2.1. Data

Each year, commercially available and new dry bean cultivars are evaluated in different environments for yield potential, adaptation, and disease resistance by the ARC. These performance test data are required for decisions on the release and seed production of new cultivars by seed companies and for cultivar recommendations to farmers. Trials are compiled by ARC and distributed to approximately 30 localities throughout the dry bean production regions of South Africa (Free State, North West, KwaZulu Natal, Mpumalanga, and Limpopo), and they are planted by seed firms, cooperatives, agricultural companies, farmers (strip trials on their actual fields), and research stations during October/November of each trial year.

The seeds are planted by hand or with planters—recommended spacing for the trials was 750 mm between rows and 75 mm within rows, resulting in about 170,000 seeds/ha. Enough seed for four rows of 5 m per plot was supplied for each plot, and the middle two rows were harvested, leaving the last plant at the end of each row to eliminate any border effects. Although cultural practices vary somewhat across participant and production locations, each bean trial is produced under normal farming practices for a given region, and all trials are visited by ARC staff to monitor growth and production practices. Additionally, nitrogen, phosphorus, and potassium fertilizers are applied to the fields at an average annual rate of 42.30 kg/ha, 22.34 kg/ha, and 18.43 kg/ha, respectively. Figure 1 indicates the location of the test plots used in the study.

Figure 1. Agricultural Research Council Dry Bean Trial Locations Used in the Data Set

The ARC bean breeding program concentrates on two main dry bean types: small white canning (SWC) and red speckled (RS). The SWC bean varieties are used for canning purposes and have canning attributes, such as (1) low moisture content of approximately 8% or less, (2) low levels of splitting (not higher than 9%), and (3) a water uptake of an 80% maximum, and have determinate growth (growth habit I: flowers at the ends of branches, which stops stem growth after flowering). In addition, SWC cultivars have upright growth and are usually higher yielding than RS (ARC, 2014b). Unlike the SWC cultivars, RS cultivars have indeterminate growth and have few short and upright branches. In addition, RS cultivars grow after flowering and are almost always inclined to lodging; hence, they have lower yields than do SWC cultivars. The RS cultivars are relatively softer than SWC and cook in a short period of time (ARC, 2014b). As such, households throughout South Africa prefer RS to SWC bean types when making dry bean soups, stews, salads, and so forth. About 61% of the observations in the data set (available in the online supplementary appendix) are of the RS bean type, and the remaining 38.74% are of the SWC bean type. Table A1 reports characteristics of bean varieties included in the data set. The average yield by variety and location are presented in Table A2.

Optimally, weather data (temperature, relative humidity, solar radiation, vapor pressure deficit, etc.) would have been collected and used in the analysis, but these data were not available for this data set.Footnote ¹ Lobell, Cassman, and Field (Reference Lobell, Cassman and Field2009) stated that one must conduct experiments over many years to ensure the mean yield estimate reflects a typical range of weather variation. As a caveat to this claim, localized weather outcomes could be controlled for if the time series dimension of the data is small. Thus, although actual weather observations are preferred, some of the scientific literature (Tack, Barkley, and Nalley, Reference Tack, Barkley and Nalley2015) suggests that year and location fixed effects can simulate a “typical” growing year if the data set is large enough. To demonstrate how the data set used in this study varied over time and location, box plots over trial years are presented in Figure A1 in the online supplementary appendix. The vertical height of each box plot represents the cross-sectional variation across varieties and locations within each trial year, and the sequence of boxes demonstrates variation across years, which could be taken as the common weather shocks across locations.

2.2. Conceptual Framework

The methodology used to calculate the economic benefits of the ARC breeding program followed extensive literature on the economic impacts of agricultural research, as summarized by Huffman and Evenson (Reference Huffman and Evenson2006) and Alston, Norton, and Pardey (Reference Alston, Norton and Pardey1995). Previous evaluations of agricultural breeding programs are exemplified in the literature (Brennan Reference Brennan1989b; Maredia, Bernsten, and Ragasa, Reference Maredia, Bernsten and Ragasa2010; Nalley, Barkley, and Chumley, Reference Nalley, Barkley and Chumley2008a; Nalley et al., Reference Nalley, Barkley, Crespi and Sayre2008b; Traxler et al. Reference Traxler, Falck-Zepeda, Ortiz-Monasterio R. and Sayre1995). Brennan (Reference Brennan1989b) evaluated the impacts of breeding programs at different stages, which further extended the applications of this type of analysis. With this in mind, our first step in evaluating the economic impact of the ARC breeding program was to measure the proportion of yield increases attributable to genetic improvements, holding all other factors, such as agronomic conditions, management practices, and weather, constant.

The use of relative yield performance data from test plots implicitly assumes that actual producer yields are equivalent to test plot yields in the trials. Annual changes in relative yields are measured with performance test data, which represent ideal management and agronomic conditions, instead of actual dry bean yield performance. Although a gap between experimental and actual yields exists, Brennan (Reference Brennan1984) states that the only reliable sources of relative yields are variety trials. Thus, the absolute yield/yield variance could be higher/lower on test plots, and the relative difference should be the same between test plots and producers’ fields. The genetic contribution of the ARC breeding program was measured by quantifying the increase in yields attributable to genetic enhancements for the period from 1982 to 2014. Salmon (Reference Salmon1951) reported that tests over many location-years are necessary to accurately detect differences in variety yields. With this in mind, the yield data were aggregated over all locations and years to develop a yield ratio for each variety.

Following Feyerherm, Paulsen, and Sebaugh (Reference Feyerherm, Paulsen and Sebaugh1984), the relative yield ratios were derived by calculating the mean yield ratio between the first released variety (Bonus, released in 1972) and the subsequent varieties, over all location-years. For ease of interpretation, the yield differences were also calculated by subtracting the mean yield (kg/ha) of each variety from that of Bonus. The yield ratio and yield differential provide comparisons of varietal performance (Table 1). Table 1 shows that since the release of Bonus in 1972, yields have improved for 17 out of 20 of the released varieties. The only exceptions to this are Stomberg, Kranskop, and Teebus RCR2, released in 1990, 1993, and 2005, respectively. Although the Feyerherm, Paulsen, and Sebaugh (Reference Feyerherm, Paulsen and Sebaugh1984) method allows for the estimation of relative yield differences, it does not account for differences in breeding objectives; that is, a variety might be bred for resistance to a fungus such as the common mosaic necrosis virus in beans, or it might be bred for maximum yield and yield stability. Therefore, to incorporate this objective of yield stability, the Just and Pope (Reference Just and Pope1979) method was applied.

Table 1. Relative Yield Advantages of Agricultural Research Council (ARC) Varieties, 1972–2012

^a Mean values of the ratio of the yield of each variety to the yield of the control variety (Bonus) for all locations and years. A larger value indicates a higher yield relative to the control variety.

^b Calculated by subtracting the mean yield of each variety from the mean yield of the control variety (Bonus).

The Just-Pope production function offers flexibility in describing a stochastic technological process that might exhibit changes in the mean and the probability distribution of output. This method provides a straightforward procedure for testing the effects of increased yield on yield stability.Footnote ² Specifically, the Just-Pope production function allows the inputs to affect both the mean and variance of the outputs. The production function is as follows:

(1) $$\begin{equation} {Y_{ilt}} = f\left( {{\bm{X}_{ilt}},\beta } \right) + h\left( {{\bm{X}_{ilt}},\alpha } \right){\varepsilon _{ilt}}, \end{equation}$$

where Y_ilt is yield of the ith varietal test at location l and in time t, X _ilt represents explanatory variables, β and α are parameter vectors, and ε_ilt is the customary error term with a mean of zero. The first term, f( X _ilt , β), on the right-hand side of equation (1) captures other factors affecting the mean output, whereas the second term, h( X _ilt , α)ε _ilt , captures factors affecting the output variance (σ² _ilt ).

An advantage of the Just-Pope production function is its correction of multiplicative heteroskedasticity, which is important for varietal traits because of the variations in both of the species (RS vs. SWC) and in the breeding goals (yield, disease resistance, etc.) across varieties. Notably, because of these stated differences in the breeding program across time, the error terms across varieties may be heteroskedastic in nature. As such, by using the Just-Pope production function, we account for the heterogeneity in breeding goals across varieties. Thus, if output variance (σ² _ilt ) is an exponential function of K explanatory variables, the general model with heteroskedastic errors can be written as follows:

(2) $$\begin{equation} {Y_{ilt}} = X_{ilt}^{\rm{'}}\beta + {e_{ilt}}, \end{equation}$$

(3) $$\begin{equation} E\left( {e_{ilt}^2} \right) = \sigma _{ilt}^2 = exp\big[ {X_{ilt}^{\rm{'}}\alpha } \big],{\rm{\ }} \end{equation}$$

where X ^' _ilt = (x _1ilt , x _2ilt , . . ., x_kilt ) is a row vector of observations on the K independent variables. The vector α = (α_1ilt , α_2ilt , . . ., α _kilt ) is of the dimension (K × 1) and represents the unknown coefficients. E(e_ilt ) = 0 and E(e_ilt · e_jlt ) = 0 for i ≠ j. Equation (3) is rewritten as

(4) $$\begin{equation} \ln \sigma _{ilt}^2 = X_{ilt}^{\rm{'}}\alpha , \end{equation}$$

where σ² _ilt is unknown, but the marginal effects of the explanatory variables on the variance of production, using the ordinary least squares (OLS) residuals from equation (2), can be estimated such that

(5) $$\begin{equation} \ln \hat{e}_{ilt}^2 = X_{ilt}^{\rm{'}}\hat{\alpha } + {\rm{\ }}{\mu _{ilt}}, \end{equation}$$

where ${\hat{e}_{ilt}}$ represents predicted values of e_ilt from the least squares estimation of equation (2). The error term μ _ilt is calculated by solving equations (4) and (5) for μ _ilt . The output variance (σ² _ilt ) is calculated from the estimation of equation (5), which provides estimates of

(6) $$\begin{equation} {\mu _{ilt}} \cdot {\mu _{ilt}} = \ln \left( {\hat{e}_{ilt}^2/\sigma _{ilt}^2} \right). \end{equation}$$

The predicted values from equation (5) are used as weights for estimating generalized least squares coefficients for the mean output in equation (2). That is, the estimates from equation (5) can be viewed as the effects of the independent variables on yield variability (σ² _ilt ). The predicted values from equation (5) are then used as weights when reestimating equation (2). Thus, the results from the reestimation of equation (2) with the weights from the error terms of equation (5) provide the effects of the independent variables on yield.

2.3. Empirical Model Specification

The mean and variance of yield are specified as a function of the release year (RLYR) of each variety, which can be interpreted as the “vintage” of a breeding technology (Arrow, Reference Arrow1962; Nalley et al., Reference Nalley, Barkley, Crespi and Sayre2008b; Traxler et al., Reference Traxler, Falck-Zepeda, Ortiz-Monasterio R. and Sayre1995). The coefficient on the RLYR captures the progression of the breeding technology across time and is the main parameter for measuring the impact (yield and yield variance) of the breeding program. However, a distinction exists between RLYR, which varies from 1972 to 2012, and the trial date, which varies from 1990 to 2014. Each variety has a single RLYR, the date that the variety was released to the public for planting, and each one embodies the breeding technology for that specific year. In the estimated multiple regression model, the coefficient on RLYR only captures the effect of dry bean seed technology at the specific year of release. A typical life cycle of a variety is one of relatively higher yields than previously released varieties in the early years of adoption, then the eventual replacement with yet higher yielding releases (Nalley et al., Reference Nalley, Barkley, Crespi and Sayre2008b).

RLYR is not a time-trend variable but is modeled similarly to the way in which Arrow's (Reference Arrow1962) growth model showed the embodied technology (Traxler et al., Reference Traxler, Falck-Zepeda, Ortiz-Monasterio R. and Sayre1995). Specifically, Arrow (Reference Arrow1962) assigned “serial numbers” of ordinal magnitude to the embodied technology in capital. In this model, the variable RLYR represents the embodied technology for a given year of release by the breeding program. This method is standard procedure for measuring the impact of technological change on output (Nalley et al., Reference Nalley, Barkley, Crespi and Sayre2008b). In addition to the RLYR, the mean and variance of yield were also modeled as a function of whether variety i was an RS variety (RS).

Ideally, precipitation, solar radiation, and temperature would enter the yield models given that bean yields are a function of climatic data. However, like the majority of large panel data sets from low-/middle-income countries, weather data were not available. Year ( Year ) and location ( Loc ) fixed effects were used to account for weather and cluster the standard errors by Year . Additionally, the year and location fixed effects account for differences in farm structure across time and location, respectively. The location variables entered the models as dummies: Free State, North West, KwaZulu Natal, Mpumalanga, and Limpopo, with Gauteng acting as the control location. Likewise, growing years were also modeled as dummies, with 1981 as the control. Therefore, the estimated models for yield (Y_i ) in kilograms per hectare and the log variance of yield ( $\hat{e}_i^2$ ) are as follows:

(7) $$\begin{equation} {Y_i} = {\beta _1}RLY{R_i} + {\beta _2}RS + {\bm{\beta }_3}\bm{Lo}{\bm{c}_i} + {\bm{\beta }_4}\bm{Yea}{\bm{r}_t} + {e_i} \end{equation}$$

(8) $$\begin{equation} \ln \hat{e}_i^2 = {\delta _1}RLY{R_i} + {\delta _2}Rs + {\bm{\delta }_2}\bm{Lo}{\bm{c}_i} + {\bm{\delta }_3}\bm{Yea}{\bm{r}_t} + {\rm{\ }}{\mu _i}. \end{equation}$$