Commodity Market Capital Flow and Asset Return

Predictability∗

Harrison Hong† Motohiro Yogo‡

February 28, 2010

Abstract

We establish several new findings on the relation between capital flow in commod-ity markets and asset returns. Capital flowing into commodity markets, as measuredby high open-interest growth, predicts high commodity returns and low bond returns.Open-interest growth is a more powerful and robust predictor of commodity returnsthan other known predictors such as the short rate, the yield spread, the basis, andhedging pressure. It is positively correlated with commodity returns but has informa-tion for future returns beyond that contained in past commodity prices. Open-interestgrowth also predicts changes in inflation and inflation expectations. These findingssuggest that open-interest growth contains information about future inflation that getspriced into commodity and bond markets with delay. Our findings are consistent withrecent theories of gradual information diffusion and have implications for macroeco-nomic forecasting models.

∗This paper subsumes our earlier work titled “Digging into Commodities”. For comments and discussions,we thank Erkko Etula, Hong Liu, David Robinson, Nikolai Roussanov, Allan Timmermann, and seminarparticipants at Boston College, Centre de Recherche en Economie et Statistique, Dartmouth College, Ford-ham University, PanAgora Asset Management, Stockholm School of Economics, University of California SanDiego, University of Pennsylvania, University of Southern California, Washington University in St. Louis,the 2008 Economic Research Initiatives at Duke Conference on Identification Issues in Economics, and the2010 Annual Meeting of the American Finance Association. We thank Jennifer Kwok, Hui Fang, YupengLiu, James Luo, Thien Nguyen, and Elizabeth So for research assistance. Hong acknowledges a grant fromthe National Science Foundation. Yogo acknowledges a grant from the Rodney L. White Center for FinancialResearch at the University of Pennsylvania.

†Princeton University and NBER (e-mail: hhong@princeton.edu)‡University of Pennsylvania and NBER (e-mail: yogo@wharton.upenn.edu)

1. Introduction

We analyze how capital flow in commodity markets is related to commodity and bond re-

turns. Our analysis is motivated by the recent volatility in commodity prices and the renewed

interest in the behavior of these markets, which have not been seen since the energy crisis of

the 1970s. Once largely ignored by the investment community, commodities have emerged as

an important asset class. By some estimates, index investment in this asset class increased

from $13 billion at the end of 2003 to $317 billion in July 2008, just prior to the financial

crisis (Masters and White, 2008). During the same period, the influx of new investors led to

elevated levels of capital flow as measured by open interest in commodity futures, which grew

from $103 billion to $509 billion. This capital flow has led to inquiries about how trading

affects asset price formation in these markets, underscored by the recent Congressional hear-

ings on the impact of excessive speculation. Hence, understanding the link between capital

flow and commodity price fluctuations is important not only for investors but also for public

policy.

Our analysis covers 30 commodities across four sectors (agriculture, energy, livestock,

and metals) over the period of 1965 through 2008. Using hand-collected data on open inter-

est from the Commitments of Traders since 1965, we establish several new findings on the

relation between capital flow and returns in commodity markets. Figure 1 summarizes our

main finding. The first series is the percentage change in open interest over the previous

12 months, averaged across all commodities. The second series is the return on fully collat-

eralized commodity futures over the previous 12 months, averaged across all commodities.

During the recent commodity boom from 2003 to 2008, capital flowed into the sector at a

persistently high rate, more so than in any other period over the previous thirty years. Only

the energy crisis of the 1970s witnessed higher activity. During these two historic periods

and also more generally, open-interest growth and commodity returns are highly correlated.

But the most interesting finding in this plot is that open-interest growth seems to lead com-

modity returns. In other words, capital flowing into commodity markets appears to predict

2

subsequent appreciation of commodity prices.

To formalize our observation, we regress the monthly excess returns on a portfolio of

commodity futures onto lagged 12-month open-interest growth. We find that a standard

deviation increase in open-interest growth increases expected commodity returns by 0.64%

per month. Similarly, we find that a standard deviation increase in open-interest growth

increases expected spot-price growth by 0.41% per month. Both of these estimates are

economically large and statistically significant. Open-interest growth is a more powerful and

robust predictor than a number of other variables that are known to predict commodity

returns. These include common predictors such as the short rate and the yield spread and

commodity-specific predictors such as aggregate basis (i.e., the ratio of futures to spot price

averaged across commodities) and aggregate hedging pressure (i.e., the net short position

of hedgers averaged across commodities).1 Open-interest growth is a more robust predictor

than these other variables in two important ways. First, aggregate open-interest growth

predicts returns on sector portfolios, in contrast to other variables that predict returns for

only particular sectors. Second, open-interest growth is the only variable that continues

to demonstrate forecasting power in the most recent period since 1987, when there are the

greatest number of commodities in the database.

Open-interest growth is most closely related to 12-month commodity returns. We find

that past aggregate commodity returns forecast the subsequent month’s return. In other

words, there is momentum in the time series of aggregate commodity returns. However, in a

horse race between these variables, open-interest growth entirely drives out the forecasting

power of past commodity returns. This means that open-interest growth contains informa-

tion about future returns that is not fully captured by past commodity prices. A potential

1Bessembinder and Chan (1992) are the first to establish that the same variables that predict bond andstock returns (such as the short rate, the default spread, and the dividend yield) also predict commodityreturns. There is mixed evidence that basis predicts returns on commodity futures. Fama and French (1987)are the first to establish that basis predicts returns for some commodities. They emphasize that there ismore consistent evidence for the theory of storage. A number of other studies have documented mixedevidence for the theory of backwardation, controlling for systematic risk and using an empirical proxy forhedging pressure (Carter, Rausser, and Schmitz, 1983; Chang, 1985; Bessembinder, 1992; de Roon, Nijman,and Veld, 2000).

3

interpretation of these findings is that capital flows into commodity markets in response to

news, which get impounded into commodity prices with delay. In the 1970s, for example,

there were news about supply shocks to oil. In the most recent period, there were news

about strong demand for commodities from the emerging economies.

To test this hypothesis, we examine whether open-interest growth predicts inflation and

excess bond returns. Consistent with the hypothesis, we find that high open-interest growth

predicts rising inflation and also a rising nominal short rate. In addition, high open-interest

growth predicts low bond returns with a t-statistic over 3. A standard deviation increase in

open-interest growth decreases expected bond returns by 0.32% per month. Open-interest

growth is the only predictor that survives in the most recent period since 1987, when the

short rate and the yield spread fail to predict bond returns. Hence, open-interest growth

not only contains powerful information about future commodity returns, but also important

information about future bond returns.

To summarize, our novel finding is that capital flow into the commodity sector contains

information about inflation news and bond returns that is not fully captured by commodity

prices. As we discuss in the body, our findings are most consistent with recent theories

of gradual information diffusion in asset markets (see Hong and Stein, 2007, for a review).

These theories suggest that when market prices under-react to news, trading activity emerges

as a useful additional predictor of future returns. Moreover, the fact that capital flow can be

useful for predicting economic activity like inflation expectations has important implications

for macroeconomic forecasting models.

Our work is part of a second generation of commodity papers that have recently emerged

in response to renewed interest in commodity markets. In a pioneering study that lays

out the agenda, Gorton and Rouwenhorst (2006) emphasize that commodities have a high

Sharpe ratio and a low correlation with other asset classes. They argue that this evidence

is consistent with the theory of backwardation in particular and market segmentation more

generally. Acharya, Lochstoer, and Ramadorai (2009) find that producers’ hedging demand,

4

as captured by their default risk, predicts commodity returns. Etula (2009) finds that the

supply of speculator capital, as captured by changes in broker-dealer balance sheets, predicts

commodity returns, especially in energy. Relative to these studies, we share the view that

market segmentation is a key driver of predictability in commodity markets. However, our

focus on the implications of gradual information diffusion is quite different from these other

studies that focus on limited risk-bearing capacity in commodity markets. More closely

related is a group of studies that document momentum in the cross section of commodity

returns (Erb and Harvey, 2006; Gorton, Hayashi, and Rouwenhorst, 2007; Miffre and Rallis,

2007; Asness, Moskowitz, and Pedersen, 2009). We find momentum in the time series of

aggregate commodity returns, which interacts with capital flow into commodity markets.

The rest of the paper proceeds as follows. Section 2 describes the commodity market data

and the construction of the key variables used in our empirical analysis. Section 3 reports

summary statistics for commodity returns, spot-price growth, and the predictor variables.

Section 4 presents our main finding that open-interest growth predicts commodity returns.

We also present evidence that open-interest growth predicts inflation news and bond returns

to illuminate the economic mechanism behind our findings. Section 5 concludes.

2. Commodity Market Data and Definitions

2.1. Commodity Market Data

Our data on commodity prices are from the Commodity Research Bureau, which has daily

prices for individual futures contracts as well as spot prices for many commodities beginning

in December 1964. Gorton and Rouwenhorst (2006) also use this database, and additional

details can be found in the appendix to their paper. As they point out, the database mostly

contains data for contracts that have survived until the present or that were in existence for

an extended period between 1965 and the present. Many different types of contracts fail to

survive because of lack of interest from market participants, and they are consequently not

5

recorded in the database. Consequently, the computed returns on commodity futures may

be subject to survivorship bias.

Following Gorton and Rouwenhorst (2006), we work with a broad set of commodities

contained in the database. Table 1 is a list all our commodities, together with the date

of the first recorded futures price for each commodity. We categorize commodities into

four broad sectors. Agriculture consists of 15 commodities and tends to contain the oldest

contracts. Energy consists of five commodities. Heating oil is the oldest contract in energy,

which starts in November 1978. Data for crude oil are available only since March 1983.

Livestock consists of five commodities, and metals consists of six commodities. A potential

concern with using a broad set of commodities is that not all contracts are liquid. In results

that are not reported here, we have confirmed our main findings on a subset of 17 relatively

liquid commodities that are in the AIG Commodities Index.

Following Gorton and Rouwenhorst (2006), we exclude futures contracts with one month

or less to maturity. These contracts are typically illiquid because futures traders do not

want to take delivery of the underlying physical commodity. We therefore rule out investment

strategies that require holding futures contracts to maturity. While Gorton and Rouwenhorst

(2006) isolate the contract that is closest to maturity for each commodity, we include all

contracts with more than one month to maturity.

We also use data on open interest (i.e., the number of futures contracts outstanding)

as well as the long and short positions of noncommercial traders (or “hedgers”) for each

commodity. Since January 1986, the data are available electronically from the Commod-

ity Futures Trading Commission. Prior to that date, we hand-collected data from various

volumes of the Commitments of Traders in Commodity Futures. Data for December 1964

through June 1972 are from the Commodity Exchange Authority (1964–1972). Data for

July 1972 through December 1985 are from the Commodity Futures Trading Commission

(1972–1985). There is a 11 month gap from January through November of 1982, during

which the Commodity Futures Trading Commission did not collect data due to budgetary

6

reasons.

Figure 2 shows the share of total dollar open interest that each sector represents. The

figure shows that agriculture dominates the early part of the sample, while energy becomes

the biggest sector later in the sample. The relative size of the four sectors is much more

balanced in the second half of the sample starting in 1987. These stylized facts have two im-

portant implications for our empirical analysis. First, we construct the aggregate commodity

portfolio as an equal-weighted portfolio of the four sectors, which ensures that the portfolio

composition is consistent throughout the sample. Second, we examine the predictability of

commodity returns by sector and in subsamples to check the robustness of our main results.

The subsample since 1987 is perhaps more representative of what we can expect from com-

modity markets going forward because it has a more balanced representation across the four

sectors.

2.2. Aggregate Commodity Returns

To construct aggregate commodity returns, we first compute the return on a fully collater-

alized position in commodity futures as follows. Let Rf,t be the monthly gross return on

the 1-month T-bill in month t, which is assumed to be the interest earned on collateral. Let

Fi,t,T be the price of a futures contract on commodity i at the end of month t, which matures

at the end of month T . The monthly gross return on a fully collateralized long position in

commodity i with maturity T − t is

Ri,t,T =Fi,t,TRf,t

Fi,t−1,T. (1)

We sort the universe of commodity futures into four sectors and two levels of maturity.

We define short maturity contracts as those with more than one but no more than three

months to maturity. Long maturity contracts are those with more than three months to

maturity. We then construct eight equal-weighted portfolios of commodity futures, corre-

7

sponding to two levels of maturity for each of the four sectors. For each portfolio, we compute

its monthly gross return as an equal-weighted average of returns on fully collateralized com-

modity futures. Finally, we construct an aggregate commodity portfolio as an equal-weighted

portfolio of the these eight portfolios. The aggregate commodity portfolio that results from

this construction is consistently balanced with respect to sector and maturity.

For some of our analysis, it is useful to look at commodity returns separately by sector

and maturity. Using the eight portfolios, we construct four sector portfolios as an equal-

weighted portfolio of the short-maturity and long-maturity portfolio for each sector. For

example, the agriculture portfolio is an equal-weighted portfolio of the short-maturity and

the long-maturity portfolio for agriculture. Using the eight portfolios, we also construct two

maturity-sorted portfolios as an equal-weighted portfolio of the four sector portfolios for each

level of maturity. For example, the short-maturity portfolio is an equal-weighted portfolio

of the short-maturity portfolio for agriculture, energy, livestock, and metals.

Our construction of the aggregate commodity portfolio differs from that of Gorton and

Rouwenhorst (2006), who construct their portfolio by equal-weighting all commodities that

exist at each point in time. The advantage of our approach is that the sectors are always

equal-weighted, and hence no sector dominates even as the number of commodities within

each sector changes over time. Despite the differences in the construction, the summary

statistics for our aggregate commodity portfolio (reported in Section 3) are very close to

those reported by Gorton and Rouwenhorst (2006).

2.3. Aggregate Spot-Price Growth

We construct aggregate spot-price growth in analogy to our construction of aggregate com-

modity returns. Let Si,t be the spot price of commodity i at the end of month t. The monthly

spot-price growth for commodity i is

Gi,t =Si,t

Si,t−1. (2)

8

We compute spot-price growth for each sector as an equal-weighted average of all commodi-

ties in that sector. We then compute aggregate spot-price growth as an equal-weighted

average spot-price growth across the four sectors.

The reason we examine spot-price growth separately from futures price movements is

that spot-price growth is economically different from the return on commodity futures for

two important reasons. First, unlike investment in physical commodities, commodity futures

are financial investments like bonds and stocks. Therefore, the results for commodity futures

are more meaningful than those for the spot price from a pure investment or asset allocation

perspective. Second, as we discuss below, different theories have different implications for

mean reversion in futures versus spot prices. Therefore, the way in which a variable predicts

futures versus spot prices can help us discriminate among different theories.

2.4. Predictor Variables

Our key predictor variable is aggregate open-interest growth. To construct this variable,

we first compute the dollar open interest for each commodity as the spot price times the

number of contracts outstanding. We then aggregate dollar open interest within each sector

and compute its monthly growth rate. Finally, we compute aggregate open-interest growth

as an equal-weighted average of open-interest growth across the four sectors.2 Because

monthly open-interest growth is noisy, we smooth it by taking a 12-month geometric average

in the time series. A variable that is closely related to open-interest growth is the 12-

month geometric average of aggregate commodity returns. We use this variable to test for

momentum in aggregate commodity returns.

In addition to open-interest growth, we consider a variety of predictor variables that are

known to predict commodity returns, which can grouped into two categories (see de Roon

2We have tried an alternative construction that uses only the number of contracts outstanding and doesnot involve the spot price. We first compute the growth rate of open interest for each commodity. We thencompute the median of open-interest growth across all commodities within each sector. Finally, we computeaggregate open-interest growth as an equal-weighted average of open-interest growth across the four sectors.This alternative construction leads to a time series that is very similar to our preferred construction ofopen-interest growth.

9

et al., 2009, for a similar list). The first category consists of aggregate market predictors,

which are motivated by theories like the (I)CAPM that view commodity markets as being

fully integrated. According to this view, commodity prices are driven by aggregate market

predictors that influence portfolio allocation decisions across different asset classes. An

implication of this theory is commodities may be useful for hedging time-varying investment

opportunities in other asset classes. Hence, commodity prices may be high, or its expected

returns may be low, when such hedging motives are important. Since an investor can hedge

market fluctuations by either entering futures contracts or by holding physical commodities,

this theory implies that the same aggregate market predictors should predict returns on

commodity futures and spot-price growth with similar sign and magnitude.

We focus on two aggregate market variables that are known to predict the common vari-

ation in bond and stock returns: the short rate and the yield spread (Fama and Schwert,

1977; Campbell, 1987; Fama and French, 1989). These variables are also known to predict

commodity returns (Bessembinder and Chan, 1992; Bjornson and Carter, 1997). The short

rate is the monthly average yield on the 1-month T-bill. The yield spread is the difference

between Moody’s Aaa corporate bond yield and the short rate. In analysis that is not re-

ported here, we have also experimented with other predictor variables. In particular, we have

examined the dividend yield for a value-weighted portfolio of NYSE, AMEX, and Nasdaq

stocks. We have also examined the default spread (i.e., the difference between Moody’s Baa

and Aaa corporate bond yields) and measures of aggregate stock market volatility (i.e., both

realized volatility and the VIX). Although these variables predict returns individually, their

incremental contribution is weak once we control for the short rate and the yield spread.

The second category consists of those variables that are motivated by the view that

commodity markets are segmented to some degree. The basis, or the ratio of futures to

spot price, emerges as a particularly important variable in these theories. In the theory

of backwardation, producers take a (long or short) position in commodity futures to hedge

their position in the underlying spot (Keynes, 1923; Hicks, 1939). Risk averse speculators

10

demand a risk premium for providing insurance. The excess demand for insurance, or hedging

pressure, drives a wedge between the futures price and the expected future spot price. In

the theory of storage, a low inventory causes the spot price to be temporarily high, which

subsequently mean reverts as supply-demand imbalances correct (e.g., Deaton and Laroque,

1992). Note that the theory of backwardation and storage have very different implications

for mean reversion in futures versus spot prices. The theory of backwardation implies that a

low basis predicts high returns on commodity futures, but it remains silent about spot-price

movements. In contrast, the theory of storage implies that a low basis predicts low spot-price

growth, but it remains silent about futures-price movements.

We construct aggregate basis in analogy to our construction of aggregate commodity

returns. We first compute the basis for each commodity i with maturity T − t as

Basisi,t,T =

(Fi,t,T

Si,t

) 1T−t

− 1. (3)

While the Commodity Research Bureau has a reliable record of spot prices, a spot price

is not always available on the same trading day as a recorded futures price. In instances

where the spot price is missing, we first try to use an expiring futures contract to impute

the spot price. If an expiring futures contract is not available, we then use the last available

spot price within 30 days to compute the basis. For example, if we have a futures price on

December 31, but the last available spot price is from December 30, we compute the basis

as the ratio of the futures price on December 31 to the spot price on December 30.

We then compute the median of basis within each of eight portfolios, corresponding to

four sectors and two levels of maturity. We use the median, instead of the mean, because it

is less sensitive to outliers in the basis for individual futures contracts. Finally, we compute

aggregate basis as an equal-weighted average of the basis across the eight portfolios. Recall

that the basis is the implied net convenience yield derived from the cost-of-carry relation.

The net convenience yield is defined as the riskless interest rate, plus additional storage costs,

11

minus the convenience usage earned from owning the spot. Hence, aggregate basis identifies

the common variation in the net convenience yield across all commodities.

In addition to the basis, the theory of backwardation implies that a direct measure of

hedging pressure should be correlated with the basis and also predict returns on commodity

futures. We construct an aggregate version of hedging pressure as defined by de Roon,

Nijman, and Veld (2000). We first construct hedging pressure for each sector as the ratio

of two objects. The numerator is the dollar value of short minus long positions held by

noncommercial traders in the Commitments of Traders, summed across all commodities

in that sector. The denominator is the dollar value of short plus long positions held by

noncommercial traders, summed across all commodities in that sector. Finally, we compute

aggregate hedging pressure as an equal-weighted average of hedging pressure across the four

sectors.

3. Summary Statistics of Commodity Markets

3.1. Commodity Returns

Panel A of Table 2 reports the summary statistics for monthly excess returns over the 1-

month T-bill rate. The aggregate commodity portfolio has a mean of 0.58% and a standard

deviation of 4.05%. This corresponds to an annualized average excess return of 6.96% and

an annualized standard deviation of 14.03%. During the same period, the 10-year Treasury

bond has an annualized average excess return of 2.04% and an annualized standard deviation

of 8.00%. The CRSP value-weighted market portfolio for NYSE, AMEX, and Nasdaq stocks

has an annualized average excess return of 4.32% and an annualized standard deviation of

15.66%. The Sharpe ratio for the aggregate commodity portfolio was higher than that for

stocks in this sample period, which is emphasized by Gorton and Rouwenhorst (2006).

The table also reports the autocorrelation and the cross correlation of excess returns. The

first-order autocorrelation for aggregate commodity returns is 0.08, which is comparable to

12

that for bond and stock returns. Aggregate commodity returns have a correlation of −0.11

with bond returns and a correlation of 0.07 with stock returns. Because commodities have

a high Sharpe ratio and low correlation with bonds and stocks, it is an attractive asset class

from the perspective of diversifying the investment portfolio.

The table also reports the summary statistics for the four sector portfolios. Both the

mean and the standard deviation of excess returns have the same ordering across the four

sectors. Agriculture has the lowest average excess return at 0.27% per month and the lowest

standard deviation at 4.25% per month. Livestock has an average excess return of 0.47% per

month and a standard deviation at 4.87% per month. Metals have an average excess return

of 0.59% per month and a standard deviation of 7.40% per month. Energy has the highest

average excess return at 0.91% per month and the highest standard deviation at 8.08% per

month.

3.2. Predictor Variables

Table 3 reports the summary statistics for the predictor variables. Aggregate basis has

a mean of 0.03% and a standard deviation of 0.84%. Its autocorrelation is 0.69, which

is lower than that for the short rate and the yield spread. This suggests that aggregate

basis is a predictor variable that operates at a higher frequency than the aggregate market

predictors. Aggregate basis has a positive correlation of 0.22 with the short rate and a

negative correlation of −0.11 with the yield spread. Recall that the net convenience yield

is defined as the riskless interest rate, plus additional storage costs, minus the convenience

usage earned from owning the spot. Because aggregate basis is the average net convenience

yield across commodities, the positive correlation between aggregate basis and the short rate

is unsurprising (Fama and French, 1988; Bailey and Chan, 1993).

Figure 3 shows aggregate basis together with the spot-price index for an equal-weighted

portfolio of commodities. The spot-price index is the cumulative growth rate of aggregate

spot-price growth, deflated by the consumer price index. Note that movements in the spot-

13

price index tend to be inversely related to movements in aggregate basis. When the spot-price

index rises, aggregate basis tends to fall. This is due to mean reversion in the spot price.

An increase in the spot price, due to a transitory demand shock for instance, will not lead

to a one-for-one movement in the futures price because the futures market anticipates mean

reversion.

Since 2003, there is a break in this relation between the spot price and the basis, which in-

terestingly coincides with the period of high capital flow into commodity markets. Although

spot prices have appreciated considerably, aggregate basis has risen if anything. This implies

that futures prices have responded at least (if not more than) one-for-one with spot-price

movements. This striking movement in futures prices is unprecedented, even if we consider

the energy crisis of the 1970s. A potential explanation for the recent experience is that

investors believe that there were permanent, or highly persistent, shocks to the demand for

commodities. Another explanation is the conventional wisdom that more capital flowed into

commodity futures than into the spot market in this period, as commodity index investors

chased returns.3 This story provides additional motivation for us to study the relation be-

tween capital flow and returns in commodity markets.

Open-interest growth has a mean of 1.47% and a standard deviation of 2.07%. Its au-

tocorrelation is 0.90, which arises from the fact that open-interest growth is smoothed as a

12-month moving average. Open-interest growth is essentially uncorrelated with aggregate

basis, but it has a positive correlation of 0.31 with hedging pressure. Unsurprisingly, 12-

month open-interest growth has a high contemporaneous correlation of 0.50 with 12-month

commodity returns. This imperfect correlation suggests that capital flow contains informa-

tion that is not entirely reflected in commodity prices. In fact, Figure 1 shows that capital

flow into commodity markets tends to lead a subsequent rise in commodity prices.

3Pindyck and Rotemberg (1990) find excess co-movement among commodity prices and conjecture thatthis is due to speculators moving in and out of commodities as an asset class. In related work, Tan and Xiong(2009) find that commodities have co-moved more with stocks in the recent period, which they attribute tothe indexation of commodity markets.

14

4. What Does Commodity Market Capital Flow Pre-

dict?

4.1. Predictability of Commodity Returns

Table 4 presents our main findings on the predictability of aggregate commodity returns

and spot-price growth. In column (1), we first examine the predictability of commodity

returns by the short rate, the yield spread, and aggregate basis. This specification allows us

to establish a benchmark to see the incremental forecasting power of open-interest growth,

which is our key variable of interest. All coefficients are standardized so that they can be

interpreted as the percent change in monthly expected returns per one standard deviation

change in the predictor variable.

The short rate enters with a coefficient of −0.47 and a t-statistic of −2.40. This means

that a standard deviation increase in the short rate decreases expected returns by 0.47% per

month. Hence, the short rate explains an economically important magnitude of predictability

in commodity returns. The fact that the short rate, or the inflation rate, predicts asset

returns with a negative coefficient is well known (Fama and Schwert, 1977). However, there

is no consensus on its economic interpretation.

In our view, a more interesting and novel finding is the coefficient for the yield spread.

The yield spread predicts commodity returns with a coefficient of −0.45 and a t-statistic of

−2.47. This means that a standard deviation increase in the yield spread decreases expected

returns by 0.45% per month. The fact that the yield spread predicts commodities with a neg-

ative coefficient is in sharp contrast to the positive coefficient for bonds and stocks, reported

in previous studies (Campbell, 1987; Fama and French, 1989). The usual interpretation for

bonds and stocks is that when the yield spread is high, which tends to coincide with reces-

sions, the risk premia for all risky assets are high (due to high risk aversion or high quantity

of risk). In contrast, expected commodity returns are low, or alternatively commodity prices

are high, when the yield spread is high. This finding suggests that commodities are a good

15

hedge for time-varying investment opportunities in bond and stock markets.

Aggregate basis predicts commodity returns with a coefficient of −0.52 and a t-statistic of

−2.58. This means that a standard deviation increase in aggregate basis decreases expected

returns by 0.52% per month. The fact that low basis (i.e., a low futures price relative to

the spot price) predicts high returns on being long commodity futures is consistent with the

theory of backwardation. Overall, the R2 of the forecasting regression is 3.29%. While the

specification in column (1) follows earlier work and is not our main focus, we obtain much

stronger results than previously reported. The primary reasons are that we have access

to a longer sample period and that we use of a broader cross section of commodities in

constructing aggregate basis.

In column (2), we introduce open-interest growth to examine its incremental power for

predicting aggregate commodity returns. The coefficients for the other three predictor vari-

ables are virtually unchanged from column (1) because open-interest growth is essentially

uncorrelated with these other predictor variables. Open-interest growth enters with a co-

efficient of 0.64 and a t-statistic of 2.66. This means that a standard deviation increase in

open-interest growth increases expected returns by 0.59% per month. In this sample, open-

interest growth explains a larger share of the variation in expected returns than the other

predictor variables. Importantly, the introduction of open-interest growth increases the R2

of the forecasting regression from 3.29% to 5.29%.

In columns (3) and (4) of Table 4, we examine whether the same four variables predict

aggregate spot-price growth. In column (3), we predict spot-price growth using only the

short rate, the yield spread, and aggregate basis. The short rate enters with a coefficient

of −0.68 and a t-statistic of −3.49. The yield spread enters with a coefficient of −0.40 and

a t-statistic of −2.22. These results are similar to those for aggregate commodity returns

in column (1). Aggregate basis enters with a coefficient of 0.37 and a t-statistic of 1.79.

Note that the sign of the coefficient is the opposite of that for aggregate commodity returns

in column (1). The fact that high basis predicts high spot-price growth is consistent with

16

the theory of storage. A standard deviation increase in aggregate basis increases expected

spot-price growth by 0.37% per month. The R2 of this forecasting regression is 2.50%, which

is comparable to that for aggregate commodity returns in column (1).

In column (4), we introduce open-interest growth to examine its incremental power for

predicting aggregate spot-price growth. Open-interest growth enters with a coefficient of

0.41 and a t-statistic of 1.91. Importantly, the inclusion of open-interest growth increases

the R2 of the forecasting regression from 2.50 to 3.16%. This is similar to our findings for

aggregate commodity returns.

In Table 5, we examine additional predictor variables that are potentially related to

open-interest growth. For the purposes of comparison, column (1) repeats our main spec-

ification from column (2) of Table 4. In column (2), we predict commodity returns with

past 12-month commodity returns instead of open-interest growth. Past returns enter with

a coefficient of 0.42 and a t-statistic of 1.90. This means that a standard deviation increase

in past returns increases expected returns by 0.42% per month, which is comparable to the

economic magnitude of open-interest growth in column (1). Our finding boils down to a

strong momentum effect in the time series of aggregate commodity returns. Our finding is

different from the well known momentum effect in stock and commodity returns, which is a

cross sectional phenomenon.

In column (3), we run a horse race between open-interest growth and past returns. We

find that open-interest growth crowds out past returns. Open-interest growth enters with

a coefficient of 0.59 and a t-statistic of 1.84, while past returns enter with a statistically

insignificant coefficient of 0.12. On the one hand, this result shows that the forecasting power

of open-interest growth is closely related to the momentum effect in aggregate commodity

returns. On the other hand, capital flow and past returns, while highly correlated, contain

different information about future commodity returns. As revealed by Figure 1, capital flow

tends to lead returns slightly and can therefore be more informative. Our finding is not only

novel for the commodity market literature, but it connects more generally to evidence for

17

slow information diffusion in asset markets as we discuss below.

In column (4), we predict commodity returns with hedging pressure instead of open-

interest growth. Hedging pressure enters with a coefficient of 0.28 and a t-statistic of 1.50.

The sign of the coefficient is consistent with the theory of backwardation, which implies

that high hedging pressure should predict high returns. However, hedging pressure is only

marginally significant. In column (5), we run a horse race between open-interest growth

and hedging pressure. We find that open-interest growth entirely eliminates the forecasting

power of hedging pressure. Open-interest growth enters with a coefficient of 0.61 and a

t-statistic of 2.50, while hedging pressure enters with a coefficient of 0.11 and a t-statistic

of 0.56. Recall that the correlation between open-interest growth and hedging pressure is

0.31. Hence, a plausible interpretation of these results is that hedging pressure is just a noisy

proxy for open-interest growth.

We summarize our main findings in Tables 4 and 5 as follows. The fact that the short

rate and the yield spread predict changes in both futures and spot prices is consistent with

the asset allocation view of commodities, that commodity prices are partly driven by ag-

gregate market predictors. The fact that aggregate basis predicts changes in both futures

and spot prices with opposite signs is consistent with the segmented markets view, that

the theory of backwardation and the theory of storage are partly responsible for commodity

price fluctuations. The results for hedging pressure lends further support to the theory of

backwardation.

More importantly, these tables demonstrate that our findings for open-interest growth are

unrelated to these traditional theories. First, the forecasting power of open-interest growth

is unaffected by these other known predictors based on these theories. Second, the fact that

open-interest growth predicts changes in both futures and spot prices with the same sign

suggests that our findings are unrelated to the theory of backwardation or hedging pressure in

futures markets. A more likely explanation for our findings is that capital flow in commodity

markets contains important information about commodity prices in general (e.g., about the

18

future supply or demand for commodities), instead of being a proxy for risk. As we discuss

in more detail below, the fact that open-interest growth is contemporaneously correlated

with changes in commodity prices and also forecasts future returns suggests the following

interpretation: open-interest growth contains information about fundamentals that is not

entirely impounded in commodity prices.

4.2. Dissecting the Predictability of Commodity Returns

We consider a number of additional analyses to check the robustness of our findings and to

build towards an interpretation. In Table 6, we examine the predictability of commodity

returns by contract maturity and sector. We first examine the predictability of a portfolio

of short-maturity contracts separately from a portfolio of long-maturity contracts. Short

maturity refers to futures contracts with three months or less to maturity, and long maturity

refers to futures contracts with more than three months to maturity. The results for these

two portfolios are very similar to those for the aggregate commodity portfolio in Table 4.

The coefficient for the yield spread is −0.37 for short maturity and −0.45 for long maturity.

The coefficient for aggregate basis is −0.50 for short maturity and −0.47 for long maturity.

Finally, the coefficient for open-interest growth is 0.50 for short maturity and 0.79 for long

maturity, both of which are statistically significant. Overall, these results show that our

main findings are not driven by long-maturity contracts that are potentially less liquid than

short-maturity contracts.

We next examine whether the same aggregate variables that were used in Table 4 predict

returns on the four sector portfolios. For agriculture, the short rate enters with a coefficient

of −0.44 and a t-statistic of −1.75, similar to that obtained for the aggregate commodity

portfolio. The yield spread has a much weaker forecasting power for the agriculture portfolio,

compared to the aggregate commodity portfolio. The yield spread enters with a statistically

insignificant coefficient of −0.25. Aggregate basis has virtually no forecasting power for the

agriculture portfolio. The coefficient is only −0.09 with a t-statistic of −0.43. Relative to

19

these other predictor variables that have weak forecasting power, open-interest growth has

some forecasting power for the agriculture portfolio. Open-interest growth enters with a

coefficient of 0.44 and a t-statistic of 1.44.

We next examine energy, which is a sector of particular interest in light of our introduc-

tion. Note that energy contracts are available only since 1978, so the sample is shorter than

the other three sectors. The short rate enters with a statistically insignificant coefficient of

−0.34. However, the yield spread enters with a coefficient of −1.36 and a t-statistic of −2.52.

This coefficient is over three times the magnitude of that for the aggregate commodity port-

folio. This implies that energy is responsible for much of the forecasting power of the yield

spread for the aggregate commodity portfolio. We also find that aggregate basis is a strong

predictor of returns on the energy portfolio. A high aggregate basis predicts low returns on

being long energy futures with a coefficient of −1.65 and a t-statistic of −2.06. The mag-

nitude of this coefficient is larger than that for any other sector. Importantly, open-interest

growth is a strong predictor with a coefficient of 1.34 and a t-statistic of 2.50. Again, the

magnitude of this coefficient is larger than that for any other sector.

For livestock, neither the short rate or the yield spread are statistically significant. The

short rate enters with a coefficient of −0.17 and a t-statistic of −0.63. The yield spread

enters with a coefficient of 0.14 and a t-statistic of 0.49. However, aggregate basis is a strong

predictor of returns on the livestock portfolio with a coefficient of −0.88 and a t-statistic of

−3.30. Finally, open-interest growth enters with a coefficient of 0.52 and a t-statistic of 1.93.

The short rate has the highest forecasting power for metals. The short rate enters with

a coefficient of −1.04 and a t-statistic of −2.32. The magnitude of this coefficient is more

than two times that for any other sector. The yield spread also works quite well for metals,

although its forecasting power is less than that for energy. The yield spread enters with a

coefficient of −0.71 and a t-statistic of −1.84. Aggregate basis enters with a statistically

insignificant coefficient of −0.14. However, open-interest growth predicts returns on the

metal portfolio with a coefficient of 0.70 and a t-statistic of 1.55.

20

We now summarize our findings for the sector portfolios. Open-interest growth is the

most robust variable in the sense that it consistently predicts returns across all four sectors.

While open-interest growth is only marginally significant in agriculture and livestock, the

magnitude of the coefficients is economically important across all four sectors. In contrast,

the forecasting power of the other three predictor variables is confined to particular sectors.

The short rate works best for metals and to some extent for agriculture. The yield spread

works best for energy and to a lesser extent for metals. Aggregate basis has the highest

forecasting power for energy and livestock and virtually no power for agriculture and metals.

These patterns for aggregate basis can be interpreted in light of the theory of backwardation.

For example, fluctuations in the convenience yield are apparently more important drivers of

expected returns in energy than they are for metals.

In the first two columns of Table 7, we examine the predictability of aggregate commodity

returns by subsample. We split our sample into two halves, 1965–1986 and 1987–2008. The

short rate, the yield spread, and aggregate basis have virtually no forecasting power for

aggregate commodity returns in the second half of the sample. For example, the short rate

enters with a coefficient of −0.90 and a t-statistic of −2.98 in the first half, while it enters

with a coefficient of 0.07 and a t-statistic of 0.17 in the second half. The yield spread is

not statistically significant in either subsample. Its coefficient of −0.35 in the first half is

larger than its coefficient of −0.20 in the second half. Aggregate basis enters with the same

coefficient of −0.40 in both subsamples. However, it is not statistically significant in either

subsample. Overall, our results for the 1965–1986 sample are consistent with the classic

literature on commodities that did not find a strong role for the yield spread or the basis

(Fama and French, 1987; Bessembinder and Chan, 1992).

In contrast to these other predictor variables, open-interest growth has consistent fore-

casting power in both subsamples. Open-interest growth enters with a coefficient of 0.69

and a t-statistic of 1.92 for the first half, while it enters with a coefficient of 0.73 and a

t-statistic of 2.60 for the second half. These results show that our findings for open-interest

21

growth are not driven by a particular period in the sample, nor any peculiarity related to

our hand-collected data prior to 1986.

In the last two columns of Table 7, we examine the predictability of aggregate spot-price

growth by subsample. The forecasting power of the short rate and the yield spread again

comes mostly from the first half of the sample. The short rate enters with a coefficient of

−0.93 and a t-statistic of −3.38 in the first half, while the coefficient is nearly zero in the

second half. The yield spread enters with a coefficient of −0.28 in the first half, which is

larger than the coefficient of −0.16 in the second half. Moreover, the yield spread is not

statistically significant in either subsample. Aggregate basis retains its forecasting power in

the second half of the sample, which can be interpreted as evidence for the theory of storage.

Its coefficient is 0.81 with a t-statistic of 1.78. Open-interest growth predicts spot-price

growth somewhat better in the second half of the sample compared to the first half. Its

coefficient is 0.34 with a t-statistic of 1.24 in the first half, while its coefficient is 0.77 with

a t-statistic of 2.06 in the second half.

Having established that open-interest growth is a robust predictor of commodity returns,

we next examine whether it predicts the volatility of commodity prices. The motivation

for this analysis is that open-interest growth may be proxying for an omitted risk factor

that is not captured by the yield spread, aggregate basis, or hedging pressure. In Table 8,

we regress the monthly volatility of spot-price growth onto lagged predictor variables that

include open-interest growth. As shown in column (1), open-interest growth enters with

a statistically insignificant coefficient of −0.10. In column (2), we include past 12-month

returns as an additional predictor variable. Interestingly, high 12-month returns predicts the

volatility of spot-price growth with a coefficient of 0.64 and a t-statistic of 3.93. This means

that a standard deviation increase in 12-month returns increases the standard deviation of

spot-price growth by 0.64% per month. In contrast, open-interest growth enters with a

coefficient of −0.40 and a t-statistic of −2.47. These results show that open-interest growth

does not seem to be related to the volatility of commodity prices in a way that is consistent

22

with a risk story.

4.3. Predictability of Inflation News and Bond Returns

Having established the robustness of our main results, we now focus on building an economic

interpretation of our findings. A natural interpretation is that capital flow into commodity

markets contain information about fundamentals that is not fully incorporated into com-

modity prices. This view of delayed reaction to fundamental news has some anecdotal

support. For example, the 1970s experienced supply shocks to oil, which eventually led to

high inflation. The most recent period starting around 2003 experienced strong demand for

commodities from emerging economies like China and India, which again led to worries about

inflationary pressures. This episode ended abruptly in 2008 with the onset of the financial

crisis. As highlighted by Figure 1, each of these periods with inflation worries experienced

high capital flow, followed immediately by a run-up of commodity prices.

In Table 9, we examine whether open-interest growth does indeed contain information

about inflation in several ways. In column (1), we test whether open-interest growth predicts

the monthly change in the annual inflation rate. We regress the change in inflation onto

its own lag as well as 1-month lags of the yield spread and open-interest growth. This

specification assumes that inflation is integrated of order one, so that we do not include

the level of inflation or the short rate in the regression (see Stock and Watson, 1999, for a

similar specification). Open-interest growth enters with a coefficient of 0.05 and a t-statistic

of 2.99, consistent with our intuition that it contains fundamental news about inflation. In

column (2), we add past 12-month commodity returns to see which of the two variables has

more forecasting power for inflation. We find that past 12-month returns is a more powerful

predictor of inflation. It enters with a coefficient of 0.07 and a t-statistic of 3.10. The

coefficient for open-interest growth drops from 0.05 to 0.02, and the t-statistic is now 1.16.

Our findings are consistent with the known result in the macroeconomic forecasting literature

that commodity prices are valuable predictors of inflation in the near term. This is not

23

surprising since commodity prices feed almost mechanically into the consumer price index.

Nevertheless, it is interesting to note that open-interest growth retains some forecasting

power for inflation. The results in columns (1) and (2) strengthen our intuition that both

open-interest growth and past commodity returns contain news about inflation.

In column (3), we examine whether open-interest growth predicts inflation expectations

as opposed to realized inflation. In particular, we examine the predictability of changes in

the short rate, which can be roughly interpreted as changes in expected monthly inflation

by the Fisher hypothesis. The yield spread enters with a coefficient of 0.07 and a t-statistic

of 1.58. Open-interest growth enters with a coefficient of 0.12 and a t-statistic of 3.22. This

means that a standard deviation increase in open-interest growth implies an increase in the

annualized short rate by 0.12%. In column (4), we add 12-month commodity returns to find

that it also predicts changes in the short rate. However, it does not drive out open-interest

growth. Our findings here suggest that open-interest growth has incremental forecasting

power for inflation expectations beyond commodity prices. This finding, as we discuss in the

conclusion, has potentially important implications for the large industry of macroeconomic

forecasting.

In column (5), we predict excess returns on the 10-year Treasury bond over the 1-month

T-bill rate. The idea here is that long-term bond prices are sensitive to news about inflation

worries over the longer term. The short rate enters with a statistically insignificant coefficient

of 0.14. The yield spread enters with a coefficient of 0.38 and a t-statistic of 2.63. Open-

interest growth enters with a coefficient of −0.32 and a t-statistic of −3.17. This means that

a standard deviation increase in open-interest growth decreases expected bond returns by

0.32% per month. The forecasting power of open-interest growth rivals that of previously

known predictors such as the short rate and yield spread. In results not reported here, we

have also tested the predictability of bond returns by subsample. We find that in the recent

sample since 1987, only open-interest growth has any forecasting power for bond returns.

Therefore, our findings have potentially important implications for the large literature on

24

the predictability of bond returns. Column (6) shows that past 12-month returns do not

contain any forecasting power beyond open-interest growth. This finding suggests that open-

interest growth may be a more powerful predictor of inflation over long horizons than past

commodity prices. Overall, Table 9 unanimously supports our intuition that the forecasting

power of open-interest growth is coming from information about future inflation above and

beyond that contained in commodity prices.

In light of the ability of open-interest growth to forecast inflation news and expectation,

our findings are most consistent with recent theories examining trading activity and price

momentum, identified in the stock market by Jegadeesh and Titman (1993). This literature

has developed very quickly over the last decade, and there are many studies that have

greatly improved out understanding of the relation between trading and momentum (see

Hong and Stein, 2007, for a survey). Hong and Stein (2007) describe two mechanisms in

the literature in which high trading activity and high past returns can predict high future

returns. One mechanism is gradual information diffusion. To the extent information diffuses

only gradually because of segmentation and limits to arbitrage, an increase in open interest

reflects good news about commodities (perhaps due to inflation worries), which only gets

gradually incorporated. There is substantial support for this view from many studies of price

momentum in the stock market. Another mechanism is serial correlation in trading activity,

perhaps because of passive feedback traders. Price increases lead to positive feedback trading,

which lead to even higher prices. Alternatively, there is time variation in the arrival of news.

Periods of higher intensity trigger disagreement and trading, which lead to higher prices in

the presence of short-sales constraints. There is empirical support for both mechanisms in

stock market studies.

In the context of commodity markets, both mechanisms are believable to the extent that

these markets have traditionally been somewhat segmented from other asset markets. The

commodity price run-ups triggered perhaps initially by fundamental demand from the emerg-

ing economies could also led to over-trading and excessive valuations. However, the finding

25

that open-interest growth also predicts bond returns suggests that gradual information diffu-

sion is the more likely mechanism. Indeed, there is evidence for gradual information diffusion

in the cross section of stock returns (Menzly and Ozbas, 2006; Hong, Torous, and Valkanov,

2007; Cohen and Frazzini, 2008). These studies find that when a particular firm or industry

has positive stock returns over some period, customers and suppliers of that firm or industry

tend to experience positive stock returns over a subsequent period. Gervais, Kaniel, and

Mingelgrin (2001) identify an intriguing effect in the cross section of stock returns, where

abnormal volume predicts high returns over the subsequent week. No such pattern exists

for the aggregate stock market. They attribute their finding to serial correlation in trading

activity. In comparison to these studies for the stock market, our finding that capital flow

predicts commodity returns is striking because it operates at a much lower frequency.

This related literature establishes that trading activity will serve as an important predic-

tor of returns in addition to past price movements. Our findings are somewhat more stark

in that capital flow drives out past price movements as a predictor of future returns. How-

ever, we do not want to over-emphasize this result since it may be an in-sample outcome.

Moreover, at least for forecasting realized monthly inflation, past commodity prices appear

to perform better than capital flow. One can think of reasons unique to commodity markets

why capital flow predicts returns better than past prices. For example, prices may not move

much initially because of excess production capacity, in which case capital flow may be more

informative. More work remains to fully flesh out whether and why capital flow is more

informative than prices in commodity markets.

5. Conclusion

Using hand-collected data from Commitments of Traders reports since 1965, we establish a

relation between capital flow and returns in commodity markets. Specifically, we find that

high capital flow into commodity markets, as measured by aggregate open interest in futures

26

markets, predicts high commodity returns and low bond returns. As part of our analysis, we

update and extend the literature on the predictability of commodity returns. Our finding

is robust to controlling for aggregate market predictors such as the short rate and the yield

spread. It is also robust to controlling for commodity market predictors such as the basis, past

commodity returns, and hedging pressure. Our findings seem most consistent with theories

of gradual information diffusion, which suggest that when market prices under-react to news,

trading activity emerges as a useful additional predictor of future returns.

A broader implication of our findings is that capital flow in commodity markets may

be useful for predicting macroeconomic quantities, such as inflation and the term structure

of interest rates. The macroeconomic literature on inflation forecasting has already known

for some time that commodity and bond prices are important inputs in forecasting models.

These models generally assume that commodity and bond prices contain timely information

about inflation expectations. However, we find that commodity and bond prices seem to

initially under-react to inflation news and that capital flow into commodity markets contain

additional forecasting power. Our work points to a new direction for forecasting models of

inflation and the term structure, where capital flow may be fruitfully incorporated to improve

forecasting power.

27

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31

Table 1: List of Commodities in the PortfolioOur portfolio includes 30 commodities for which futures and spot prices are available throughthe Commodity Research Bureau. The futures contracts are traded on the Chicago Boardof Trade (CBOT), the Chicago Mercantile Exchange (CME), the Intercontinental Exchange(ICE), and the New York Mercantile Exchange (NYMEX). The sample period starts inDecember 1964, after which prices are available for many commodities.

Sector Commodity Exchange First ObservationFutures Price Commitments of Traders

Agriculture Butter CME September 1996 May 1997Cocoa ICE December 1964 July 1978Coffee ICE August 1972 July 1978Corn CBOT December 1964 December 1964Cotton ICE December 1964 December 1964Lumber CME March 1970 July 1978Oats CBOT December 1964 December 1964Orange Juice ICE May 1967 January 1969Rough Rice CBOT August 1986 October 1986Soybean Meal CBOT December 1964 December 1964Soybean Oil CBOT December 1964 December 1964Soybeans CBOT December 1964 December 1964Sugar ICE December 1964 July 1978Wheat CBOT December 1964 December 1964

Energy Crude Oil NYMEX March 1983 April 1983Gasoline NYMEX December 1984 December 1984Heating Oil NYMEX November 1978 October 1980Natural Gas NYMEX April 1990 April 1990Propane NYMEX August 1987 August 1987

Livestock Broilers CME February 1991 March 1991Feeder Cattle CME March 1972 December 1975Lean Hogs CME February 1966 July 1968Live Cattle CME December 1964 July 1968Pork Bellies CME December 1964 July 1968

Metals Aluminum NYMEX December 1983 January 1984Copper NYMEX December 1964 December 1982Gold NYMEX December 1974 December 1982Palladium NYMEX January 1977 July 1978Platinum NYMEX March 1968 July 1978Silver NYMEX December 1964 December 1982

32

Tab

le2:

SummaryStatisticsforCom

modityReturnsan

dSpot-Price

Growth

Pan

elA

reports

themeanan

dthestan

darddeviation

ofmon

thly

excess

returnsover

the1-mon

thT-billrate.It

also

reports

the

autocorrelationan

dthepairw

isecorrelationof

excess

returns.

Theaggregateportfolio

offullycollateralized

commodityfutures

isequal-w

eigh

tedacross

agriculture,energy,livestock,an

dmetals.

Theother

assets

arethe10-yearTreasury

bon

dan

dthe

CRSPvalue-weigh

tedstock

portfolio.Pan

elB

reports

thesamestatistics

formon

thly

spot-price

grow

th.Thesample

periodis

1965:1–2008:12

(1978:12–2008:12

forenergy

only).

Variable

Mean

Standard

Auto-

Correlation

with

(%)

Deviation

correlation

Com

modity

Agriculture

Energy

Livestock

Metals

10-Year

(%)

Portfolio

Bon

dPanel

A:Commodity,

Bond,andStock

Returns

Com

modityportfolio

0.58

4.05

0.08

Agriculture

0.27

4.25

0.02

0.64

Energy

0.91

8.08

0.14

0.69

0.06

Livestock

0.47

4.87

0.03

0.56

0.35

0.03

Metals

0.59

7.40

0.06

0.75

0.36

0.15

0.17

10-yearbon

d0.17

2.31

0.08

-0.11

-0.10

-0.04

-0.07

-0.09

Stock

portfolio

0.36

4.52

0.09

0.07

0.04

0.01

0.04

0.12

0.18

Pan

elB:Spot-Price

Growth

Com

modityportfolio

0.32

4.00

0.06

Agriculture

0.16

4.66

0.00

0.50

Energy

0.72

11.33

0.04

0.76

-0.03

Livestock

0.27

6.84

-0.05

0.58

0.18

0.03

Metals

0.19

5.04

0.09

0.51

0.23

0.14

0.06

33

Tab

le3:

SummaryStatisticsforthePredictorVariables

Thetablereports

themean,thestan

darddeviation

,theau

tocorrelation,an

dthepairw

isecorrelationof

thepredictorvariab

les.

Theshortrate

isthemon

thly

averageyield

onthe1-mon

thT-bill.

Theyield

spread

isthedifference

betweenMoody’s

Aaa

corporatebon

dyield

andtheshortrate.Aggregate

basis

isequal-weigh

tedacross

agriculture,energy,livestock,an

dmetals.

Thenextpredictorvariab

lesarethe12-m

onth

geom

etricaverageof

open-interest

grow

than

dthe12-m

onth

geom

etricaverage

ofcommodityreturns.

Hedgingpressure

istheratioof

shortminuslongpositionsrelative

toshortpluslongpositionsheldby

non

commercial

trad

ersin

theCommitmen

tsofTraders.

Thesample

periodis1965:1–2008:12.

Variable

Mean

Standard

Auto-

Correlation

with

(%)

Deviation

correlation

Short

Yield

Aggregate

Open-Interest

12-M

onth

(%)

Rate

Spread

Basis

Growth

Returns

Shortrate

5.49

2.69

0.97

Yield

spread

2.60

1.61

0.93

-0.52

Aggregate

basis

0.03

0.84

0.69

0.22

-0.11

Open-interest

grow

th1.47

2.07

0.90

0.02

-0.10

-0.06

12-m

onth

returns

1.03

1.24

0.94

0.07

-0.37

0.06

0.50

Hedgingpressure

17.68

14.02

0.90

0.27

-0.29

0.16

0.31

0.44

34

Table 4: Predictability of Commodity ReturnsWe test the predictability of returns on an aggregate portfolio of fully collateralized com-modity futures and aggregate spot-price growth. We regress monthly excess returns, overthe 1-month T-bill rate, onto 1-month lags of the short rate, the yield spread, aggregate ba-sis, and 12-month open-interest growth. The table reports point estimates for standardizedregressors with heteroskedasticity-consistent t-statistics in parentheses. The sample periodis 1965:1–2008:12.

Predictor Variable Commodity Return Spot-Price Growth(1) (2) (3) (4)

Short rate -0.47 -0.48 -0.68 -0.70(-2.40) (-2.04) (-3.49) (-3.04)

Yield spread -0.45 -0.41 -0.40 -0.38(-2.47) (-1.95) (-2.22) (-1.85)

Aggregate basis -0.52 -0.48 0.37 0.37(-2.58) (-2.17) (1.79) (1.61)

Open-interest growth 0.64 0.41(2.66) (1.92)

R2 (%) 3.29 5.29 2.50 3.16

35

Table 5: Alternative Predictors of Commodity ReturnsWe test the predictability of returns on an aggregate portfolio of fully collateralized commod-ity futures. We regress monthly excess returns, over the 1-month T-bill rate, onto 1-monthlags of the short rate, the yield spread, aggregate basis, 12-month open-interest growth,12-month commodity returns, and hedging pressure. The table reports point estimates forstandardized regressors with heteroskedasticity-consistent t-statistics in parentheses. Thesample period is 1965:1–2008:12.

Predictor Variable (1) (2) (3) (4) (5)Short rate -0.48 -0.39 -0.46 -0.53 -0.50

(-2.04) (-1.96) (-1.99) (-2.49) (-2.16)Yield spread -0.41 -0.26 -0.36 -0.42 -0.39

(-1.95) (-1.45) (-1.89) (-2.13) (-1.85)Aggregate basis -0.48 -0.53 -0.49 -0.55 -0.49

(-2.17) (-2.37) (-2.27) (-2.61) (-2.19)Open-interest growth 0.64 0.59 0.61

(2.66) (1.84) (2.50)12-month returns 0.42 0.12

(1.90) (0.38)Hedging pressure 0.28 0.11

(1.50) (0.56)R2 (%) 5.29 3.65 5.34 3.76 5.35

36

Table 6: Predictability of Commodity Returns by Maturity and SectorWe test the predictability of returns on portfolios of fully collateralized commodity futures,separately by maturity (greater than three months for long maturity) and sector. We regressmonthly excess returns, over the 1-month T-bill rate, onto 1-month lags of the short rate,the yield spread, aggregate basis, and 12-month open-interest growth. The table reportspoint estimates for standardized regressors with heteroskedasticity-consistent t-statistics inparentheses. The sample period is 1965:1–2008:12 (1978:12–2008:12 for energy only).

Predictor Variable Short Long Agriculture Energy Livestock MetalsMaturity Maturity

Short rate -0.48 -0.48 -0.44 -0.34 -0.17 -1.04(-2.03) (-1.88) (-1.75) (-0.78) (-0.63) (-2.32)

Yield spread -0.37 -0.45 -0.25 -1.36 0.14 -0.71(-1.74) (-1.96) (-1.07) (-2.52) (0.49) (-1.84)

Aggregate basis -0.50 -0.47 -0.09 -1.65 -0.88 -0.14(-2.41) (-1.77) (-0.43) (-2.06) (-3.30) (-0.33)

Open-interest growth 0.50 0.79 0.34 1.34 0.52 0.70(2.34) (2.49) (1.44) (2.50) (1.93) (1.55)

R2 (%) 4.38 4.99 1.45 5.81 4.96 2.37

37

Table 7: Predictability of Commodity Returns by SubsampleWe test the predictability of returns on an aggregate portfolio of fully collateralized commod-ity futures and aggregate spot-price growth, separately by subsample. We regress monthlyexcess returns, over the 1-month T-bill rate, onto 1-month lags of the short rate, the yieldspread, aggregate basis, and 12-month open-interest growth. The table reports point esti-mates for standardized regressors with heteroskedasticity-consistent t-statistics in parenthe-ses.

Predictor Variable Commodity Return Spot-Price Growth1965–1986 1987–2008 1965–1986 1987–2008

Short rate -0.90 0.07 -0.93 -0.05(-2.98) (0.17) (-3.38) (-0.09)

Yield spread -0.35 -0.20 -0.28 -0.16(-1.01) (-0.75) (-0.95) (-0.43)

Aggregate basis -0.40 -0.40 0.34 0.81(-1.40) (-1.14) (1.26) (1.78)

Open-interest growth 0.69 0.73 0.34 0.77(1.92) (2.60) (1.24) (2.06)

R2 (%) 6.49 5.72 4.51 3.60

38

Table 8: Predictability of Spot-Price VolatilityWe test the predictability of spot-price volatility, computed as the standard deviation ofdaily spot-price growth within each month. We regress spot-price volatility onto 1-monthlags of the short rate, the yield spread, aggregate basis, 12-month open-interest growth, and12-month commodity returns. The table reports point estimates for standardized regressorswith heteroskedasticity-consistent t-statistics in parentheses. The sample period is 1965:1–2008:12.

Predictor Variable (1) (2)Short rate -0.48 -0.38

(-3.31) (-2.63)Yield spread -0.04 0.22

(-0.26) (1.45)Aggregate basis 0.33 0.29

(2.64) (2.36)Open-interest growth -0.10 -0.40

(-0.76) (-2.47)12-month returns 0.64

(3.93)R2 (%) 3.96 8.21

39

Table 9: Predictability of Inflation News and Bond ReturnsWe test the predictability of changes in inflation, computed as the 12-month growth rate ofthe consumer price index, and changes in the short rate. We also test the predictability ofexcess returns on the 10-year Treasury bond over the 1-month T-bill rate. We regress thedependent variable onto 1-month lags of the short rate, the yield spread, 12-month open-interest growth, and 12-month commodity returns. The table reports point estimates forstandardized regressors with heteroskedasticity-consistent t-statistics in parentheses. Thesample period is 1965:1–2008:12.

Predictor Variable Change in Inflation Change in Short Rate Bond Return(1) (2) (3) (4) (5) (6)

Short rate 0.14 0.13(0.79) (0.72)

Yield spread -0.06 -0.04 0.07 0.09 0.38 0.35(-2.84) (-1.73) (1.58) (2.15) (2.63) (2.34)

Open-interest growth 0.05 0.02 0.12 0.08 -0.32 -0.28(2.99) (1.16) (3.22) (1.72) (-3.17) (-2.41)

12-month returns 0.07 0.08 -0.08(3.10) (1.57) (-0.59)

Lagged dependent variable 0.11 0.10 -0.01 -0.01(5.06) (4.19) (-0.06) (-0.06)

R2 (%) 16.05 18.30 4.04 4.96 4.27 4.36

40

−2

02

46

Ret

urn

(%, 1

2−m

o. a

vg.)

−6

−4

−2

02

46

8O

pen−

inte

rest

gro

wth

(%

, 12−

mo.

avg

.)

1964 1969 1974 1979 1984 1989 1994 1999 2004 2009Year

Open−interest growth Return

Figure 1: Aggregate Open-Interest Growth and 12-Month Average ReturnsThe figure shows the 12-month geometric average of aggregate open-interest growth. It alsoshows the 12-month geometric average of returns on an aggregate portfolio of commodi-ties, equal-weighted across agriculture, livestock, energy, and metals. The sample period is1965:1–2008:12.

41

0.2

.4.6

.81

1964 1969 1974 1979 1984 1989 1994 1999 2004 2009Year

AgricultureEnergyLivestockMetals

Figure 2: Open Interest in Commodity Futures by SectorThe figure shows the share of dollar open interest in commodity futures that each sectorrepresents. The sample period is 1965:1–2008:12.

42

0.4

.81.

21.

62

2.4

Spo

t pric

e (lo

g, C

PI d

efla

ted)

−4

−2

02

46

8B

asis

(%

)

1964 1969 1974 1979 1984 1989 1994 1999 2004 2009Year

Basis Spot price

Figure 3: Aggregate Basis and the Spot-Price IndexThe figure shows the basis and the spot-price index for an aggregate portfolio of commodities,equal-weighted across agriculture, livestock, energy, and metals. We define basis for eachfutures contract as (Fi,t,T/Si,t)

1/(T−t) − 1. We then compute the median of basis withineach of four sectors and two maturity levels (greater than three months for long maturity).Aggregate basis is an equal-weighted average of basis across all four sectors and two maturitylevels. The spot-price index is deflated by the consumer price index. The sample period is1965:1–2008:12.

43