -0.000 1.000 0.000 1.000 -0.000 1.000 0.000 1.000
(0.000)
(0.000)
(0.000)
(0.000)
PROPVAL -0.001 0.999 -0.002 0.998 -0.001 0.999 -0.007 0.993
(0.000)***
(0.002)
(0.003)
(0.003)*
LTV -0.003 0.997 0.003 1.003 -0.004 0.996 -0.013 0.987
(0.003) (0.009) (0.017) (0.023)
141
Table 4.4: Results of Competing-Risk Hazard Model Using Subsamples 2.1 and 2.2 (Cont.) MODEL 2.1 MODEL 2.2
Prepayment Default Prepayment Default
Estimates Odds Ratio Estimates
Odds Ratio Estimates
Odds Ratio Estimates
Odds Ratio
DISCPT 0.143 1.153 -0.456 0.634 0.007 1.007 -0.283 0.754
(0.047)***
(0.183)**
(0.242)
(0.299)
LOANSIZE 0.002 1.002 0.000 1.000 0.002 1.002 0.006 1.006
(0.001)***
(0.003)
(0.004)
(0.005)
SELFEMP 0.002 1.002 -0.199 0.819 -0.190 0.827 -0.692 0.501
(0.038)
(0.137)
(0.191)
(0.287)**
REFI 0.003 1.003 -0.337 0.714 -0.024 0.976 0.173 1.189
(0.040)
(0.136)**
(0.215)
(0.342)
NONPRIMRES 0.030 1.030 0.424 1.528 -0.031 0.969 0.452 1.571
(0.054)
(0.188)**
(0.258)
(0.307)
WHOLESALE -0.034 0.967 -0.046 0.955 -0.043 0.958 -0.063 0.939
(0.031)
(0.102)
(0.173)
(0.228)
PENÂLT Y 0.986 2.680 -0.921 0.398 0.925 2.521 -0.486 0.615
(0.152)***
(0.529)*
(0.755)
(0.973)
month -0.025 0.975 0.060 1.062 0.667 1.949 0.425 1.530
(0.005)***
(0.013)***
(0.073)***
(0.056)***
month2 -0.000 1.000 -0.001 0.999 -0.010 0.990 -0.005 0.995
(0.000)
(0.000)**
(0.001)***
(0.001)***
Intercept -2.842
0.869
-14.550
-8.419 (0.252)*** (0.876) (1.731)*** (2.120)***
Year Fixed-Effect YES YES
State Fixed-Effect YES YES
Number of Obs. 125,367 60,400
Pseudo R2 0.100 0.192
142
Table 4.5: Results of Competing-Risk Hazard Model Using Subsamples 3.1 and 3.2
MODEL 3.1 MODEL 3.2
Prepayment Default Prepayment Default
Estimates Odds Ratio Estimates
Odds Ratio Estimates
Odds Ratio Estimates
Odds Ratio
PENALTY -0.145 0.865 0.133 1.142 -0.183 0.833 0.958 2.607
(0.021)***
(0.069)*
(0.287)
(0.263)***
ΔRATE 1.224 3.401 -0.238 0.788 -1.966 0.140 4.539 93.568
(0.106)***
(0.278)
(0.992)**
(0.769)***
CLTV -0.747 0.474 1.118 3.059 -2.713 0.066 2.027 7.589
(0.118)***
(0.351)***
(2.387)
(1.167)*
YLDCURVE 0.709 2.031 -0.221 0.802 0.046 1.047 1.920 6.820
(0.010)***
(0.036)***
(0.290)
(0.274)***
MORTVOL -1.047 0.351 -0.399 0.671 3.466 32.015 39.960 2.262e+17
(0.088)***
(0.392)
(3.187)
(3.849)***
HPIVOL 0.002 1.002 -0.001 0.999 -0.014 0.986 0.032 1.033
(0.001)*
(0.003)
(0.017)
(0.010)***
FICO -0.001 0.999 -0.009 0.991 -0.002 0.998 -0.007 0.993
(0.000)***
(0.000)***
(0.001)
(0.001)***
DTI 0.214 1.238 1.979 7.239 1.280 3.595 2.989 19.860
(0.076)***
(0.225)***
(0.823)
(0.641)***
DOC 0.074 1.077 0.436 1.547 0.328 1.388 0.679 1.972
(0.015)***
(0.048)***
(0.158)**
(0.119)***
AGE 0.003 1.003 -0.037 0.964 -0.012 0.988 -0.054 0.948
(0.003)
(0.009)***
(0.033)
(0.028)*
AGE2 -0.000 1.000 0.000 1.000 0.000 1.000 0.000 1.000
(0.000)
(0.000)***
(0.000)
(0.000)
PROPVAL -0.001 0.999 -0.001 0.999 -0.004 0.996 -0.001 0.999
(0.000)***
(0.001)*
(0.002)**
(0.002)
LTV 0.004 1.004 -0.001 0.999 0.014 1.014 -0.007 0.993
(0.001)*** (0.004) (0.019) (0.010)
143
Table 4.5: Results of Competing-Risk Hazard Model Using Subsamples 3.1 and 3.2 (Cont.)
MODEL 3.1 MODEL 3.2
Prepayment Default Prepayment Default
Estimates Odds Ratio Estimates Odds Ratio Estimates Odds Ratio Estimates Odds Ratio
DISCPT -0.046 0.955 -0.171 0.843 -0.523 0.593 0.003 1.003
(0.019)**
(0.062)*** (0.245)**
(0.160)
LOANSIZE 0.001 1.001 -0.000 1.000 0.005 1.005 -0.001 0.999
(0.000)***
(0.001) (0.002)**
(0.003)
SELFEMP -0.042 0.959 -0.018 0.982 -0.135 0.874 -0.064 0.938
(0.019)**
(0.060) (0.199)
(0.148)
REFI -0.016 0.984 -0.148 0.862 -0.286 0.751 -0.013 0.987
(0.019)
(0.057)*** (0.185)
(0.160)
NONPRIMRES -0.050 0.952 0.092 1.096 0.200 1.221 -0.210 0.811
(0.024)**
(0.076) (0.225)
(0.219)
WHOLESALE -0.060 0.942 -0.032 0.968 -0.057 0.944 -0.370 0.691
(0.018)***
(0.060) (0.271)
(0.205)*
PENÂLTY 0.541 1.718 -0.043 0.958 -0.068 0.935 0.177 1.194
(0.075)***
(0.239) (0.872)
(0.823)
month -0.034 0.966 0.048 1.049 1.885 6.589 2.349 10.470
(0.003)***
(0.007)*** (0.302)***
(0.321)***
month2 0.000 1.000 -0.000 1.000 -0.022 0.978 -0.026 0.974
(0.000)
(0.000) (0.004)***
(0.004)***
Intercept -2.724
0.518 -42.503
-56.177
(0.127)***
(0.408) (5.927)***
(6.830)***
Year Fixed-Effect YES YES
State Fixed-Effect YES YES
Number of Obs. 487,670 107,053
Pseudo R2 0.092 0.353
144
Table 4.6: Results of Bivariate-Probit Models
This table presents the estimated correlations, , of the error terms estimated from equations (4.16) and (4.17), which are jointly
estimated as a bivariate-probit model. The standard error of and the 2 statistic of the LM test ( = 0) are also provided. One, two, and
three asterisks respectively denote significance at 10%, 5%, and 1% levels.
Default Model Prepayment Model
Estimates Standard
Error
LR test: =
0
Estimates Standard
Error
LR test: =
0
Full Sample 0.087*** 0.017 27.279 -0.090*** 0.012 51.742
Subsample 1.1 0.089*** 0.029 9.279 -0.068*** 0.021 10.569
Subsample 1.2 0.140*** 0.045 9.579 -0.048 0.034 1.990
Subsample 2.1 0.113*** 0.036 9.917 -0.100** 0.028 12.431
Subsample 2.2 0.289*** 0.083 10.706 0.099 0.077 1.613
Subsample 3.1 0.093*** 0.018 27.146 -0.112*** 0.014 66.853
Subsample 3.2 0.362*** 0.078 17.818 -0.017 0.081 0.046
145
Chapter 5
Concluding Remarks
This dissertation shows that understanding the screening functions of mortgage
instruments when borrowers are heterogeneous in multiple risk dimensions is not only
theoretically interesting but also possesses significant practical importance. Chapter 2
contributes to the theoretical literature on screening and signaling by pointing out that
one outcome of the conflicting role of the prepayment penalty in screening prepayment
and default risk is the possibility of a pooling equilibrium. If the negative correlation
between prepayment penalty and prepayment risk is completely offset by the positive
correlation between prepayment penalty and default risk, then all borrower types would
have identical preferences over contract choices; hence, the prepayment penalty choice of
the borrower would have no informational value to the lender about that borrower’s
prepayment or default risk. This gives rise to a pooling equilibrium as the unique
outcome. Proposition 3 characterizes the conditions under which such an equilibrium
outcome emerges. Proposition 4 states that a pooling equilibrium can exist even if the
two opposing screening roles of prepayment penalty for prepayment and default risk do
not completely offset each other—that is, even if different borrower types will prefer
different mortgage contracts. This possibility arises when there is a contract that yields
the same expected profits to the lenders, regardless of the borrower’s type that chooses
that contract. Proposition 4 states the conditions under which and when such contracts
exist, it becomes the pooling equilibrium contract. As stated above, what is interesting
about this pooling equilibrium is that it is inferior to the first-best contract of both types.
146
This is in contrast to a typical pooling equilibrium, in which only one borrower type
receives less utility than her first-best contract, while the other borrower type receives the
same utility as her first-best contract.
The contribution of the chapter 3 is threefold. First, it shows that the
heterogeneity of transaction costs can explain the commonly observed practice of lenders
offering a menu of loans with a wide range of points-coupon combinations. The study
compliments existing mortgage-choice literature by supplying an alternative theory on
why people choose to pay points. Second, the study finds empirical support for the
transaction-costs theory, by using a new measure that isolates the effect of transaction
costs from that of mobility. This new measure focuses on the extent that borrowers
overpay in terms of mortgage rate. A borrower may overpay for his mortgage due to
either high transaction cost (e.g. cost of search and bargaining) or limited expected
holding period. While the high transaction cost often correlates with a reduced tendency
of prepayment, shorter expected holding period implies exactly the opposite. Thus, if the
―overvaluedness‖ of a mortgage loan is negatively correlated with the probability of
prepayment, it is highly likely caused by high transaction cost rather than high mobility. I
support the validity of this measure by showing that borrowers with overvalued loans are
less likely to prepay. In particular, these loans are less responsive to declining interest
rates. Finally, to the knowledge, this is the first study examining the relation between the
signaling role of discount points and mortgage securitization. The unique dataset enables
us to study the originator’s interpretation of borrowers paying discount points. I show that
mortgage originators employ a points-coupon menu to sort loans based on transaction
147
costs, and mortgages held by high-cost borrowers are more likely to be retained by the
originator.
Chapter 4 reconsiders the popular predation view on subprime lending products
by examining borrowers’ choice of prepayment penalties under information asymmetry. I
show that there exists a separating equilibrium such that borrowers with high default risk
select mortgage contracts with a prepayment penalty and receive a low contract rate, and
vice versa. Thus, the positive correlation between prepayment penalties and mortgage
delinquencies, defaults, and foreclosures does not necessarily imply that prepayment
penalties elevate default risk. It may simply reflect the fact that borrowers who are
intrinsically riskier tend to select loans with a prepayment penalty. In addition, the third
essay confronts a challenge usually encountered by empirical tests of information
asymmetry: separating moral hazard from adverse selection. The study exploits the fact
that loan performance remains observable after prepayment penalties expire. To rule out
the potential causal effect of prepayment penalties on loan performance, I focus on loan
terminations in time periods when prepayment penalties are no longer effective.
Empirical evidence supports the adverse selection hypothesis.
This dissertation also answers two important questions asked at the beginning of
this dissertation. First, how do different borrowers risk dimensions interact with each
other and why are those interactions important? The first essay shows that default and
prepayment risks may offset each other and generate pooling equilibria that compromise
the screening function of certain mortgage instruments. This outcome does not exist
when default risk or prepayment risk is considered separately. The second essay shows
that prepayment risk may be further separated into mobility and transactions costs.
148
Although both are sources of greater likelihood of prepayment, lenders may not treat both
with equal importance. Finally, the third essay points out a potential linkage between
prepayment and default risks. When borrower income is commonly used in underwriting
for determining a borrower’s qualification, default and prepayment risks are tied together.
Compromised financial strength not only may trigger default but also may increase the
probability that a borrower is ineligible for a new loan. The choice of prepayment penalty
reflects this linkage and has important policy implications.
The second question addressed by this dissertation is that: Does allowing a
greater variety of mortgage choices benefit consumers? Based on the work here, the
answer is positive. The first essay shows that a single instrument (e.g. prepayment
penalty) is insufficient to screen two risk dimensions. Allowing for the simultaneous use
of more instruments may potentially mitigate this problem. The third essay indicates that
eliminating the choice of prepayment penalty is equivalent to forcing an inefficient
pooling equilibrium. The social welfare and consumer welfare are both reduced by the
prohibition of prepayment penalties. In summary, the studies here suggest that a greater
variety of mortgage products is desirable and should be promoted.
149
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Appendix A
Proofs of Propositions in Chapter 2
Proof of Proposition 2.1:
A separating equilibrium under information asymmetry is a set of contracts such
that (a) the contract assignments are consistent with incentive compatibility, (b) lenders
earn zero profit, and (c) no other contracts outside the equilibrium set attracts borrowers
while generating nonnegative profit. Conditions (a) and (b) collectively imply
),,(),( hhllll siUsiU
(a.1)
),,(),( llhhhh siUsiU
(a.2)
,0),( lll si
(a.3)
,0),( hhh si
(a.4)
where )( jU denotes the utility function of type j borrowers ( lhj , ), and
),( jj si denotes the equilibrium contract of type j borrowers. Equations (a.1) and (a.2) are
the incentive compatibility constraints. Equations (a.3) and (a.4) are the zero-profit
conditions.
Consider the case where borrowers are different only in their mobility.
Superscripts h and l respectively denote the high- and low-mobility type. Recall that
points closer to the origin are associated with greater utility. Conditions (a.3) and (a.4)
imply that the equilibrium contract for each type must respectively lie on their zero-profit
curves. Because the high-mobility zero-profit curve lies above the low-mobility zero-
profit curve, low-mobility borrowers have no incentive to mimic the high-mobility type.
157
In other words, condition (a.1) is not binding. As a result, the equilibrium high-mobility
contract must lie at the tangency point between the lowest high-mobility indifference
curve and the high-mobility zero-profit curve. This contract is the same as the high-
mobility first-best contract ),( ** hh si .
With the equilibrium contract for the high-mobility borrower determined, (a.2)
and (a.3) collectively imply the low-mobility equilibrium contract ),( ll si must be located
where the high-mobility indifference curve passing through ),( ** hh si cuts the low-
mobility zero-profit curve. First, (a.3) implies that ),( ll si must lie on the low-mobility
zero-profit curve. Second, because (a.2) must be binding, only intersections between the
high-mobility indifference curve passing through ),( ** hh si and the low-mobility zero-
profit curve satisfies both conditions. An intersection could be either above or below
),( ** hh si . However, the necessary condition that no alternative contract can generate
nonnegative profit implies the equilibrium contract for low-mobility borrower, ),( ll si ,
can only be above the two first-best contracts. Let us denote the intersection below
),( ** hh si by )','( ll si . As I established previously, the low-mobility indifference curve is
steeper than the high-mobility indifference curve passing through any given ),( si .
Consider the low-mobility indifference curve passing through )','( ll si . Its segment above
)','( ll si must be above the high-mobility indifference curve. Thus, an alternative
contract located to the northwest of )','( ll si and between the two indifference curves
passing through )','( ll si will only attract low-mobility borrowers. Such a contract
158
generates positive lending profit as it is above the low-mobility zero-profit curve.
Therefore, )','( ll si cannot be in the equilibrium contract set.
Now, I verify that when ),( ** hh si and ),( ll si are simultaneously offered, no
alternative contract can attract borrowers without making negative profit. Consider the
two indifference curves of high- and low-mobility types passing through ),( ll si . First, a
contract that is above both indifference curves attracts no one because both ),( ** hh si and
),( ll si are superior (closer to the origin). Second, a contract that is below the low-risk
zero-profit curve always generates negative profit and, thus, will not be offered. Third,
the assumption that is sufficiently large rules out contracts below both indifference
curves passing through ),( ll si , but above the low-mobility zero-profit curve. Such a
contract attracts both types but generates negative profits. Finally, a contract that is
between the two indifference curves passing through ),( ll si attracts only the high-
mobility type. Because such a contract is below the high-mobility zero-profit curve, it
generates negative profits. Therefore, ),( ** hh si and ),( ll si constitute a separating
equilibrium.
A.2. Proof of Proposition 2.2:
Consider the case where borrowers are different only in their default risk.
Superscripts h and l respectively denote the high- and low-default type. Conditions (a.1),
(a.2), (a.3), and (a.4) must hold at an equilibrium. Conditions (a.3) and (a.4) imply that
the equilibrium contract for each type must respectively lie on their zero-profit curves.
159
Because the high-default zero-profit curve lies above the low-default zero-profit curve,
low-default borrowers have no incentive to mimic the high-default type. In other words,
condition (a.1) is not binding. As a result, the equilibrium high-default contract must
locate at the tangency point between the lowest high-default indifference curve and the
high-default zero-profit curve. This contract is the same as the high-mobility first-default
contract ),( ** hh si .
With the equilibrium contract for high-default borrower determined, (a.2) and
(a.3) collectively imply that the low-default equilibrium contract ),( ll si must be located
where the high-mobility indifference curve passing through ),( ** hh si cuts the low-default
zero-profit curve. First, (a.3) implies that ),( ll si must lie on the low-default zero-profit
curve. Second, because (a.2) must be binding, only intersections between the high-default
indifference curve passing through ),( ** hh si and the low-default zero-profit curve
satisfies both conditions. An intersection could be either above or below ),( ** hh si .
However, the necessary condition that no alternative contract can generate nonnegative
profit implies the equilibrium contract for low-default borrower, ),( ll si , can only be
below the two first-best contracts. Let us denote the intersection above ),( ** hh si by
)','( ll si . As I established previously, the low-default indifference curve is flatter than
the high-default indifference curve passing through any given ),( si . Consider the low-
default indifference curve passing through )','( ' ll si . Its segment below )','( ll si must be
above the high-default indifference curve. Thus, an alternative contract located to the
160
southeast of )','( ll si and between the two indifference curves passing through )','( ll si
will only attract low-default borrowers. Such a contract generates positive lending profit
as it is above the low-default zero-profit curve. Therefore, )','( ll si cannot in the
equilibrium contract set.
Now, I verify that when ),( ** hh si and ),( ll si are simultaneously offered, no
alternative contract can attract borrowers without making negative profit. Consider the
two indifference curves of high- and low-default types passing through ),( ll si . First, a
contract that is above both indifference curves attracts no one because both ),( ** hh si and
),( ll si are superior (closer to the origin). Second, a contract that is below the low-default
zero-profit curve always generates negative profit and, thus, will not be offered. Third,
the assumption that y
is sufficiently large rules out contracts below both indifference
curves passing through ),( ll si , but above the low-default zero-profit curve. Such a
contract attracts both types but generates negative profit. Finally, a contract that is
between the two indifference curves passing through ),( ll si attracts only the high-default
type. Because such a contract is below the high-default zero-profit curve, it generates
negative profit. Therefore, ),( ** hh si and ),( ll si constitute a separating equilibrium.
A.3. Proof of Proposition 2.3:
Consider a set of pooling contracts ),( pp si that satisfy
01 BAAA . The locus of the set of pooling contracts is given by
161
./
/
p
p
p
p
s
i
i
s (a.5)
I refer to (a.5) as the zero-profit pooling curve. Consider the pooling contract
),( ** pp si at the tangency point between type-A indifference curve and the zero-profit
pooling curve. Equation (2.10) suggests that type-B indifference curve overlaps
completely with the type-A indifference curve and must also be tangent to the zero-profit
pooling curve at ),( ** pp si . It is clear that ),( ** pp si yields zero profit when it is offered
to both types. I now show that there exists no alternative contract that attracts borrowers
and makes nonnegative profits. First, a contract that is above both indifference curves
attracts no one. Second, a contract that is above both indifference curves attracts both
types. However, because such a contract is also below the zero-profit pooling curve, it
will generate negative profit. Therefore, ),( ** pp si constitute a pooling equilibrium.
A.4. Proof of Proposition 2.4:
Consider a pooling contract ),( QQ si located at the intersection point Q of two
zero-profit curves. It is clear that ),( QQ si yields zero profits when it is offered to both
types. For ),( QQ si to be an equilibrium, I must show that there exists no alternative
contract that attracts borrowers and makes nonnegative profits. Consider the two
indifference curves of high- and low-default types passing through ),( QQ si . First, a
contract that is above both indifference curves attracts no one because ),( QQ si is superior
(closer to the origin). Second, a contract that is below both zero-profit curves always
162
generates negative profit and, thus, will not be offered. Third, the assumption about y
and y
1 rules out contracts below both indifference curves passing through ),( QQ si ,
but above both zero-profit curves. Such a contract attracts both types but generates
negative profit. Finally, a contract that is between the two indifference curves passing
through ),( ll si attracts only the high-default type and makes negative profits. Consider a
contract between the two indifference curves passing through ),( QQ si . It is either above
or below Q. When it is above Q, it must be below the type-A indifference curve and
above the type-B indifference curve. This is because the type-A indifference curve is
steeper. Thus, such a contract attracts only type-A borrowers. However, such a contract is
below the type-A zero-profit curve, hence generates negative profit. A similar logic rules
out an alternative contract below Q. When it is below Q, it must be above the type-A
indifference curve and below the type-B indifference curve. This is because the type-A
indifference curve is steeper. Thus, such a contract attracts only type-B borrower.
However, such a contract is below the type-B zero-profit curves, hence it generates
negative profits. Therefore, ),( QQ si constitute a separating equilibrium.
A.5. Proof of Proposition 2.5:
A.5.1. No intersection between zero-profit curves.
Assuming two zero-profit curves do not cross, a separating equilibrium is feasible
when the slopes of borrower indifference curves are different between type A and type B.
In general, I will show that the borrower type with a steeper (flatter) indifference curve
will select a contract with a high (low) prepayment penalty. Thus, borrower type A will
163
select a high prepayment penalty and borrower type B will select a low prepayment
penalty if B
U
A
U MRSMRS —that is, if
.
)1)(1(1
)1)(1(1
2,1
2,1
A
B
AB
j
j
BA
j
j
yy
yy
(a.6)57
Before I formally show this result, it is easy to see that the cases where borrowers
are different in either mobility or default risk can be viewed as special scenarios of the
more general case discussed here. The case when borrowers are different only in mobility
corresponds toBA
yy . In this case, the right-hand side of expression (a.6) becomes one,
and (a.6) is satisfied conditional on BA . This is consistent with the intuition that a
low-mobility borrower will self-select into a contract with a high prepayment penalty and
a low interest rate. When borrowers are different only in default risk, I have BA ,
and the left-hand side becomes one. Expression (a.6) is satisfied if BA
yy . I obtain the
result that high-default-risk borrowers (the ones with a lower y ) obtain loans with a
greater prepayment penalty and a lower interest rate than low-default-risk borrowers.
A.5.1.a: Type A zero-profit curves lies above type B zero-profit curves
57 The parameter condition that produces the other scenario that borrower type A selects low prepayment
penalty and borrower type B selects high prepayment penalty can be easily obtained by switching the
superscripts A and B in equation (2.11).
164
A separating equilibrium under information asymmetry is a set of contracts such
that (a) the contract assignments are consistent with incentive compatibility; (b) lenders
earn zero profit, and (c) no other contracts outside the equilibrium set attracts borrowers
while generating nonnegative profit. Condition (a) and (b) collectively implies
),,(),( BBAAAA siUsiU
(a.7)
),,(),( AABBBB siUsiU
(a.8)
,0),( AAA si
(a.9)
,0),( BBB si
(a.10)
where )( jU denotes the utility function of type j borrowers ( BAj , ), and ),( jj si
denotes the equilibrium contract of type j borrowers. Equations (a.7) and (a.8) are the
incentive compatibility constraints. Equations (a.9) and (a.10) are the zero-profit
conditions, which imply that the equilibrium contract of each type must respectively lie
on their zero-profit curve. Because type A zero-profit curve lies above type B zero-profit
curve, type B borrowers have no incentive to mimic type A. In other words, condition
(a.8) is not binding. As a result, the equilibrium type A contract must lie at the tangency
point between the lowest type A indifference curve and the type A zero-profit curve. This
contract is the same as the type-A first-best contract ),( ** AA si .
With the equilibrium contract for type A borrowers determined, (a.7) and (a.10)
collectively imply the type B equilibrium contract ),( BB si must be located where the
165
type A indifference curve passing through ),( ** AA si cuts the type B zero-profit curve.
First, (a.10) implies that ),( BB si must locate on the type B zero-profit curve. Second,
because (a.7) must be binding, only intersections between the type A indifference curve
passing through ),( ** AA si and the type-B zero-profit curve satisfies both conditions. An
intersection could be either above or below ),( ** AA si . However, the necessary condition
that no alternative contract can generate nonnegative profit implies the equilibrium
contract for low-mobility borrower, ),( BB si , can only be below the two first-best
contracts. Let us denote the intersection above ),( ** AA si by )','( BB si . As I established
previously, the type B indifference curve is flatter than the type A indifference curve
passing through any given ),( si . Consider the type B indifference curve passing through
)','( BB si , its segment below )','( BB si must be above the type-A indifference curve.
Thus, an alternative contract located to the southeast of )','( BB si and between the two
indifference curves passing through )','( BB si will only attract type-B borrowers. Such a
contract makes positive profit as it is above type-B zero-profit curve. Therefore,
)','( BB si cannot be in the equilibrium contract set.
Now, I verify that when ),( ** AA si and ),( BB si are simultaneously offered, no
alternative contract can attract borrowers without making negative profit. Consider the
two indifference curves of type A and type B passing through ),( BB si . First, a contract
that is above both indifference curves attracts no one, because both ),( ** AA si and
),( BB si are superior (closer to the origin). Second, a contract that is below the type B
166
zero-profit curve always generates negative profit and, thus, will not be offered. Third,
the assumption that A is sufficiently large rules out contracts below both indifference
curves passing through ),( BB si but above the type-B zero-profit curve. Such a contract
attracts both types but generates negative profit. Finally, a contract that is between the
two indifference curves passing through ),( BB si attracts only type A. Because such a
contract is below the type A zero-profit curve, it generates negative profit. Therefore,
),( ** AA si and ),( BB si constitute a separating equilibrium.
A.5.1.b: Type A zero-profit curves lies below type B zero-profit curves
I then consider the situation when the type A zero-profit curve lies below the type
B zero-profit curve. Conditions (a.7), (a.8), (a.9), and (a.10) must be satisfied in an
equilibrium. (a.9) and (a.10) imply that the equilibrium contract of each type must
respective lie on their zero-profit curve. Because the type A zero-profit curve is below the
low-mobility zero-profit curve, type A borrowers have no incentive to mimic type B. As a
result, (a.7) is not binding. As a result, the equilibrium type-B contract must locate at the
tangency point between the type B indifference curve and the type B zero-profit curve.
This contract is the same as the high-mobility first-best contract ),( ** BB si .
With the equilibrium contract for type B determined, (a.8) and (a.9) collectively
imply that the type A equilibrium contract ),( AA si must be located where the high-
mobility indifference curve passing through ),( ** BB si cuts the type A zero-profit curve.
First, (a.9) implies that ),( AA si must locate on the type A zero-profit curve. Second,
167
because (a.8) must be binding in an equilibrium, only intersections between the type B
indifference curve passing through ),( ** BB si and the type A zero-profit curve satisfies
both conditions. An intersection could be either above or below ),( ** BB si . However, the
equilibrium condition that no alternative contract can generate nonnegative profit implies
the equilibrium contract for type A borrower, ),( AA si , can only be above the two first-
best contracts. Let us denote the intersection below ),( ** BB si by )','( AA si . Because the
type A indifference curve is steeper than the type B indifference curve passing through
any given ),( si . Consider the type A indifference curve passing through )','( AA si . Its
segment above )','( AA si must be above the type-B indifference curve passing through the
same point. Thus, an alternative contract located to the northwest of )','( AA si and
between the two indifference curves passing through )','( AA si will only attract type-A
borrowers. Such a contract makes positive profit as it is above the type A zero-profit
curve. Therefore, )','( AA si cannot be in the equilibrium contract set.
Now, I verify that when ),( ** BB si and ),( AA si are simultaneously offered, no
alternative contract can attract borrowers without making negative profit. Consider the
two indifference curves of type A and type B passing through ),( AA si . First, a contract
that is above both indifference curves attracts no one because both ),( ** BB si and ),( AA si
are superior (closer to the origin). Second, a contract that is below the type A zero-profit
curve always generates negative profit and, thus, will not be offered. Third, the
assumption that A1 is sufficiently large rules out contracts below both indifference
168
curves passing through ),( AA si . Such a contract attracts both types but generates
negative profit. Finally, a contract that is between the two indifference curves passing
through ),( AA si attracts only the type B borrower. Because such a contract is below the
type A zero-profit curve, it generates negative profit. Therefore, ),( ** BB si and ),( AA si
constitute a separating equilibrium.
A.5.2: Zero-profit curves intersect and tangency points are on the same side of Q.
I will now discuss the case when the two zero-profit curves intersect each other,
and the tangency points between indifference curves and the respective zero-profit curves
for the two types lie on the same side of Q. I first consider the case when the two
tangency points are above Q . I want to show that there exists a separating equilibrium
such that the type A borrower receives their first-best contract ),( ** AA si , which
corresponds to the tangency point between the lowest indifference curve and the zero-
profit curve for the type A borrower, and the type B borrower receives contract ),( BB si .
),( BB si is shown in figure A.5.1 as the intersection between the type A indifference
curve passing through ),( ** AA si and the type B zero-profit curve. I construct the proof in
two steps.
First, let us only consider contracts above Q, that is, contracts with Qss .
Because the type A zero-profit curve is steeper, it must lie above the type B zero-profit
curve. By considering the subset of contracts above Q, I have the scenario described in
A.5.1.a, in which the type-A zero profit curve lies above the type-B zero-profit curve. By
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the proof in A.5.1.a, I know that ),( ** AA si and ),( BB si sustain as a separating
equilibrium when only this subset of contracts is available. Second, I add the contracts
with Qss to see if ),( ** AA si and ),( BB si still constitute an equilibrium. Because both
tangency points are above Q, the type A indifference curve passing through ),( ** AA si
must be below the type-A zero-profit curves for Qss . Because ),( BB si is above Q, the
type-B indifference curve passing through ),( BB si must be below the type-B zero-profit
curves for Qss . As a result, in order to have a contract below Q to attract at least one
type of borrowers, it must make negative profit. Therefore, adding contracts below Q
does not break the separation. Thus, ),( ** AA si and ),( BB si still constitute a separating
equilibrium.
In the alternative case, where the two tangency points are below Q (shown in fig.
5.2), I construct a proof using a similar logic. I want to show that there exists a
separating equilibrium such that type B borrowers receive their first-best contract
),( ** BB si , which corresponds to the tangency point between the lowest indifference
curve and the zero-profit curve for type B, and that type A borrowers receive contract
),( AA si . ),( AA si is shown in figure A.5.2 as the intersection between the type B
indifference curve passing through ),( ** BB si and the type A zero-profit curve. Again, I
construct the proof in two steps.
First, let us only consider contracts below Q, that is, contracts with Qss .
Because the type A zero-profit curve is steeper, it must lie below the type B zero-profit
curve. By considering the subset of contracts below Q, I have the scenario described in
170
A.5.2.a. By the proof in A.5.2.a, I know that ),( AA si and ),( ** BB si sustain as a
separating equilibrium when only this subset of contracts is available. Second, I add the
contracts with Qss to see if ),( AA si and ),( ** BB si still constitute an equilibrium.
Because both tangency points are below Q, the type B indifference curve passing through
),( ** BB si must be below the type-B zero-profit curves for Qss . Because ),( AA si is
below Q, the type-A indifference curve passing through ),( AA si must be below the type-
B zero-profit curves for Qss . As a result, in order to have a contract above Q to attract
at least one type of borrowers, it must make negative profit. Therefore, adding the
contracts above Q does not break the separation. Thus,
),( AA si and ),( ** BB si still
constitute a separating equilibrium.
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Appendix B
Proof of Proposition 1 in Chapter 4
Proof. The proof presented here follows the framework developed in Posy and Yavas
(2000). First, I prove that if );(),( ***
Lpn
L
nH
H
pn iiiii , then the separating equilibrium
exists. Consider Figure 4.1. Assume );(),( ***
Lpn
L
nH
H
pn iiiii . Since ** ),( L
nH
H
pn iii ,
the contract pair ),( ** H
p
L
n ii is above the high-risk indifference curve, and since
);( **
Lpn
L
n iii and **
p
H
p ii the contract pair ),( ** H
p
L
n ii is below the low-risk indifference
curve. Therefore, if such a contract pair is offered, high risks will choose contract p and
low risks will choose contract n and lenders will make zero profits from each borrower
type. In Figure 4.1, pi ' represents the greatest contract-p rate that will attract both
borrower types. Since );( **
Lpn
L
n iii , the zero-profit pooling contract-p rate *
pi is greater
than pi ' Therefore, there exists no contract p to which lenders can deviate, attract both
borrower types, and earn nonnegative profits. The condition means that the lowest
contract-n rate that will attract both borrower types is less than *L
ni (which is less than the
zero profit pooling contract-n rate *
ni ). As a result, no lender can offer contract n to attract
both borrower types and earn nonnegative profits. So, if );(),( ***
Lpn
L
nH
H
pn iiiii ,
then ),( ** H
p
L
n ii is a separating equilibrium which lenders earn zero expected profits.
I now prove the only if statement. Assume that there exists a separating
equilibrium where high risks obtain contract p with rate *H
pi , low risks obtain contract n
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with rate *L
ni , and lenders earn zero expected profits. Then, it must be that
** ),( L
nH
H
pn iii , or else high risks will prefer contract n at rate *H
ni . In addition, it must
be the case that );( **
Lpn
L
n iii , or else pp ii '* , in which case a lender can offer a
contract p at the rate ]',( *
ppp iii , attract both borrower types, and earn positive profits.
Therefore, if there exists a separating equilibrium where high risks obtain contract p with
a rate *H
pi , low risks obtain a contract n with rate *L
ni , and lenders earn zero expected
profits, then );(),( ***
Lpn
L
nH
H
pn iiiii .
VITA
Xun Bian
Office Address: Office Phone: 814-863-5454
360 A Business Building Email: [email protected]
Dept. of Insurance and Real Estate Citizenship and Visa Status:
The Pennsylvania State University P. R. China, F-1 student visa
University Park, PA 16802
Education
The Pennsylvania State University – University Park
Ph.D Candidate in Business Administration, Real Estate Aug, 2011 (expected)
Dissertation: ―Information Asymmetry and Mortgage Choices‖ (Proposal Defended in April, 2010)
Dissertation Committee: Brent W. Ambrose (Chair), Edward Coulson, Austin Jaffe, Jiro Yoshida
Illinois Wesleyan University
B.A. in Economics (Cum Laude) May, 2005
(Minor in Mathematics)
Research Interests
Real Estate Capital Markets, Corporate Finance, and Household Finance
Refereed Publication
Ambrose, B. W. and X. Bian. ―Stock Market Information and REIT Earnings Management‖
Journal of Real Estate Research. 2010. 32(1): 101-138.
► 2009 Best Paper Award (1st Place) at the Structural Issues Facing Real Estate
Investment Trusts Conference, Baruch College, New York, NY.
Teaching Experience
Instructor (full responsibility)
R EST 301: Real Estate Fundamentals
The Pennsylvania State University – University Park Summer 2008, Spring 2009
R EST 420: Analyzing Real Estate Markets
The Pennsylvania State University – University Park Spring 2010