2. WASDE Reports

The WASDE reports are released on a monthly basis and contain information for many different agricultural commodities. They include information at the U.S. and world levels to provide information on the current supply of commodities and expected acreage and yield data. The WASDE report releases part of its information as projections and part as estimates. We use only projections. The projections can change as more information about economic conditions, availability of inputs, and crop and weather conditions are reported. Each new WASDE contains a new projection that represents the most current information gathered during that report month. The projections generally begin between May and April; the exception is the early WASDE reports from 1973 through 1979. During this time period, there was not a standard in which the projection year began, which allowed it to vary among the early months in the calendar year. All trading is in the March futures contract. A single expiration month is used so that the regression model is always predicting the same price. The only month of the calendar year that would not report returns is April because of the March contract expiration and a new WASDE report for the next contract year not becoming available until May.

The WASDE periodically releases reports that contain corrections for previous WASDE information. These corrections are generally issued soon after an initial report and show a small difference in the previously reported numbers and do not provide a large amount of new information to the market. As such, these reports were not included. Of the 533 WASDE reports released from September 17, 1973, to March 8, 2013, that contained U.S. corn projections, 38 contained corrections to corn ending stocks, and the ending stocks changed on average by 4.24% of the original value. The largest changes from the corrections occurred in WASDE reports that were released in the 1970s.

Insengildina, Irwin, and Good (Reference Isengildina, Irwin and Good2006a) provide evidence that when a large adjustment in a previous prediction is needed, the adjustment is not fully made in the next report, and thus projections are smoothed. Such smoothing could reduce the accuracy of our forecasts if the market responded to the true expected values rather than the smoothed reported values. Prices are not deflated because of the short estimation period and the lack of clear theory about what index to use.

The number of observations between WASDE reports can vary depending on the days that the WASDE reports are released. Because of the varying calendar days each month and the untimely release of various WASDE reports, the number of days between reports varies. Observations more than 31 calendar days are not considered because there are too few of them to be representative. Months are crop reporting months, and years are WASDE projection years (for example, 1975 is the 1974/75 crop year).

3. Forecasting Models

Like past research, the key forecasting tool is a regression of price against ending stocks to use. However, past ending stocks regressions have used annual models. Here, we use monthly data and regress the futures price following the report against the projected ending stocks to use from the WASDE report. The models are reestimated for each report so that projections are out of sample from the estimation. Projections are made using the true ending stocks from the next WASDE report. Either a short or long position is always held. Trading returns are calculated daily and are based on settlement prices. The simulated trading holds a long (short) position when the settlement price is below (above) the price forecast. Two different regression approaches are used. The weighted average model uses a weighted average of the regression coefficients using previous reports on this crop year and the regression coefficients using last year's data. The weights are linearly adjusted based on the number of observations in the current crop year. Once 10 observations are available, only the current crop year is used. The intuition behind the approach is to place more weight on the most current data and to give equal weight to data within a crop year. The rolling regression uses data from a set number of recent months to estimate the regression used to forecast prices. The alternative amounts of data used in the rolling regression are 12, 24, 35, 48, and 60 months.

Similar to previous literature (Anderson and Tweeten, Reference Anderson and Tweeten1975; Do, Reference Do2010; Irwin and Good, Reference Irwin and Good2016; Westcott and Hoffmann, Reference Westcott and Hoffman1999; Westcott and Hull, Reference Westcott and Hull1985), price forecasts are obtained by regressing price against a function of ending stocks. The model is reestimated for each report so that the predictions are based on out-of-sample parameter estimates. To account for structural change, the regression model is estimated only using recent data. The ending stocks regressions are estimated using monthly data:

(1) $$\begin{equation} {F_i} = {\beta _{1m}} + {\beta _{2m}}{x_i} + e_i;{\rm{\ }}i = k, \ldots ,m, \end{equation}$$

where F_i is the futures settlement price from the day that the ith WASDE report was released, and x_i contains observations of the independent variable, which is the ratio of ending stocks (or yield) and use. We also consider yield rather than ending stocks to determine the potential of using only yield forecasts.

The work of Anderson and Tweeten (Reference Anderson and Tweeten1975), Westcott and Hull (Reference Westcott and Hull1985), Westcott and Hoffman (Reference Westcott and Hoffman1999), and Do (Reference Do2010) provided the inspiration for the use of this model. Their models mostly used a stocks-to-use ratio or a ratio of utilization and ending stocks. They use a ratio in an attempt to correct for structural change in the overall size of the market. Adjemian and Smith (Reference Adjemian and Smith2012) focused on parameter estimation rather than forecasting but also used a stocks-to-use ratio. A ratio is not required here because a relatively short time period is used,Footnote ¹ but we go ahead and use a stocks-to-use ratio to be consistent with past literature.

The predicted price equation is

(2) $$\begin{equation} {\rm{\ }}{\widehat {Price}_{m + 1}} = {\bar{\beta }_{1m}} + {\bar{\beta }_{2m}}{x_{m + 1}}, \end{equation}$$

where $\ {\widehat {Price}_{m + 1}}$ is the forecasted price at the next WASDE report release, x _{m + 1} is the ending stocks from the next WASDE report, and m is the current report month. The slope coefficient for the rolling regression model is forced to be nonnegative:

(3) $$\begin{equation} {\bar{\beta }_{2m}} = {\rm{max}}\left( {{{\hat{\beta }}_{2m}},0} \right), \end{equation}$$

where ${\hat{\beta }_{2m}}$ is the estimated slope coefficient. The intercept coefficient ${\bar{\beta }_{1{\rm{m}}}}$ is calibrated to predict the current report month price without error:

(4) $$\begin{equation} {\bar{\beta }_{1m}} = {\rm{\ }}{F_m} - {\bar{\beta }_{2m}}{x_m}. \end{equation}$$

The calibration of the intercept was inspired by a similar approach used by a private market advisory service. The trading rule for day d is

(5) $$\begin{equation} Positio{n_{md}} = I({F_{md}} \le {\rm{\ }}{\widehat {Price}_{m + 1}}), \end{equation}$$

where I() is an indicator function that is 1 when true and −1 when false, and Position_md is the desired futures position with 1 representing a long position and −1 a short position.

For the moving average method, the slope coefficient for the weighted average model is calculated using a weighted average of the previous year's last regression slope and the slope from the current year. The decision to limit the use of the previous year's regression slope coefficient in this manner is because the model uses only the current year of data. The model's accuracy is low early in the year when there is limited information. Slowly throughout the year the slope is weighted more to the current year than the previous year and in the last month does not use any of the previous slope estimation.

The weighted average model does not provide a price forecast unless two observations are observed in the current WASDE projection year, and the rolling regression model loses some observations at the start of the sample period.

To determine the effectiveness of the models in capturing all possible trading returns, a perfect foresight method was used for comparison. The forecast price of the perfect foresight model is the actual closing price on the day of the next WASDE report.

Note that transaction costs are not included in the calculations. Trades were generated on approximately 10% of the possible days (10.02% for corn and 10.40% for soybeans). Commission costs should be small for this type of trader such as $4 per round turn. Trading is based on closing prices. Liquidity costs would be incurred. With electronic markets, the bid-ask spread is usually one tick ($12.50) (Wang, Garcia, and Irwin, Reference Wang, Garcia and Irwin2014). So the total costs would be $16.50 per trade or 0.33¢/bu. Incurring this cost 10% of the time would give costs of 0.033¢/bu. per day. There could also be additional costs from managing a margin account.

4. Evaluation Procedure

The regressions involve corn and soybeans closing prices directly regressed on the ratio of WASDE U.S. ending stocks to use. This section describes the heteroskedasticity adjustment used in calculating the mean of trading returns and our efforts in trying to identify a relationship between trading returns and days until the report.

The trading returns displayed heteroskedasticity because of increased prices and the subsequent increased volatility of futures prices starting around 2008. An estimated generalized least squares (EGLS) approach was used to estimate mean returns. The first-stage regression includes only an intercept. The log of the squared residuals is regressed on dummy variables for year. The inverse of the exponential of the predicted value from this auxiliary regression gives the predicted variance, which is used to estimate the mean via weighted least squares. Mathematically, the model estimated is

(6) $$\begin{equation} {r_{jt}} = {\rm{\ }}\mu + {\varepsilon _{jt}}, \end{equation}$$

where r_jt is returns from month j and year t, μ is the mean, and ε _jt ~ N(0, σ² _t ). The logarithm transformation is used to reduce the influence of outliers.

We also studied how returns changed as the days from the next report changed. We considered both linear parametric regressions and nonparametric regressions of returns on days to maturity. The nonparametric procedure used was locally weighted regression (LOESS), which fits a separate weighted regression for each data point where observations close to that data point receive greater weight (Cleveland and Devlin, Reference Cleveland and Devlin1988). The weaknesses of the LOESS procedure are that like other nonparametric procedures, it requires a large number of observations to be precise, and it can be time consuming to calculate as local fitting occurs at every observation of the independent variable. No statistical significance was obtained. We concluded that the results were too noisy to make any conclusions regarding how returns changed with days until the report, and so none of these results are included here.

Note also that our results provide the returns from trading a single contract. The value of knowing the WASDE report in advance would depend on the number of contracts traded. The optimal number of contracts to trade would depend on market liquidity, supply/demand of futures contracts, and the trader's ability to tolerate risk. Further, an actual forecast would have errors, which would reduce its value. Thus, the results here provide only a partial picture of the value of knowing the WASDE report in advance.