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HAVERFORD COLLEGE
Determinants of Stock Market Participation Among Elderly U.S. Households with Internet Access
Christopher Leung
Supervised by Biswajit Banerjee 5/2/2013
This study is an analysis of the determinants of stock market participation,. t looks broadly at the literature concerning stock market participation determinants and limits it to the elderly population in the United States with Internet access. In addition, it looks in depth and differentiates between reduced participation costs and the accessibility of those costs by examining the specific financial activities conducted on the Internet by households. Through econometric analysis, the use of the Internet for financial market research leads to an increase in probability of stock market participation by 21.8% while the use of an online brokerage shows an increase in probability by 38.7%. And so, finance-oriented Internet usage is seen to be important due to the widespread availability of the Internet, rendering regular Internet use less meaningful in the context of stock market participation.
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I. Introduction
In 1985, Mehra and Prescott proposed that an alternative model to the traditional Arrow-
Debreu general would better model the observed historical differential returns of risky and
riskless assets (shown in Table 1) by incorporating additional frictional factors such as
transaction, information, and entry costs – soon after, an interest developed around the low stock
market participation rates themselves (i.e. stock market participation puzzle) to respond to the
equity premium puzzle and has consequently sparked numerous studies seeking important stock
market participation determinants that address an easing of the above mentioned market frictions.
The equity premium puzzle and stock market participation puzzle have become entangled
in a sub-strand of the literature due to the large societal shift that occurred during the late 1980s
and has defined the 1990s and early 2000s, i.e. the mass adoption of computers and subsequently
the Internet. Why may this be of large potential significance? If we look at the financial
participation rates from 1989 to the present, as shown in Table 2, it can be seen that there was a
steady positive trend in stock market participation, which started in 1989 and peaked in 2001.
After having peaked, the U.S. stock market participation rate has declined ever since. The current
trend can be traced to the collapse of the “Internet bubble” and extended by the 2008 Financial
Crisis. Participation in the other financial markets (bonds, transactional accounts, and certificates
of deposit) follows a similar trend and confirms the hypothesized primary cause. With the asset
bubble bursts, the effect of the Internet is hidden in these numbers, yet the Internet is here to stay
and it would be ill-informed to not take into account its effect on stock market participation rates
along with the determinants integral in modeling these participation rates.
Older studies have overlooked the trend towards universal access to the Internet for U.S.
households (from the 2010 U.S. Census, it has been reported that 60.1% of individuals sampled
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had access to the Internet), and focused their examination on simple Internet usage. It is idealistic
to think that the reduction in participation costs are distributed evenly and fairly, however from a
more realistic stance, reduction in participation costs are more likely privileges, rather than rights
– i.e. as applies to most thing, it is only available to a select few, rather than to all. And so, I
believe the question I wish to address changes from how regular Internet use affects households
and their stock market participation decision to how specific households are able to take
advantage/exploit reduced costs with finance-oriented Internet usage. In the following study, I
examine various household characteristics, focusing on how households use the Internet to
access these reduced costs with my elderly U.S. household sample.
The remainder of this paper reviews older literature in Section II, provides a data
description in Section III, and presents the econometric analysis and results in Section IV, V, and
VI. Results and impact of this study are summarized and enunciated in the final section, Section
VII.
II. Literature Review
In a bottom-up approach, much of the literature has analyzed household behavior through
the determinants of stock market participation rates, which is defined as the percentage of U.S.
households that own stocks. I intend to inform my study with their conclusions, ensuring that the
literature is applicable to my sample, which treats stockholding in elderly U.S. households.
In studies looking at the overall U.S. stock market participation rate, the models make use
of a dependent variable that is a binary variable for whether or not a household owns stock at a
particular time t. In the literature surveyed, seven out of ten papers use this binary variable. The
other three papers are less focused on the stockholding aspect of the stock market; Choi, Laibson,
and Metrick (2000) and Barber and Odean (2002) focus primarily on trading and the profile of
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traders and as a result, they use dependent variables that treat trade frequency and usage of an
online broker. Cole and Shastry (2009) look at cognitive ability and its effect on financial market
participation, and therefore use amount of investment income as their dependent variable. Since
these three papers do not exactly focus on stock market participation determinants, but rather
trader profiling and education effects on financial markets, it is not unusual that the dependent
variables in these studies are different.
Returning to the binary variable used as a dependent variable by the majority of the
relevant literature, we find that it is built and conceptualized through the Consumption of
Capital Assets Pricing Model (CCAPM). It is the primary model used to predict the optimal level
of capital asset consumption and has led to the claim that on average, U.S. households do not
appreciate the equity premium present in the stock market, shown by their sub-optimal level of
stocks in their portfolio.
Bogan (2008) builds a calibrated CCAPM model from the standard frictionless CCAPM
by adding constraints, i.e. information costs and transaction costs, satisfying the necessary
frictional conditions suggested by Mehra and Prescott (1985). This model has its base in a
household’s utility optimization equation in regard to its allocation of disposable income to
capital assets. Because theory expects that individuals maximize their utility function,
economists are able to model the optimal allocation levels from an indirect utility derived from
the CCAPM. Following Bogan’s approach in defining the dependent variable, one differentiates
between the assumed linear indirect utility function of stockholders,𝑈𝑠𝑖 = 𝑋𝑠𝑖𝐵𝑠 + 𝑒𝑠𝑖, and that
of non-stockholders, 𝑈𝑛𝑠𝑖 = 𝑋𝑛𝑠𝑖𝐵𝑛𝑠 + 𝑒𝑛𝑠𝑖, where Xi are observable characteristics of household
i and ei is the error term. Because the indirect function is unobservable, one must turn to the
participation decision of household i, Di – to participate or to abstain. If we let 𝐷𝑖 = 1 when
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𝑈𝑠𝑖 > 𝑈𝑛𝑠𝑖, we would say that a household participates in the stock market because their indirect
utility is greater when holding stocks than when they are not. Following suit, 𝐷𝑖 = 0 when
𝑈𝑠𝑖 < 𝑈𝑛𝑠𝑖 , since the household will abstain from the stock market since their utility is not
maximized when they hold stocks. These outputs, 𝐷𝑖 = 1 𝑎𝑛𝑑 𝐷𝑖 = 0, are the two outcomes of
this binary dependent variable.
Leaving the left side of the equation and moving towards the right side, we turn our focus
to the household characteristics that affect the probability that a household owns stock at time t.
To organize my approach of the significant and valid explanatory variables, I look to provide a
broad perspective by reviewing significant stock market participation determinants applicable to
the whole of the United States, which I classify into two categories: (1) general household
characteristics and (2) Internet-specific determinants. As it is hard to define such categories that
are mutually exclusive, I navigate the first section by addressing individual independent
variables found to be significant in the literature and group them under the general household
characteristics designation. In the second section, I focus on Internet-specific variables as they
address specifically the new environment in which we find ourselves.
General Household Characteristics As Determinants Of Stock Market Participation Age
Given the survey data often used in the literature, some identifying household
characteristics are significant in determining stock market participation. From the literature, age
is generally agreed to be an important determinant and can be explained by a variety of reasons.
However, there exists support of both statistically significant negative and positive coefficients
on the age variable. Explanations concerning the negative correlation between stockholding and
age are defended by the finite investment horizon of households as well as age-dependent risks,
such as health risks (Vissing-Joregenson 2002; Cole and Shastry 2009), while those that have
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positive coefficients on their age variable look at the potential for exogenous information
revelation, i.e. households learn more about the stock market randomly over time, such that age
increases the probability of stock ownership (Bertaut 1998).
For those papers that do not find age to be significant such as Haliassos and Bertaut
(1995), the lack of significance in the age variable can be explained by the fact that the time-
horizon effect may have already been captured by a liquidity-preference variable, defined as how
willing one would is to give up liquidity for a higher return on investment. Combined with a
finite investment horizon and life-cycle, it is likely older households prefer higher liquidity over
higher returns.
Nonetheless, in the majority of the literature we find that the age variable maintains a
negative, yet significant relationship with stock market participation. (Choi, Laibson, and
Metrick 2000; Barber and Odean 2002; Vissing-Jorgenson 2002, Hong, Kubik, and Stein 2004;
Bogan 2008; Glaser and Klos 2012)
Labor Income and Financial Wealth
The finances of a household are naturally an important factor in a household’s decision to
participate in the stock market. Often used jointly and sometimes individually, labor income and
financial wealth are the main indicators of a household’s finances. In respect to the stock market
participation relationship, labor income’s effect is inconsistent in current studies, while financial
wealth has been found to be vital to the stock market participation decision.
Bertaut (1998) and Barber and Odean (2002) find that the labor income variable is
statistically insignificant but positive, whereas the rest of the papers either don’t use the labor
income variable (Vissing-Jorgenson 2002; Hong, Kubik, and Stein 2004) or find it positive and
significant in its relationship with stockholding (Haliassos and Bertaut 1995; Choi, Laibson, and
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Metrick 2000) Labor income plays into the decision as it allows a household to plan their
consumption and follow the traditional consumption smoothing theory where households that
have excess income have the tendency to save/invest in order to maintain their same level of
consumption in the future. To shed additional light on labor income as a determinant of stock
market participation, Cole and Shastry (2009) note “the share of individuals who participate in
financial markets increases as at a decreasing rate with total income, reaching a peak of
approximately 60% for households with earned income levels of $150,000.” And so, we see that
there is ambiguity in the literature concerning the place of labor income in the stock market
participation decision.
Financial wealth, as it is defined, is an asset and can be drawn upon for consumption or
investment. In its relation to stock market participation, Vissing-Jorgenson (2002) finds that “a
per period stock market participation cost of just 50 dollars is sufficient to explain the choices of
half of stock market nonparticipants.” So, the literature finds, in effect, that wealthier households
have more to invest which renders insignificant the effect of the fixed costs to stock market
participation as a barrier to entry. The literature (Haliassos and Bertaut 1995; Bertaut 1998;
Vissing-Jorgenson 2002 and Hong, Kubik, and Stein 2004; Lusardi, Rooij, and Alessie 2007)
finds unanimously that wealth holds a positive and significant correlation with the stockholding
decision for households.
Education and Financial Literacy From the literature, the consensus is that education is a primary determinant of stock
market participation and is positively correlated in its relationship. The education variable is seen
in various forms, most often in dummy variable form, divided into less than high school, high
school, and college degree or the international equivalents. It is often interpreted that education
works through the cost channel, specifically the entry cost channel and information cost channel.
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This may be due to the ability of more educated households to understand the stock market better,
open financial accounts more easily, etc. (Haliassos and Bertaut 1995; Hong, Kubik, and Stein
2004). Secondly, it may be seen to increase the ability of households to process information
and/or used as a proxy for future expected earnings. (Bertaut 1998) And so, education is
interpreted to be integral since it allows households to access the reduced information costs, if
there are any, and take advantage of the information as well as indicate a boost in future labor
income and investment income.
In a study dedicated to education and financial market participation, Cole and Shastry
(2009) use instrumental variable analysis to establish a causal link between the two. They
conclude that education is an integral factor in encouraging households to participate in various
financial markets (stocks, bonds, mutual funds, savings, IRAs, CDs, etc.) They estimate the
effect of an additional year of schooling on stock market participation to be around +1.5%.
Financial literacy is another interesting variable to consider; as it has been shown to
reduce information costs to a level that makes the stock market more attractive to households. It
works through a channel similar as education and can be explained by the ability or inability to
process this financial information. Working through the information cost channel, it is likely that
those with a higher level of financial literacy are more able to apply their knowledge to matters
concerning the financial markets, thus able to “access” the already reduced information costs
created by the expansion of financial resources and tools and media attention.
In addition, the financial literacy variable is gaining in importance as individuals are
claiming more responsibility over their financial futures with the advent of new financial
products and the increasing customizability of retirement plans. (Lusardi, Rooij, and Alessie
2007; Cole and Shastry 2009)
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Lusardi, Rooij, and Alessie (2007) approach stockholding by way of financial literacy
and measure it with two special modules, which are composed of an “extensive list of questions
aimed at measuring and differentiating among different levels of literacy and financial
sophistications.”In the first module, they look at basic financial literacy, asking questions about
concepts such as inflation and interest rate. In the second, they look at more advanced concepts
such as valuation, difference between asset classes, and portfolio diversification strategies. As
theory expects them to, financial literacy increases the probability that a household owns stock
because stocks are relatively complex assets. Accordingly, it takes financial knowledge to
understand stock market processes and fundamental stock analysis – and so, financial literacy
reduces information costs by increasing the efficiency of financial information processing. From
their empirical analysis, Lusardi, Rooij, and Alessie (2007) conclude that with increased
financial literacy comes a higher probability that a household will participate in the stock market
through their ability to accumulate wealth, formulate retirement plans, as well as navigate the
stock market. Their finding is statistically significant.
Internet-Specific Variables as Determinants Of Stock Market Participation The literature on stock market participation and the Internet is very limited. In this
respect, Stock Market Participation and the Internet(2008) by Vicki Bogan and Causal Evidence
on Regular Internet Use and Stock Market Participation (2012) by Glaser and Klos are the only
papers that address this relationship directly to my knowledge. Bogan makes use of a probit
model, in which computer usage is a proxy for Internet usage. From her empirical results, she
posits that computer usage is significant in a household’s decision to own stock. However, her
conclusions are applied to a broad population though her sample does not seem to be powerful
enough to make such a statement. Furthermore, she assumes that all households experience the
reductions in information costs, which is questioned by Glaser and Klos (2012), who approach
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stock market participation more realistically. Glaser and Klos attempt to establish a causal
relationship between the Internet and stock market participation rates through instrumental
variable analysis. Additionally, they pay particular attention to the interaction effect between
financial literacy and Internet usage, which has enlightened the conversation concerning the
accessibility of reduced frictional costs. This accessibility factor is central to my study.
Conclusions from both papers are similar and I will detail them here so that we can gain a
sense of what has already been explored in terms of Internet-specific variable. From Bogan’s
probit model, she estimates that computer usage increases a household’s probability of holding
stock by at least 3.4%. In a second empirical model, Bogan employs a true Internet dummy
variable (survey questions about Internet usage rather than computer usage) and estimates that
Internet usage increases a household’s probability of owning stock by about 31%. Her findings
indeed show significance in the relationship between stock ownership and Internet. Some
shortcomings of her model is seen in the broad generalizations she makes about all U.S.
households even though her sample has an average age of 65 years. She attempts to substantiate
her claim by citing the work of Ameriks and Zeldes (2001) who found that “equity portfolios
shares increased strongly with age.” However, it seems that Bogan simplifies the results of
Ameriks and Zeldes when we compare the claim with the data provided by Lusardi, Rooij,
Alessie (2007) who show that stock market participation rates do increase with age, but only up
until the age of 40 years; afterwards, the relationship levels off and remains fairly constant.
Therefore, Bogan’s assumption may be problematic when one interprets her results and leads to
a suspicion that Bogan’s results are truly not applicable to the whole of the United States.
Glaser and Klos (2012) search for a causal effect of regular Internet use on stock market
participation through the channel of reduced information costs and employ instrumental variable
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analysis. The instrumental variables were created from the responses, based on a Likert scale
ranging from 1 (totally disagree) to 4 (totally agree), to two questions: (1) “Computers and other
modern electronic hardware are simply fun” and (2) “I fear that the technical progress will
destroy our lives.” Both are valid as instrumental variables since the statements are both highly
correlated to Internet usage (F-statistic is between 41 and 45; threshold value for strong
instruments is 10) and exogenous to stock market participation (computers used for fun and
attitude towards technology do not have much of a relationship with stockholding). And so, these
assessment questions were exploitable as instrumental variables for Glaser and Klos. In the
empirical model, each of the variables is split into three dummy variables, with the omitted
variable being the response, which was equal to 1 (totally disagree). The model yielded a
participation rate of about 43.6% in households that have regular Internet using households and
14.5% among non-regular Internet using households. This result is consistent with Bogan’s
empirical analysis and conclusion in 2008. In their second model, Glaser and Klos hypothesize
that the channel of causality is that of financial literacy. Glaser and Klos find that that lower
transaction costs have no effect on the probability of holding stocks for financially illiterate
households, though the effect was very significant among the financially literate households,
yielding an increase in probability of stockholding by 8.56%. This specific analysis of the
interaction effect between financial literacy and stockholding informs the construct of
accessibility of reduced market frictions and the approach that I assume.
III. Data
To consider the relationship between stock ownership by elderly U.S. households and
how they use the Internet, I will employ the 2009 HRS Internet Survey, a specialized study that
is conducted on the Internet and collects information on independent U.S. households that
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includes financial decisions pertaining to the stock market. The 2009 Internet Survey included
4,433 observations. For a summary of how the sample was created, please refer to Table 3.
Although there are other various databases that have been represented in the literature,
the 2009 HRS Internet Survey is the first of its kind that provides specific questions that can be
used to create more direct variables, and is the driving force for my decision to use this specific
survey, even the HRS Internet Surveys earlier in the series lack the specificity in the questions
needed to look at the relevance of the Internet to the stock market.. Thus, the 2009 HRS Internet
survey is the first of its kind that has allowed such an approach to stock market participation
rates, when one considers Internet usage for financial activities as a determinant.
The data description for the two survey questions that are the basis for this study and
model are the following:
How often do you do each of the following activities on the Internet? Buy or sell stocks, mutual funds, or bonds online ............................................................................ 3692 1. Never 332 2. Rarely 238 3. Sometimes 118 4. Often 53 9. QUESTION SKIPPED ================================================================ How often do you do each of the following activities on the Internet? Get financial information online, such as stock quotes or mortgage interest rates ............................................................................ 1855 1. Never 898 2. Rarely 869 3. Sometimes 686 4. Often 125 9. QUESTION SKIPPED
The questions listed above are essential to this study since they provide a more direct
view in how the Internet affects stock market participation through these particular channels, an
online stock brokerage as well as financial research conducted on the Internet. This is where my
study finds its niche and brings us closer to our first hurdle of determining whether or not the
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Internet is a significant determinant of stock market participation and on our way to observing its
effect on overall stock market participation rates in elderly U.S. households. Having laid out the
determinants that have already been proven to be significant, I look to use these determinants
along with my Internet variables (the use of the Internet specific for financial research which
may reduce information costs and the use of an online brokerage which may reduce transaction
and entry costs) on the right side of a probit model which I will detail in the next section.
These two Internet variables are essential to my analysis since they embody the use of the
finance-oriented Internet usage in respect to stock market participation issues. The use of the
Internet for financial research looks at how households utilize the Internet specifically for
financially research, which may provide support for reduced information costs, due to increased
media attention to the stock market and an overall surge in financial news, for households that
are able to process the information. The second variable, the use of an online brokerage, obtains
its importance from its ability to reduce transaction and entry costs given the rise of online
brokerages, which has increased competition and reduced fees and commissions in the entire
industry as a whole. In addition, the participation costs are further reduced by the ease of simple
user interfaces of online brokerages and the increased efficacy in submitting orders. With these
two variables, we look singularly at how the Internet affects elderly U.S. households with
Internet access.
IV. Methodology
In my baseline specification, I use the dependent variable as defined above on the left
side of my equation in a probit model that introduces my two Internet-specific variables along
with control variables such as age, education, financial wealth, financial literacy variables, and a
proxy for income. It takes the form:
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(1)𝑆𝑇𝑂𝐶𝐾𝑆𝑂𝑉𝐸𝑅𝐴𝐿𝐿= 𝛽0 + 𝛽1𝐴𝐺𝐸 + 𝛽2𝐸𝐷𝑈 + 𝛽3𝑊𝐸𝐴𝐿𝑇𝐻 + 𝛽4𝐹𝐼𝑁𝑅𝐸𝑆𝐸𝐴𝑅𝐶𝐻+ 𝛽5𝑂𝑁𝐿𝐼𝑁𝐸𝐵𝑅𝑂𝐾𝐸𝑅𝐴𝐺𝐸 + 𝛽6𝐹𝑂𝐿𝐿𝑂𝑊𝑆𝑇𝑂𝐶𝐾 + 𝛽7𝑈𝑁𝐷𝐸𝑅𝑆𝑇𝐴𝑁𝐷𝑆𝑇𝑂𝐶𝐾+ 𝛽8𝑊𝑂𝑅𝐾𝑆_𝑃𝐴𝐼𝐷 + 𝜀𝑖
The variables that I have employed in this model are listed below: DEPENDENT VARIABLE DESCRIPTION STOCKSOVERALL Binary variable for owning stock (1 – yes, 0 – no) INDEPENDENT VARIABLES DESCRIPTION AGE Continuous Variable that denotes age of household head EDU Continuous Variable that denotes years of education for household head WEALTH Continuous Variable that denotes Household Financial Net Worth (in $100,000) FINRESEARCH Dummy variable for using the Internet for online research (1 – yes, 0 – no) ONLINEBROKERAGE Dummy variable for using an online brokerage (1 – yes, 0 – no)
FOLLOWSTOCK Dummy variable for self-assessment rating of how closely one follows stock market (1 – yes, 0 – no); proxy for financial literacy
UNDERSTANDSTOCK Dummy variable for self-assessment rating of how much one understands stock market (1 – yes, 0 – no); proxy for financial literacy
WORKS_PAID Dummy variable for working for pay (1 – yes, 0 – no) ; proxy for income My dependent variable is a binary variable that indicates whether a household owns stock
or not. I have defined stockholding to be the holding of any stock in any form, including directly
or indirectly. Direct holdings are those that are held outside of a managed asset and are most
likely held in the form of shares in individual public corporations. On the right side, I have eight
explanatory variable, with two model-specific variables and six control variables: continuous
variable in age (measured in years), continuous variable in education (measured in years),
continuous variable in wealth (measured in $100,000), binary variable for self-assessment on
how closely one follows the stock market and how well one understands the stock market
(proxies for financial literacy), as well as a binary variable for works for pay. The two model-
specific variables are Internet-related and account for the usage of the Internet specifically for
financial research as well as the use of an online brokerage for executing trades online. Both
indicate frequent use of the Internet for financial matters.
V. Results
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From my baseline probit model on the stockholding decision, age and education are both
shown to be significant explanatory variables. The negative coefficient on the age variable
reflects the lower propensity for households to participate in the stock market as the household
grows older; the coefficient is statistically significant and this can be attributed to the fact that the
age variable captures the time horizon-effects; in Haliassos and Bertaut (1995), their age
variables are rendered insignificant due to the inclusion of a liquidity preference variable which
has already captures the horizon effects. With no liquidity variable, age is significant at the 10%
level and reduces the probability that a household owns stock, suggesting that households tend to
dis-save later in the life-cycle in order to maintain consumption levels. In addition, it would seem
that the lack of a bequest motive variable in this model also adds to the significance of the age
variable since bequests would in essence increase the time-horizon for households, encouraging
households to maintain their capital asset consumption level. The coefficient on the education
variable is positive and significant, showing that an increased access to information and more
efficient information processing increases the probability that a household owns stock. With
lower stock market participation costs, these households find the market more attractive since
they are more likely able to demystify the stock market.
Financial wealth is found to be positive and significant at the 1% level. As the availability
of excess funds increases, capital asset consumption increases (i.e. stockholding) since
households are not financially constrained in the short-term; thus they are more forward thinking
and more inclined to invest these excess assets so that they may smooth their consumption. The
income variable is negative, but insignificant. As measured, the income variable indicates solely
whether or not the household receives labor income. Given the roughness of the measurement,
the insignificance may be attributed to the variability within the income variable itself. The lack
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of a true income variable is a large drawback of model, but in a way it agrees with the literature’s
confounded thoughts on the variable as well as its statistical insignificance.
The self-assessment variables of how closely one follows the stock market and how well
one understands the stock market are both positively correlated, though the former is significant
and the latter is not. Increased familiarization with the stock market reduces information costs
through the same channel as education. In respect to the latter variable, there is potential for
response bias to be present, since the question considers an individual’s ability. This may have
led to an inflated perception of the respondent’s own ability.
As anticipated, both the Internet variables I used were both significant and positive.
Given the widespread access of the Internet, the ability to focus singularly on how people utilize
the Internet, in respect to their finances, becomes the more interesting question. Already, the
Internet has reduced entry costs (lower fees and commissions with the rise of online brokerages)
and information costs (increased media coverage of the financial markets).
With the positive correlation between the use of the Internet for financial research and
stockholding, we see that households who make use of the Internet specifically for financial
research are more inclined to hold stocks. This is important to note because it means that the
Internet itself is not a major factor in the stock market participation decision, but rather the
manner in which a household employs the Internet as a tool. For the online brokerage variable,
the model provides a positive coefficient that is significant at the 5% level and allows us to
explore the Internet’s role in increasing access to the stock market, both through the simplicity of
the interface as well as the availability of various brokerages that target certain households. With
both the reduction in information costs and transaction costs, we can see that the Internet
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variables that I have used in the model are valuable additions to the literature since they are not
proxies but rather direct measurements of the information/transaction channel itself.
In Table 6, I have detailed the marginal effects of model 1 which allows us to translate
roughly the effect of the independent variables in percentage terms from the probit model. The
results yield that the use of Internet for financial research increases the probability that a
household owns stock by about 21.8% while the use of an online brokerage improves it by
38.7%
In addition, I would like to highlight my empirical results by building a model for
comparison, which I will create from my sample. This model looks at the effect of regular
Internet usage on stock market participation.
(0)𝑆𝑇𝑂𝐶𝐾𝑆𝑂𝑉𝐸𝑅𝐴𝐿𝐿= 𝛽0 + 𝛽1𝐴𝐺𝐸 + 𝛽2𝐸𝐷𝑈 + 𝛽3𝑊𝐸𝐴𝐿𝑇𝐻 + 𝛽4𝐸𝑀𝐴𝐼𝐿 + 𝛽5𝐹𝑂𝐿𝐿𝑂𝑊𝑆𝑇𝑂𝐶𝐾+ 𝛽6𝑈𝑁𝐷𝐸𝑅𝑆𝑇𝐴𝑁𝐷𝑆𝑇𝑂𝐶𝐾 + 𝛽7𝑊𝑂𝑅𝐾𝑆_𝑃𝐴𝐼𝐷 + 𝜀𝑖
The model employs the same dependent variable as used in the baseline specification, but
deviates from the primary specification in its explanatory variables. Excluding the finance-
oriented Internet usage variables (use of internet for financial research and use of an online
brokerage) and replacing them with a proxy for internet usage (defined as usage of e-mail), I
recreate a model that ignores the accessibility factor of reduced participation costs. This serves as
a point of comparison for the results of my baseline specification. The results of this model are
motivating because the Internet variable (usage of e-mail) is found to be insignificant in
explaining stock market participation, lending credibility to the new question that I have posed:
is Internet access or how a household utilizes the Internet more important when considering their
stock market participation decision.
VI. Robustness Specifications
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In the next specifications, I will deconstruct my dependent variable so that we may see
the effect of the Internet on the various types of stockholding, thus changing my fairly liberal and
generous original definition to one that is more specific; we will look at stocks in trust funds,
IRA/KEOGH accounts, 401k plans, mutual funds, and individual public corporations.
(2 − 7)𝑆𝑇𝑂𝐶𝐾𝑆𝑆𝑃𝐸𝐶𝐼𝐹𝐼𝐶𝑇𝑌𝑃𝐸= 𝛽0 + 𝛽1𝐴𝐺𝐸 + 𝛽2𝐸𝐷𝑈 + 𝛽3𝑊𝐸𝐴𝐿𝑇𝐻 + 𝛽4𝐹𝐼𝑁𝑅𝐸𝑆𝐸𝐴𝑅𝐶𝐻+ 𝛽5𝑂𝑁𝐿𝐼𝑁𝐸𝐵𝑅𝑂𝐾𝐸𝑅𝐴𝐺𝐸 + 𝛽6𝐹𝑂𝐿𝐿𝑂𝑊𝑆𝑇𝑂𝐶𝐾 + 𝛽7𝑈𝑁𝐷𝐸𝑅𝑆𝑇𝐴𝑁𝐷𝑆𝑇𝑂𝐶𝐾+ 𝛽8𝑊𝑂𝑅𝐾𝑆_𝑃𝐴𝐼𝐷 + 𝜀𝑖
Looking at the individual investment accounts and thus redefining our dependent variable
to be whether or not a household holds stocks in a specific account type, we achieve a more
narrow approach. Similar results are produced from these robustness regressions; however there
are few notable deviations from the baseline specification. Education maintains its positive and
significant relationship with stockholding in all account types, except in trust funds, which may
make sense since beneficiaries do not have administrative access to the portfolio. When we look
at the age variable, we see that there is some contradictory evidence to what has been shown in
the baseline specification in terms of significance and sign of the coefficient. All account types
besides the 401K plan show a positive and significant correlation between age and stockholding.
It is interesting to note though that the age variable in the 401K plan specification is negative and
is the only specification to reflect the same result as the baseline specification.
In all specifications, financial wealth is positive and significant, confirming the findings
in the baseline specification. The income variable is statistically insignificant in all specifications,
however is negative in specifications 2 to 4 and positive in specifications 5-7.
The coefficient on the variable, how closely one follows the stock market, is generally
significant and positive, however we see a deviation (in that it is negative and insignificant) in
the trust fund specification, which once again potentially explained by the lack of administrative
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access to beneficiaries of trust funds. In respect to the variable, how well one understands the
stock market, we find that it is insignificant throughout the robustness specifications though there
is variability in the coefficient where half of the robustness specifications result in a positive
coefficient and the other half, a negative coefficient, for this self-assessment variable.
Internet-specific variables, use of Internet for financial research and use of an online
brokerage, are proven to be ambiguous when the definition of stockholding is deconstructed.
When looking at the Internet as a tool for financial research, we find that the variable is positive
and significant in the 401K, Individual Company, and IRA/Keogh specifications and statistically
insignificant in the remaining specifications, trust funds and mutual funds. This may be
explained by the fact that trust funds are controlled and thus advised by the contributor/owner of
the trust fund, and not the beneficiary. For mutual funds, financial research may be seen to be
insignificant since there is a portfolio manager and less research is required when investing in
mutual funds. The online brokerage variable is rendered insignificant in two of the
specifications; 401K and trust fund, but exhibits a positive and significant relationship in the
other specifications. I suggest that the online brokerage variable in the 401K specification is
insignificant since the 401K is an employer-sponsored plan; thus, companies may contribute and
match employee contributions with company stock and options, reducing the use of brokerages
in general. For trust funds, the explanation follows from the previous considerations of trust
fund’s insignificance in the various variables.
VII. Conclusion
From my empirical results, I conclude that finance-oriented Internet usage increases the
propensity of elderly U.S. households to hold stock in their investment portfolio. With additional
robustness specifications and controls, I confirm my hypothesis that access to the reduced
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participation costs is significant and indeed a matter to consider. In addition, I attempt to
introduce the concept of accessibility of reduced participation costs through finance-oriented
Internet usage with the goal of re-approaching reality in economic models.
Since Internet has become widely available, the question that needs to be answered must
be more specific. This has motivated me to focus on the accessibility of reduced participation
costs, and question whether the reduced participation costs are experienced by all households.
From my empirical results, I find that it is important to consider the specific effect rather than the
mass effect. In doing so, my models predict that the households in question tend to have higher
stock market participation rates when they use the Internet for specifically financial reasons.
From the HRS 2009 Internet Survey, use of the Internet for financial research increases the
probability of owning stock by 21.8% while the use of an online brokerage boosts that
probability by 38.7%.
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Time PeriodMean SD Mean SD
1889-1978 0.80 5.67 6.98 16.54
1889-1898 5.80 3.23 7.58 10.021899-1908 2.62 2.59 7.71 17.211909-1918 -1.63 9.02 -0.14 12.811919-1928 4.30 6.61 18.94 16.181929-1938 2.39 6.50 2.56 27.901939-1948 -5.82 4.05 3.07 14.671949-1958 -0.81 1.89 17.49 13.081959-1968 1.07 0.64 5.58 10.591969-1978 -0.72 2.06 0.03 13.11
Observed Historical Return Differential
% real return on a riskless security*
% real return on S&P 500
Source: Mehra and Prescott (1985)
*Securities used for data were 90-day T-bills from 1931-1978, T-Certificates from 1920-1930, and 60-day to 90-day Prime Commercial paper for prior to 1920
Year
% of families with stock holdings
% of families with directly held stocks
% of families with savings bonds
% of families with directly held bonds
% of families with transaction accounts
% of families with certificates of deposit
1989 31.80 16.80 23.90 5.70 85.50 19.901992 36.90 17.00 22.30 4.30 86.90 16.701995 40.50 15.20 22.80 3.10 87.40 14.301998 48.90 19.20 19.30 3.00 90.60 15.302001 53.00 21.30 16.70 3.00 91.40 15.702004 50.30 20.70 17.60 1.80 91.30 12.702007 53.20 17.90 14.90 1.60 92.10 16.102010 49.90 15.10 12.00 1.60 92.50 12.20
Notes:
Financial Market Participation Rates for All U.S. Households
Source: 2010 Survey of Consumer Finances
A Transaction Account is a liquid account that is primarily comprised of checking, savings, and money market deposit accounts, and money market mutual funds; Certificates of Deposits are interest-bearing deposits with a set term; Savings Bonds refer to a bond that is subject to a fixed interest rate for a fixed period of time; Bonds refers to mortgage-backed bonds and corporate or foreign bonds , tax-exempt and other government bills.
*Direct holdings are those held outside of a managed asset such as mutual funds, trusts, managed investment accounts, annuities, and tax-deferred retirement accounts.
Table 1
Table 2
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Observations Mean Std. Dev. Min. Max.
Age (in years) 4381 65.72 8.98 32 96
Wealth (in hundreds of thousands of dollars) 2611 3.67 7.03 0.00001 87
Education (in years) 4370 14.18 2.24 0 17
Use of Internet for Financial Research (1 = yes, 0 = no) 4308 0.57 0.50 0 1
Use of Online Brokerage (1 = yes, 0 = no) 4380 0.08 0.27 0 1
Follows Stock Market Closely (1 = yes, 0 = no) 4358 0.61 0.49 0 1
Understands Stock Market Well (1 = yes, 0 = no) 4345 0.83 0.37 0 1
Works for Pay (1 = yes, 0 = no) 4425 0.46 0.50 0 1
Summary Statistics
Contact letters were sent to 5,742 HRS respondents, inviting them to participate in the 2009 Internet Survey. The 2009 Internet sample was drawn from respondents who reported Internet access in the HRS 2008 Core survey, plus those who did not respond to the 2008 Core survey but had been selected for the 2003, 2006, or 2007 Internet surveys.
As was the case in prior HRS Internet surveys, roughly 20% of the eligible pool was reserved for a control group. A total of 4,433 respondents completed the 2009 Internet Survey, for a simple response rate of 77.2%.
2009 Health and Retirement Internet Survey Description
The 2009 Internet Survey is the fourth in a series of surveys conducted on the Internet. Completed interviews were obtained from 4,433 HRS respondents.
Table 3
Table 4
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Regular(0)
Baseline(1)
401K(2)
Trust Fund(3)
Mutual Funds
(4)
Individual Companies
(5)IRA/Keogh
(6)
Intercept 0.5744 0.5838 1.0689 -0.4348 -0.0216 -0.417 -0.0685(0.0848) (0.0811) (0.1055) (0.0715) (0.1052) (0.103) (0.1109)
Years of Education (in years) 0.012*** 0.0119*** 0.0135*** 0.0028 0.0156*** 0.0111** 0.0217***(0.0038) (0.0038) (0.0049) (0.0033) (0.0049) (0.0047) (0.0051)
Age (in years) -0.0017** -0.0018** -0.0149*** 0.0071*** 0.0025** 0.006*** 0.0005(0.0009) (0.0009) (0.0011) (0.0008) (0.0011) (0.0011) (0.0012)
Financial Wealth (in hundred of thousands of dollars) 0.0062*** 0.00642*** 0.00512*** 0.0176*** 0.01*** 0.01*** 0.01***(0.0011) (0.0012) (0.0016) (0.001) (0.002) (0.002) (0.002)
Use of Internet for Financial Research (1 = yes, 0 = no) 0.0672*** 0.0582** -0.0024 -0.0071 0.0833*** 0.0694***(0.0178) (0.0233) (0.0157) (0.0231) (0.0226) (0.0242)
Use of Online Brokerage (1 = yes, 0 = no) 0.0624** 0.0115 0.0173 0.1188*** 0.2126*** 0.0928***(0.0252) (0.0332) (0.0219) (0.0323) (0.031) (0.0331)
Follows Stock Market Closely (1 = yes, 0 = no) 0.1388*** 0.1092*** 0.0554** -0.0163 0.145*** 0.1018*** 0.1687***(0.0184) (0.0194) (0.0251) (0.0168) (0.0251) (0.0244) (0.0266)
Understands Stock Market Well (1 = yes, 0 = no) 0.0328 0.0228 0.0427 0.0215 -0.0049 0.0269 -0.0225(0.0233) (0.0234) (0.0306) (0.0204) (0.0306) (0.03) (0.0322)
Works for Pay [Proxy: Income] (1 = yes, 0 = no) -0.0095 -0.0076 -0.0165 -0.0121 -0.0204 0.0088 0.0304(0.0153) (0.015) (0.02) (0.0134) (0.0198) (0.0193) (0.0206)
Email [Proxy: Regular Internet Usage] (1 = yes, 0 = no) 0.024(0.0322)
Observations 2521 2484 2240 2119 2341 2196 2140
R2 0.0576 0.0717 0.0914 0.1915 0.0869 0.1282 0.097
F-Statistic 21.02 23.90 28.07 62.47 27.75 40.21 28.61
P-Value of F-Statistic 0.00 0.00 0.00 0.00 0.00 0.00 0.00Standard errors are in parentheses; *** p<0.01, ** p<0.05, * p<0.1. This table reports OLS estimates concerning the stock market participation decision of elderly households with internet access in the United States. Model (0) is a pre-baseline specification that indicates regular usage of the Internet. Model (1) is the baseline specification and is defined in Chapter V, while models (2) through (7) are robustness specifications described in section VI. Models (1) through (7) include goal-oriented Internet usage, which is specified as models that include the variables, Use of Internet for Financial Research and Use of Online Brokerage.
401K refers to an employer-provided retirement account; Trust fund refers to an account funded by somone other than the beneficiary; Mutual funds are a managed asset that contain a basket of investment products; Individual companies refers to an account that holds the shares one owns in individual public corporations (direct holdings); IRA/Keogh is a tax-deferred personal retirement account.
Regression Table
Table 5
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VariableIntercept .232
(0.32)Years of Education 0.038***
(0.015)Age -0.008**
(0.003)Financial Wealth 0.075***
(0.011)Use of Internet for Financial Research 0.218***
(0.067)Use of Online Brokerage 0.387***
(0.129)How Closely One Follows Stock Market 0.331***
(0.071)How Well One Understands Stock Market 0.074
(0.084)Works for Pay (Income) -0.04
(0.061)Observations 2484Pseudo R2 0.0915
LR Chi2 222.07P-Value of LR Chi2 0.00Standard errors are in parentheses; *** p<0.01, ** p<0.05, * p<0.1. This table reports marginal effect estimates of the independent variables in model (1)
Marginal Effects of Baseline-Specification (Model 1)Table 6
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Yes % No % Total %Yes 848 32.53% 1759 67.47% 2607 100%
% 47.03% 72.84% 61.81%
No 955 59.28% 656 40.72% 1611 100%
% 52.97% 27.16% 38.19%
Total 1803 42.70% 2415 57.30% 4218 100%
% 100% 100% 100%
Yes % No % Total %Yes 316 11.92% 2335 88.08% 2651 100%
% 90.03% 59.34% 61.85%
No 35 2.14% 1600 97.86% 1635 100%
% 9.97% 40.66% 38.15%
Total 351 8.19% 3935 91.81% 4286 100%
% 100% 100% 100%
Uses Internet for Financial Research
Uses an Online BrokerageHousehold Owns Stock
Household Owns Stock
Internet Specific Variables and Stockholding
Sample Characteristics
Table 7
Table 8
Household Owns Stock Freq. % Freq. % Freq. % Freq. % Freq. % Freq. % Freq. % Freq. %Yes 2669
61.71%1010
26.87%2661
60.03%1589
39.80%1253
32.09%2323
37.20%387
10.54%887
20.80%No 1656
38.29%2749
73.13%1772
39.97%2403
60.20%2652
67.91%1376
62.80%3285
89.46%3377
79.20%Total 4325
100.00%
3759100.00%
4433100.00%
3992100.00%
3905100.00%
3699100.00%
3672100.00%
4264100.00%
IRA/Keogh
*Direct holdings are those held outside of a managed asset. Managed Asset account types include mutual funds, trusts, managed investment accounts, annuities, and tax-deferred retirement accounts.
Account Definitions: Overall is composed of all accounts (direct and indirect), Individual refers to accounts that hold shares directly in individual corporations and thus is considered a directly held account, indirectly held account is composed of all other accounts, which are Mutual Fund, 401K, IRA/Keogh, Trust, and Other accounts; Other accounts are all stockholding accounts with the exception of personal brokerage accounts, mutual fund accounts, 401K accounts, IRA/Keogh accounts, and Trust accounts.
Stockholding by Account Type
401KOverall Indirectly Held OtherIndividual
(Directly Held) Mutual Fund Trust
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Years of Education
No Yes Total No Yes Total0 1 3 4 0 2 2 41 0 1 1 1 0 1 12 0 0 0 2 0 0 03 2 0 2 3 2 0 24 0 2 2 4 2 0 25 0 0 0 5 0 0 06 3 1 4 6 4 0 47 4 1 5 7 5 0 58 7 6 13 8 11 2 139 25 12 37 9 38 2 40
10 49 19 68 10 66 2 6811 52 23 75 11 72 1 7312 620 553 1173 12 1141 46 118713 183 207 390 13 376 20 39614 246 337 583 14 551 40 59115 84 143 227 15 212 19 23116 264 497 761 16 686 95 78117 290 611 901 17 798 121 919
Total 1830 2416 4246 Total 3966 351 4317
Internet Specific Variables on Education
Years of Education
Uses Internet for Financial Research
Use of Online Brokerage
Household Owns Stock
30 40 50 60 70 80 90 Total %Yes 4
0.15%41
1.56%706
26.78%1053
39.95%628
23.82%194
7.36%10
0.38%2636
100.00%
36.36% 46.59% 64.47% 62.46% 57.99% 65.32% 66.67% 61.66%
No 70.43%
472.87%
38923.73%
63338.62%
45527.76%
1036.28%
50.31%
1639100.00%
63.64% 53.41% 35.53% 37.54% 42.01% 34.68% 33.33% 38.34%
Total 110.26%
882.06%
109525.61%
168639.44%
108325.33%
2976.95%
150.35%
4275100.00%
100% 100% 100% 100% 100% 100% 100% 100%
Age on StockholdingAge
Table 9
Table 10
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Author Haliassos and Bertaut (1995) Bertaut (1998) Choi, Laibson, and
Metrick. (2000)Barber and Odean (2002)
Vissing-Jorgenson (2002)
Hong, Kubik, and Stein (2004)
Lusardi, Rooij, and Alessie (2007) Bogan (2008) Cole and Shastry
(2009)Glaser and Klos (2012)
Sample Period 1983 1983, 1989 1997-1999 Jan 1991 to Dec 1996 1968-1993 1992 2005 1992, 2002 1980, 1990, 2000 2001
Database Survey of Consumer Finances
Survey of Consumer Finances Hewitt Associates, LLC
Unidentified Large Discount Brokerage Firm
Panel Study of Income Dynamics, Consumer Expenditure Survey
Health and Retirement Survey DNB Household Survey Health and Retirement
Survey U.S. Census German SAVE data
Sample Coverage
U.S. Households U.S. Households Employees of two large companies U.S. Online Investors U.S. Households Older U.S. Households Dutch population
[Ages 22-90] Older U.S. Households U.S. Households German Households
Data observations
4103 1368Alpha (10,000+ participants), Omega (50,000 participants)
1607 1081 7,465 1,115 3774 4 to 14 million 1827
Definition of Stock
Stocks in Public Corporation, Mutual Funds, excluding stocks in company in which a household member was employed
Stocks in 401k
Stocks in Public Corporation, Mutual fund, Investment Trust, IRA
Stocks excluding IRA, Keogh account, 401K, Contribution Pension Plans
Financial Market Participation (income from interest, dividends, net rental income, royalty income, or income from estates and trusts)
Stocks in Public Corporation, Real Estate Mutual Funds (and similar assets)
Measurement of Stockholding
dummy (household owns stock)
dummy (household owns stocks) value (Trades)
dummy (household begins online trading in month t)
dummy (household owns stock)
dummy (household owns stock)
dummy (household owns stock)
dummy (household owns stock in 2002)
dummy (household has investment income)
dummy (household owns stocks)
value (Turnover)
Age Age
5 dummy variables, age<35, age=35-44, age=45-54, age=65-74, age>75, omitted variable is age=55-65
Age Age Age Age
5 dummy variables, age=30-40, age=41-50,age=51-60, age>60, omitted variable is age<30
Age19 dummy variables, 3-year age groups from 18-75 year olds
5 dummy variables (2nd, 3rd, 4th, 5th highest age quintile), omitted variable is lowest age quintile
Labor Income Labor Income Labor Income 1999 Salary 8 dummy variables, top range is >$125,000
Conditional Mean of Non-Financial Income Labor Income Household Income Household Income Household Income
4 dummy (2nd, 3rd, 4th, 5th income quintiles), omitted variable is lowest income quintile
Financial Wealth
Financial Net Worth Financial Net Worth Total plan balance at end of 1999
Financial Net Worth, Stock/Net Worth
Financial Wealth of household i in period t, nominal terms and real terms
4 dummy variables (2nd, 3rd, 4th, 5th wealth quintile), omitted variable is lowest wealth quintile
4 dummy variables (2nd, 3rd, 4th wealth quartile) omitted variable is lowest wealth quartile
Household Net Worth
4 dummy variables (2nd, 3rd, 4th, 5th highest wealth quintiles), omitted variable is lowest wealth income quintile
Sociability (Peer Effects)
dummy (sociability index, defined by questions concerning “Know neighbors”, “Visit neighbors”, “Attend Church” )
dummy (Education of peers: intermediate vocational/ second/ pre-university, Education of peers: higher vocational, university)
dummy (sociability)
Education 3 dummy variables, defined as less than high school, high school, some college, omitted variable is college degree
2 dummy variables (less than high school, college, omitted variable is at least high school)
3 dummy variables, 16+ years, 13-15 years, 9-12 years, omitted variable is less than 9 years
Years of education 4 dummy variables (intermediate vocational, secondary pre-university, higher vocational, university, omitted variable is less than intermediate
Years of education Years of education 4 dummy variables (general, intermediate, secondary degree, upper secondary omitted variable is less than general school )
Job Status
3 dummy variables (retired in 1983, retired between 1983-1989, remain retired in 1989)
dummy (retired) dummy (retired)
Internet Variable
Dummy (low tech, i.e. No computer usage)
dummy (1992 computer usage)
dummy (regular internet use in 2008)
Methodology (Regression Form)
Logit Bivariate Probit Binary Logit Logit MLE OLS OLS AND GMM Univariate Probit OLS OLS and GMM
Literature SurveyTable 11
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Appendix:
Correlation Matrix:
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Codebook:
ONLINE_BROKERAGE Level: RESPONDENT Type: Numeric How often do you do each of the following activities on the Internet? Buy or sell stocks, mutual funds, or bonds online ..................................................................... 3692 1. Never 332 2. Rarely 238 3. Sometimes 118 4. Often 53 9. QUESTION SKIPPED Recoded, (1=0, 2=0, 3=1, 4=1, 9=.) =============================== FIN_RESEARCH Level: RESPONDENT Type: Numeric How often do you do each of the following activities on the Internet? Get financial information online, such as stock quotes or mortgage interest rates ........................................................................ 1855 1. Never 898 2. Rarely 869 3. Sometimes 686 4. Often 125 9. QUESTION SKIPPED Recoded, (1=0, 2=0, 3=1, 4=1, 9=.) =============================== EDU Level: RESPONDENT Type: Numeric Years of Education ..................................................................... 4370 0-17. ACTUAL VALUE 63 Blank. Missing ===============================
AGE Level: RESPONDENT Type: Numeric Respondent’s Age ........................................................................ 4381 32-96. ACTUAL VALUE 52 Blank. Missing =============================== FOLLOWSTOCK Level: RESPONDENT Type: Numeric
How closely do you follow the stock market? ........................................................................ 449 1. Very Closely 2224 2. Somewhat 1685 3. Not at all 75 9. QUESTION SKIPPED Recoded, (1=1, 2=1, 3=0, 9=.) =============================== UNDERSTANDSTOCK Level: RESPONDENT Type: Numeric How would you rate your understanding of the stock market? ........................................................................ 77 1. Extremely Good 336 2. Very Good 1447 3. Somewhat Good 1109 4. Somewhat Poor 727 5. Very Poor 649 6. Extremely Poor 88 9. QUESTION SKIPPED Recoded, (1=1, 2=1, 3=1, 4=0, 5=0, 6=0, 9=.) ===============================
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