2.1. Stage one: Data envelopment analysis

The input-oriented minimum cost DEA model is represented by the series of linear programming equations below:

$ MC(y_{i},x^*_{im},w_{i}) = Min\sum _{m=1}^M w_{im}^{'}x_{im}^* $

subject to:

$ \sum _{i=1}^I z_{i}x_{im} \leq x_{qm}^{*} \forall m=1,\ldots, M $

$ \sum _{i=1}^I z_{i}y_{ik} \geq y_{qk} \forall k=1,\ldots, K $

$ \sum _{i=1}^I z_{i} = 1 \ (for \ VRS) $

(1) $ (z_{1},\ldots, z_{I}) \geq 0, $

where MC(y _i ,x _im *,w _i ) is the minimum cost to produce the output, w _im are the input prices for farm i with respect to input m, x _qm * are the cost-minimizing inputs for farm q with respect to input m, x _im are actual inputs used by farm i with respect to input m, z _i measures the weight of each farm when forming the frontier, and y _ik is the output k for farm i. All variables are assumed to be strictly positive and z is greater than or equal to zero. This model assumes variable returns to scale technology, which is imposed by constraining all z _i ’s to sum to one.

Establishing the annual minimum cost frontier provides a standardized efficiency metric for farms. Additionally, inherent in DEA is the ability to calculate various efficiency measures, like overall, pure technical, allocative, and scale efficiency. We use the relative differences in the estimated changes across these efficiency metrics to examine the channels through which PATs impact efficiency.

Overall efficiency is a measure of the optimal cost under constant returns to scale, relative to the actual cost the farm incurred. The formula for overall efficiency is:

(2)

where OE _i is the Overall Efficiency for farm i in a given year, $\sum _{m=1}^M w_{im}^{'}x_{im}^{CRS}$ is the optimal cost under constant returns to scale for farm i, and $\sum _{m=1}^M w_{im}^{'}x_{im}$ is the actual cost incurred by farm i. Overall efficiency ranges from zero to one.

Scale efficiency is a measure of the optimal scale under constant returns to scale, relative to the actual cost the farm incurred. The formula for scale efficiency is:

(3)

where SE _i is the Scale Efficiency for farm i in a given year, $\sum _{m=1}^M w_{im}^{'}x_{im}^{*}$ is the optimal cost under variable returns to scale for farm i, and $\sum _{m=1}^M w_{im}^{'}x_{im}^{CRS}$ is the minimum cost for farm i under constant returns to scale. Scale efficiency scores range from zero to one and are a measure of the optimum scale of the firm. A scale efficiency of 1 indicates the firm is at constant returns to scale, a score less than 1 indicates the farm is not at the optimal scale.

In addition to (1), we estimate pure technical efficiency with the following series of linear programming equations:

$ Min \ \lambda _{i} $

$ subject \ to \!: $

$ \sum _{i=1}^{I} z_{i}x_{im} \leq \lambda _{i}x_{im} \ for \ m=1,\ldots, M $

$ \sum _{i=1}^{I} z_{i}y_{ik} \geq y_{qk} \ for \ k=1,\ldots, K $

$ \sum _{i=1}^{I} z_{k}= 1 \ (for \ VRS) $

(4) $ (z_{1},\ldots, z_{I}) \geq 0, $

where λ _i is the measure of pure technical efficiency for the model. Pure technical efficiency is a measure of how far off the cost frontier a firm is or how efficiently a firm takes inputs and converts them into outputs.

Allocative efficiency is a measure of the optimal input mix for the farm. It measures the distance between the optimal input mix and the input mix the farm actually used. The formula for allocative efficiency is:

(5) $A{E_i} = {{\sum\nolimits_{m = 1}^M {} {w_{im}}x_{im}^*} \over {\sum\nolimits_{m = 1}^M {} {w_{im}}{\lambda _i}{x_{im}}}},$

where AE _i is the allocative efficiency for farm i, $\sum _{m=1}^{M} w_{im}x_{im}^{*}$ is the optimal cost under variable returns to scale for farm i, and $\sum _{m=1}^{M} w_{im}\lambda _{i}x_{im}$ is the actual cost incurred multiplied by pure technical efficiency (λ _i ) for farm i. Allocative efficiency ranges from zero to one.

2.2. Stage two: farm fixed effects regression

We use the four efficiency measures, (overall, pure technical, scale, and allocative efficiency) from the previously mentioned DEA and the within-farm variation in bundles of PAT to identify the effects on efficiency using the following equation:

(6) $ {\rm Efficiency}_{it}=\alpha + \beta {1\,} {\rm Bundle}_{it}' + \delta _{i} + \tau _{t} + \varepsilon _{it}, $

where ${\rm Bundle}_{it}^{\prime} $ is a vector of dummy variables corresponding to PATs bundles for farm i in time t, δ _i is the farm fixed effect, and τ _t is the year fixed effect. We define Efficiency _it with the output from the previous described DEA. Specifically, we are interested in overall efficiency, pure technical efficiency, scale efficiency, and allocative efficiency. Equation (6) is estimated using OLS so that fixed effects may be used to control for time invariant farm characteristics. Robust standard errors are used when estimating this model. This approach does not take into account the possible censorship of the DEA efficiency measures at 0 or 1. However, McDonald (Reference McDonald2009) argues that tobit models are inappropriate to analyze the efficiency scores from DEA models as they are generated from a fractional process, not a censoring process. Additionally, within our data, the censorship issue is minimal in most of the years across the four efficiency measures (see Figure 2).

Our aim is that β captures the within-farm effect of each combination of PATs on farm efficiency. Our DEA efficiency measures are generated separately for each year, controlling for stochastic elements which are common to the year, like weather and prices. Furthermore, τ _t controls for any additional year-specific variation common among farms, yet not captured in the DEA analysis. There is a potential that a farm may experience an idiosyncratic shock that would be reflected in their efficiency, such as region specific weather and prices. However, there is no reason to believe that this idiosyncratic shock follows a pattern over several periods. Thus, although we do not address the potential classic measurement error, we believe that our estimates of β are conservative.

${\rm Bundle}_{it}^{\prime} $ is defined by dummy variables for important PAT and the interactions of these technologies. We include yield monitors, guidance (both lightbar and automated), section control, grid soil sampling, variable rate fertilizer, and variable rate seeding. Each of these technologies are represented with a dummy variable, which takes the value of one if the farm reports using this technology and zero otherwise. The full complement of interaction possibilities with technology is included. For example, we estimate the effect of guidance alone, guidance bundled with each other technology as a pair, guidance bundled with every combination of three technologies, guidance bundled with every combination of four technologies, guidance bundled with every combination of five technologies, and the full bundle of all six technologies. Hence, ${\rm Bundle}_{it}^{\prime} $ is a vector of 56 potential bundles of PATs.

2.3. Data

We use an unbalanced panel of Kansas farms from the KFMA to examine the degree to which the use of PAT influences farm efficiency between 2002 and 2022. The panel consists of 7,245 observations from 570 unique farms. Farms that are part of the KFMA data opt-in by becoming members of the management association. In general these types of farm management datasets represent “larger farms” and a higher percentage of crop vs. livestock operations (H. Kuethe et al., Reference Kuethe, B.Briggeman, Paulson and Katchova2014). The reporting farms average almost 13 years within the panel. This data has been used by several studies that examine the economics of PAT. For example, a subset of current data was used by Miller et al. (Reference Miller, Griffin, Ciampitti and Sharda2019) to estimate the propensity to adopt precision agriculture as bundles. Additionally, Ofori et al. (Reference Ofori, Griffin and Yeager2020) use a subsample of the same data to analyze the time to adoption of Kansas farms. Most pertinent to our study, Dhoubhadel (Reference Dhoubhadel2020) use a subsample of the same data to show that PAT technologies are not associated with long-term impacts on farm profitability.

Farmers participating in KFMA report both production and financial characteristics. We use their financial metrics for our DEA analysis. We define the farms’ output as the gross revenue generated by crop production and livestock production. We define farm inputs as the dollar amounts spent on land, labor, capital, and other variable expenses. All expenses are on an accrual basis. Other variable expenses represent the value of all crop and livestock expenses for the year. Capital is the beginning inventory of all capital assets used on the farm. Labor is the annual dollar amount recorded for labor along with any unpaid operator and/or family labor expense. Unpaid operator and/or family labor is an imputed measure based on the average family living expense over the past three years for the state of Kansas. Land expense is the cash rental expense plus the opportunity cost of the owned land which was calculated using USDA NASS county-level cash rental rates (U.S. Department of Agriculture, National Agriculture Statistics Service, 2024). We retain any farms that reported positive input and output values for analysis.

Table 1 reports the annual means for our two outputs and the four inputs on the represented KFMA farms. The mean livestock receipts show that the average farm in our sample generates less than 20% of their revenue from livestock. Our sample contains many integrated crop and livestock farms, further validating our choice to model two outputs with DEA. The role of variability in weather and prices is exhibited in the mean outputs. There is a steady growth in the value of production, as we would expect, but years like 2009, 2014, 2015, and 2022 show an annual decrease in average crop receipts, and 2006, 2008, 2009, 2012, 2013, 2015, 2016, 2018, 2019, and 2022 show an annual decrease in average livestock receipts. Similar trends exist for the four inputs, land, labor, capital, and other variable expenses.

Table 1. Mean of outputs and inputs for data envelop analysis for farms of KFMA 2002 to 2022 (in US dollars)

Source: KFMA 2002 to 2022.

In addition to financial and production records, KFMA also collects information on the use of PAT. Farms voluntarily report this information starting in 2015. The farmer discloses whether they use a specific PAT, the year of first use, and the year of last use or when whether they discontinue the use. In 2015, farms reported their PAT use going back to 2002. As a result, we construct a backward looking representation of the farms’ use of PAT starting in 2002. We focus our analysis on the use of yield monitor, guidance, section control, grid soil sampling, variable rate fertilizing, and variable rate seeding. Figure 1 plots the growth of reported use of PAT in the KFMA subsample. These trends are similar to the patterns reported by USDA (McFadden et al., Reference McFadden, Rosburg and Njuki2022) and Purdue University and CropLife magazine (Erickson et al., Reference Erickson, Lowenberg-DeBoer and Bradford2017).

Figure 1. Precision agriculture usage on farms in the Kansas farm management data 2002 to 2022.

Table 2 shows the frequency with which each technology bundle occurs in the data. Thirty percent of the farm observations indicate that they did not use any of the technologies during the duration of the study. For clarity, this result could represent a farm that has never used PATs or a farm with PATs in recent years and none in the early years of our analysis. The most common technology reported was the use of guidance, with 16.2% of the farm observations indicating that during a given year, guidance was the only technology they had used. We believe that the prevalence of common bundles of technology is suggestive of the perceived gains of technology (Thompson et al., Reference Thompson, Bir, Widmar and Mintert2019) and a common adoption path (Miller et al., Reference Miller, Griffin, Bergtold, Ciampitti and Sharda2017). We choose to limit our analysis to bundles of PAT that account for at least 0.5% of the observations. As a result, Grid Soil Sampling (GRID) is the bundle with the fewest observations included in our analysis.

Table 2. Precision agriculture technology bundle frequency in KFMA 2002 to 2022. Bundles highlighted in light gray are used in our analysis