2. Agricultural Marketing Service (AMS) Data

The most common unit of observation in hedonic livestock research is auction lots. Typically, researchers enlist the services of staff, research associates, and trained personnel to record results from livestock auctions, which allows collection of a wide range of animal characteristics (e.g., Avent, Ward, and Lalman, Reference Avent, Ward and Lalman2004; Bailey, Peterson, and Brorsen, Reference Bailey, Peterson and Brorsen1991; Schroeder et al., Reference Schroeder, Mintert, Brazle and Grunewald1988). Data for this research are from aggregated U.S. Department of Agriculture (USDA)–AMS bred cow reports, where aggregation occurs across varied categories of lots. Given that the data of this research are aggregate, a brief discussion of data aggregation is warranted.

The literature on aggregated data has two main thrusts. The objective of the first deals with the aggregation problem, whereas the second is concerned with prediction. Considerable effort has been devoted toward the aggregation problem—namely, the problem of aggregation bias defined as the deviation of macroparameters from the average of the corresponding microparameters (Gupta, Reference Gupta1971; Lee, Pesaran, and Pierse, Reference Lee, Pesaran and Pierse1990; Sasaki, Reference Sasaki1978; Thiel, Reference Theil1954). The central focus of the prediction problem is in determining whether to use micro- or macromodels to predict an aggregate dependent variable (Grunfeld and Griliches, Reference Grunfeld and Griliches1960; Pesaran, Pierse, and Kumar, Reference Pesaran, Pierse and Kumar1989). Both problems, prediction and aggregation bias, have been addressed in numerous empirical studies.

Studies in various fields of economic research have documented the implications from using aggregated data sets. Richter and Brorsen (Reference Richter and Brorsen2006) derive a theoretical model that shows that aggregate data create heteroskedasticity but do not create bias if the underlying model is linear. Shumway and Davis (Reference Shumway and Davis2001) show that errors in inference, stemming from aggregation, are small relative to errors attributable to incorrect choice of functional form or failure to account for time series components of the data (Shumway and Davis, Reference Shumway and Davis2001).

Given that the data in this research are aggregated, it is important to note that although bias may be present, the bias is likely minimal because the bred cow categories are relatively narrow and relationships are approximately linear. Another point of discussion is interval-censored data. Although methods exist that could be applied to the data in this research, the methods for interval-censored data would not work well because the intervals of this data are highly irregular.

Although there are many challenges associated with aggregate data sets, the studies reviewed here suggest that a lot can be learned from aggregated data. To date, no studies have made use of aggregate data, where aggregation occurs across lots, to determine the market value of livestock characteristics. This research makes use of an aggregate data set that reports prices from seven livestock auctions.

In Oklahoma, AMSFootnote ¹ summarizes transactions from seven livestock auctions. The Oklahoma City AMS office granted access to their archive system, which provided all of the relevant historical auction reports.Footnote ² The AMS auction reports include the following data: date, price, age, weight, months bred, quality, hide color, location, and sale volume. With the assistance of the Livestock Marketing Information Center (LMIC), an automated program was developed to process the text files, totaling close to 6,000 individual files. Observations with missing values and characteristics are dropped from the data set. In total, 135 observations were dropped because of inconsistencies. The final data set includes 776 weeks composed of 14,811 bred cow lots from January 5, 2000, to May 21, 2015. The price of a bred cow lot ranges from $330/head to $3,400/head. Weight ranges from 700 lb. to 1,700 lb. Complete summary statistics are included in Table 1.

Table 1. Descriptive Statistics of Selected Bred Cow Characteristics for Seven Oklahoma Auctions, January 2000–May 2015

^a Heifers are coded as 1-year-olds for convenience.

^b Replacement cow volume is the total number of bred cows and cow-calf pairs sold.

^c U.S. Department of Agriculture market reports list the total number of cows and bulls sold, as well as the percentage of head that are slaughter cows and bulls. Multiplying the percentage of slaughter animals sold and the total number of head sold gives the total number of slaughter animals. Replacement cow volume is obtained by subtracting the number of slaughter animals sold from the total number of head sold at auction.

^d Cow quality is coded as low = 1, low-average = 2, average = 3, average-high = 4, and high = 5.

Note: Includes 14,811 total observations.

In the AMS reports, prices from a set of lots are aggregated into homogenous groups with similar age, weight, and months bred classifications. Thus, the data reported are aggregate data and do not reflect individual lots sold. Figure 1 presents an example of how reporters aggregate bred cows into categories with similar characteristics. Because of aggregation, the variables price, age, months bred, and weight are reported as ranges. The midpoint of each range is used as the observation for each lot.

Figure 1. Example Bred Cow Auction Report (source: U.S. Department of Agriculture, Agricultural Marketing Service)

Age ranges from 2 to 10 years. AMS reporters also report prices for bred heifers. Heifers are coded as 1-year-olds, for comparison. In this context, age is a reference for the number of calves born. The variable age is expected to have a nonlinear impact on price. As bred cows age, they will receive discounts at an increasing rate because of the reduced useful life of the capital asset. Research on optimal cow size (Bir et al., Reference Bir, DeVuyst, Rolf and Lalman2016; Doye and Lalman, Reference Doye and Lalman2011) suggests that smaller cows are optimal. The argument is that a smaller cow eats less than a large cow and can wean a relatively heavier calf if bred to a larger bull. As months bred increases, the gestating cows are expected to receive a higher price.

Each bred cow lot is assigned a measure of quality reported in five categories: high, high-average, average, average-low, and low. The market reporter determines cow quality by visual inspection. The classifications high-average and average-low are assigned when the quality of the lot is not uniform. Higher-quality cows are expected to receive premiums, whereas lower-quality cows are expected to be discounted. In addition to quality, bred cows are given a black or nonblack hide color classification. Black cows are expected to receive a higher price than nonblack cows.

Supplementary data include daily Chicago Mercantile Exchange feeder cattle and corn futures prices, obtained from the LMIC, to represent price expectations. Feeder cattle futures prices serve as a proxy for expected output prices, and corn futures prices measure expected input costs (Schroeder et al., Reference Schroeder, Mintert, Brazle and Grunewald1988). There is expected to be a negative impact on price, as corn futures prices increase. Likewise, it is expected that there will be a positive effect on price as feeder cattle futures prices increase. These expectations are consistent with those of related studies (Bailey, Peterson, and Brorsen, Reference Bailey, Peterson and Brorsen1991; Buccola, Reference Buccola1980; Schroeder et al., Reference Schroeder, Mintert, Brazle and Grunewald1988; Turner, Dykes, and McKissick, Reference Turner, Dykes and McKissick1991; Zimmerman et al., Reference Zimmerman, Schroeder, Dhuyvetter, Olson, Stokka, Seeger and Grotelueschen2012).

3. Bred Cow Model

In Lancaster's (Reference Lancaster1966) seminal article, “A New Approach to Consumer Theory,” he argues that utility is derived not from the good being consumed, but rather from the characteristics that a good possesses. Later, Ladd and Martin (Reference Ladd and Martin1976) took a product characteristic approach to farm production inputs. Ladd and Martin's (Reference Ladd and Martin1976) input characteristic model (ICM) illustrates how the value of production inputs is equal to the sum of the value of the input characteristics. Ladd and Martin (Reference Ladd and Martin1976) provide a theoretical framework for researchers to model livestock price determinants. A similar approach to Ladd and Martin is used here, specifically those extensions of ICM found in the livestock marketing literature.

Bred cow prices reflect supply and demand conditions in a given market at a point in time. For any given auction, supply is fixed in the short run and prices are determined by the demand for a set of bred cow characteristics. From Ladd and Martin (Reference Ladd and Martin1976), the demand for an input is influenced by the input's characteristics, which allows price to be a function of physical characteristics. Through previous extensions of ICM (Bailey, Brorsen, and Thomsen, Reference Bailey, Brorsen and Thomsen1995; Dhuyvetter et al., Reference Dhuyvetter, Schroeder, Simms, Bolze and Geske1996; Mintert et al., Reference Mintert, Blair, Schroeder and Brazle1990; Parcell, Schroeder, and Hiner, Reference Parcell, Schroeder and Hiner1995; Schroeder et al., Reference Schroeder, Mintert, Brazle and Grunewald1988; Williams et al., Reference Williams, Raper, DeVuyst, Peel and McKinney2012; Zimmerman et al., Reference Zimmerman, Schroeder, Dhuyvetter, Olson, Stokka, Seeger and Grotelueschen2012), the price of a lot of bred cows can be specified as a function of physical characteristics (C) and market forces (M), formulated as follows:

(1) $$\begin{equation} Pric{e_{it}} = \mathop \sum \limits_k {V_{ikt}}{C_{ikt}} + \mathop \sum \limits_h {R_{ht}}{M_{ht}}, \end{equation}$$

where i refers to a lot of bred cows sold in time period t, V is the marginal value of bred cow trait k, and R is the marginal effect of market factor h (Schroeder et al., Reference Schroeder, Mintert, Brazle and Grunewald1988). Factors included as market forces are price expectations, both input costs and output price expectations, sale location, and the week of sale. Equation (1) states that the price per head equals the sum of the marginal implicit values of each lot's characteristics times the yield of each characteristic (Ladd and Martin, Reference Ladd and Martin1976) and the price effect of each market force (Mintert et al., Reference Mintert, Blair, Schroeder and Brazle1990; Schroeder et al., Reference Schroeder, Mintert, Brazle and Grunewald1988).

Equation (1) is estimated to get the marginal value of bred cow characteristics and market factors. Average price per head per lot is the dependent variable in equation (1). A log-log functional form is specified for all price variables. To account for location effects, common in the livestock literature, dummy variables are assigned to the seven reporting auctions. Price seasonality is accounted for by specifying a trigonometric functional form across weeks of the year. Previous research has included random effects for sale location and uses a mixed model approach to estimate the hedonic model (Williams et al., Reference Williams, Raper, DeVuyst, Peel and McKinney2012). Similarly, a random effect for each sale location/week combination is incorporated into equation (1). All other characteristics and market forces are treated as fixed effects. The empirical model estimated is

(2) \fontsize{10}{12} \selectfont{$$\begin{eqnarray} \ln \left( {Pric{e_i}} \right) &=& {\beta _0} + \sum\nolimits_{j = 1}^9 {{\beta _{1j}}Ag{e_{ij}}} + \sum\nolimits_{j = 1}^8 {{\beta _{2j}}MBre{d_{ij}}} + \sum\nolimits_{j = 1}^9 {{\beta _{3j}}W{t_{ij}}} \nonumber\\ &&+ \sum\nolimits_{j = 1}^4 {{\beta _{4j}}Qlt{y_{ij}}} + {\beta _5}Blac{k_i} + \sum\nolimits_{j = 1}^6 {{\beta _{6j}}Lo{c_{ij}}} + {\beta _7}\ln \left( {Cor{n_i}} \right) \nonumber\\ &&+\, {\beta _8}ln(Feede{r_i}) + \sum\nolimits_{(j = 1)}^2\left[ {{\beta _1}_{0j}cos\left( {\frac{{(2\pi t(i))}}{{26j}}} \right) + {\beta _1}_{1j}sin\left( {\frac{{(2\pi t(i))}}{{26j}}} \right)} \right]\nonumber\\ &&+\, {\mu}_{{s_{(i)}}} + {\varepsilon _i}, \end{eqnarray}$$}

where i is the observation number of reported categories of lots (i = 1, 2, . . ., 14,811); t(i) denotes the sale week of observation i; Price_i is the reported average price per head; Age_ij represents dummy variables for age in years (3 years is reference); MBred_ij represents dummy variables for months bred (6 months bred is reference); Wt_ij represents dummy variables for cow weight in hundred pound ranges (901–1,000 lb. is reference weight); Qlty_ij represents dummy variables for cow quality (average quality is reference); Black_i equals 1 if hide color is black and 0 if hide color is nonblack; Loc_ij represents dummy variables for sale location (Oklahoma City is reference); Corn_i is the closing corn futures price per bushel of the nearby contract for the trading day corresponding to the auction date; Feeder_i is the closing feeder cattle futures price per hundredweight (cwt.) of the nearby contract for the trading day corresponding to the auction date; 26j denotes the sinusoidal period; μ_{s ( i )} is the random effect for each sale location and date combination; s(i) is the location/date combination for the ith observation; and ε_i is the random error term for each observation. Further description of variables is provided in Table 2.

Table 2. Description of Variables Used in the Bred Cow Hedonic Model

^a When no trading occurred on the day of the sale, the previous day's closing feeder cattle and corn futures prices of the nearby contracts are used to reflect market conditions.

Previous research has modeled age and weight as linear terms, and often the significance of a quadratic term is tested (Faminow and Gum, Reference Faminow and Gum1986; Dhuyvetter et al., Reference Dhuyvetter, Schroeder, Simms, Bolze and Geske1996; Parcell, Schroeder, and Hiner, Reference Parcell, Schroeder and Hiner1995; Schroeder et al., Reference Schroeder, Mintert, Brazle and Grunewald1988; Williams et al., Reference Williams, Raper, DeVuyst, Peel and McKinney2012). Rather than imposing a restrictive functional form, age and weight categories are included as indicator variables. Age was divided into 10 separate binary variables. Because the midpoint of each age range was used as the observation, there were 20 values that age could take. Age was rounded up to the nearest year. For example, an observation with a midpoint of 1.5 was rounded up to be 2 years. Similarly, 10 weight classes were included and assigned separate binary variables. Months bred ranges from 1 to 9 months bred. The average months bred is used as the observation for each lot; this created observations that were in 2-week increments. Months bred was rounded up to the nearest month, so that 5 months represents midpoints of 4.5 to 5 months. Nine separate binary variables were created for months bred.

The hedonic model is estimated with maximum likelihood using the MIXED procedure of SAS 9.4 (SAS Institute Inc., 2008). To estimate equation (2), an arbitrary reference lot of bred cows is selected. Three years of age is selected as the base age, and 901 to 1,000 lb. is chosen as the base weight class. Six months bred is selected as the base. Average quality is selected as the base quality. Oklahoma City is assigned as the base sale location. All estimated coefficients reflect price effects relative to the base lot.

One estimation concern is heteroskedasticity, particularly because of aggregation (Richter and Brorsen, Reference Richter and Brorsen2006). Results from a likelihood ratio test indicate the presence of heteroskedasticity arising from the variables sale volume, average weight, average age, and average months bred. Heteroskedasticity is corrected for by specifying multiplicative heteroskedasticity (Judge et al., Reference Judge, Griffiths, Hill, Kutkepohl and Lee1985) in the variance equation for the four variables as follows:

(3) $$\begin{eqnarray} E\left[ {e_i^2} \right] = \sigma _i^2 &=& {\rm{exp}}\big[ {\alpha _1} + {\alpha _2}CatVo{l_i} + {\alpha _3}AvgAg{e_i} \nonumber\\ &&+\, {\alpha _4}AvgW{t_i} + {\alpha _5}AvgMBre{d_i} \big], \end{eqnarray}$$

where AvgAge_i , AvgWt_i , and AvgMbred_i are the midpoints of each age, weight, and months bred range. CatVol_i is the number of cows per category. As volume per category increases, a greater number of bred cows are aggregated into categories with similar age, weight, and months bred characteristics. Thus, as aggregation occurs over a greater number of cows, the variance of the error term is smaller.