2.1. Characterizing Dairy Farm Production Technology

A parametric input distance function approach is used to characterize the production technology of U.S. dairy farms. The input distance function is denoted as D ^I (X,Y,R), with X referring to inputs, Y to outputs, and R to other farm efficiency determinants. Two outputs are included in our model for dairy farms: Y _DAIR = value of dairy production and Y _OTH = value of production of all other crops and livestock on the farm. Inputs include expenses associated with: X _LAB = labor; X _CAP = capital; and X _MISC = miscellaneous including fuel, fertilizer, and feed. In addition, X _LAND = land, where differences in land characteristics are accounted for by starting with state-level quality-adjusted values for the U.S. as estimated in Ball et al. (Reference Ball, Lindamood, Nehring and Mesonada2008), and multiplying these by pasture and non-pasture acres to construct a stock of land by farm. A service flow for land is computed based on a service life of 20 years and interest rate of 6%, as discussed by Nehring et al. (Reference Nehring, Barnard, Banker and Breneman2006). Ignoring land heterogeneity, urbanization effects, and climatic information would result in biased efficiency estimates (Ball et al., Reference Ball, Lindamood, Nehring and Mesonada2008; Nehring et al., Reference Nehring, Barnard, Banker and Breneman2006).Footnote ² All inputs included in the input distance function, including expenses and land, are for the whole-farm.

Estimation of D ^I (X,Y,R) requires the imposition of linear homogeneity in input levels (Färe and Primont, Reference Fare and Primont1995), accomplished through normalization (Lovell et al., Reference Lovell, Richardson, Travers, Wood and Eichhorn1994): D ^I (X,Y, R)/X ₁ = D ^I (X/X ₁ ,Y, R) = D ^I (X*,Y, R). Approximation using a translog functional form results in the following specification:

(1a) $$\matrix{ {{\rm{ln}}\;{{\rm{D}}^{\rm{I}}}_{{\rm{it}}}{\rm{/}}{X_{{\rm{1}},{\rm{it}}}} = \;{\alpha _{\rm{0}}}{\rm{ + }}{\mkern 1mu} {\Sigma _{\rm{m}}}{\mkern 1mu} {\alpha _{\rm{m}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} X_{{\rm{mit}}}^{\rm{*}}{\rm{ + }}.{\rm{5}}{\Sigma _{\rm{m}}}{\mkern 1mu} {\Sigma _{\rm{n}}}{\mkern 1mu} {\alpha _{{\rm{mn}}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} X_{{\rm{mit}}}^{\rm{*}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} X_{{\rm{nit}}}^{\rm{*}}{\rm{ + }}{\mkern 1mu} {\Sigma _{\rm{k}}}{\mkern 1mu} {\beta _{\rm{k}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} {Y_{{\rm{kit}}}}} \cr {{\rm{ + }}.{\rm{5}}{\mkern 1mu} {\Sigma _{\rm{k}}}{\mkern 1mu} {\Sigma _{\rm{l}}}{\mkern 1mu} {\beta _{{\rm{kl}}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} {Y_{{\rm{kit}}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} {Y_{{\rm{lit}}}}{\rm{ + }}{\Sigma _{\rm{q}}}{\mkern 1mu} {\phi _{\rm{q}}}{R_{{\rm{qit}}}}{\rm{ + }}.{\rm{5}}{\mkern 1mu} {\Sigma _{\rm{q}}}{\mkern 1mu} {\Sigma _{\rm{r}}}{\mkern 1mu} {\phi _{{\rm{qr}}}}{\mkern 1mu} {R_{{\rm{qit}}}}{\mkern 1mu} {R_{{\rm{rit}}}}} \cr {{\rm{ + }}{\Sigma _{\rm{k}}}{\mkern 1mu} {\Sigma _{\rm{m}}}{\gamma _{{\rm{km}}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} {Y_{{\rm{kit}}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} X_{{\rm{mit}}}^{\rm{*}}{\rm{ + }}{\Sigma _{\rm{q}}}{\Sigma _{\rm{m}}}{\gamma _{{\rm{qm}}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} {R_{{\rm{qit}}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} X_{{\rm{mit}}}^{\rm{*}}} \cr { + {\Sigma _{\rm{k}}}{\Sigma _{\rm{q}}}{\gamma _{{\rm{kq}}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} {Y_{{\rm{kit}}}}{\mkern 1mu} {\rm{ln}}{\mkern 1mu} {R_{{\rm{qit}}}} + {{\rm{v}}_{{\rm{it}}}} = {\rm{TL}}({X^*},Y,R){\rm{ + }}{{\rm{v}}_{{\rm{it}}}},{\rm{or}}} \cr } $$

(1b) $$\hskip -15pt - {\rm{ln}}\,{X_{1,it}}\, = \,\bf\it {\rm{TL}}\,\left( {X^*,Y,R} \right){\rm{ }} + {\rm{ }}{{\rm{v}}_{{\rm{it}}}} - {\rm{ ln }}{{\rm{D}}^{\rm{I}}}_{{\rm{it}}}\, = \,\bf \it {\rm{ TL}}\,\left( {X^*,Y,R} \right){\rm{ }} + {\rm{ }}{{\rm{v}}_{{\rm{it}}}} - {\rm{ }}{{\rm{u}}_{{\rm{it}}}},$$

where i denotes farm; t the time period; k,l the outputs; m,n the inputs; and q,r the R variables. In our analysis, X ₁ is land, so the function is specified on a per-acre basis. Structural R variables include soil texture (TEXT), water-holding capacity of the soil (WATHCA), the population accessibility of the farm to urban areas (URBAN), and whether the farm is certified organic (ORGANIC). TL(.) refers to the translog SPF. Stochastic frontier production methods used to estimate this equation were first developed by Aigner, Lovell, and Schmidt (Reference Aigner, Lovell and Schmidt1977) and Meeusen and van den Broeck (Reference Meeusen and van den Broeck1977). Distance from the frontier −ln D^I _it is measured as a technical inefficiency error −u_it. This error is combined with a random error component ν_it, which represents factors such as measurement error and unobserved inputs that generate noise in the data. The ν_it is assumed to be an independently and identically distributed random variable, N(0,σ_v ²). The −u_it is assumed to be non-negative, independently distributed with truncation at zero with distribution N(m_it, σ_u ²), where m_it = R_it.

The marginal productive contributions (MPC) of outputs and inputs are estimated by the first-order elasticities, MPC_m = −ε_DI,Ym = −∂ln D^I( X,Y,R )/∂ln Y _m = ε_X1,Ym and MPC_k = −ε_DI,X*m = −∂ln D^I( X,Y,R )/∂ln X*_k = ε_X1,X*k. The increase in overall input use when output expands is represented by MPC_m and is expected to be positive, such as an output elasticity or marginal cost measure. The shadow value of the k^th input relative to X ₁ is represented by MPC_k (Fare and Primont, Reference Fare and Primont1995) and, like the slope of an isoquant, is expected to be negative. MPCs of structural factors are measured through elasticities MPC_Rq = −ε_DI,Rq = −∂ln D^I( X,Y,R )/∂R _q = ε_X1,Rq. The total contribution of the M outputs Y _m, or the scale elasticity SE = −ε_DI,Y = −Σ_m∂ln D^I( X,Y,R )/∂ln Y _m = ε_X1,Y, provides a measure of scale economies (SE). Increasing RTS is found if SE < 1. We estimate TE “scores” as TE = exp(−u_it).

2.2. Selection Bias

Bias associated with selecting organic versus conventional production may be of concern for SPF estimation. Because organic producers self-select into organic production, their productivity may have been higher or lower than that of conventional farmers regardless of whether or not they had chosen to produce organic milk. In past studies, selection bias in organic dairy farming has been corrected for using propensity score matching (Mayen, Balagtas, and Alexander, Reference Mayen, Balagtas and Alexander2010) and by including an inverse Mills ratio estimated in a first-stage probit equation in a second-stage profit equation (McBride and Greene, Reference McBride and Greene2009). Mayen, Balagtas, and Alexander (Reference Mayen, Balagtas and Alexander2010) found that if self-selection bias was not corrected for, the TE of organic dairy farms would be underestimated relative to conventional farms. Alternatively, in our SPF approach, we test for selectivity bias in identifying organic versus conventional operators using the approach developed in Greene (Reference Greene2010) for nonlinear SPFs, wherein a significant rho indicates selection bias has been detected and corrected for such that it does not otherwise bias frontier estimation in a statistical sense. Accordingly, and following Nehring, Barton, and Hallahan (Reference Nehring, Barton and Hallahan2017), we correct for selectivity bias using LIMDEP. The treatment effects test, using a probit model with a dependent variable for organic versus conventional dairies and with independent variables for operator age, operator education, off-farm work hours by the operator and spouse, a household well-being index, an index for urbanization of the area where the farm is located, and total farm acres, resulted in statistically significant drivers and was conclusive with a significant rho. Probit results are included in Appendix Table A1. The interested reader is directed to Greene (Reference Greene2010) for a fuller development of this procedure.

2.3. Factors Impacting TE

Impacts of farm and producer characteristics on TE can be measured as “inefficiency effects” on u _it . Inefficiency effects are assumed to be independently distributed, and u _it arises by truncation (at zero) of the exponential distribution with mean μ _it and variance σ². The parametric SPF approach, introduced by Aigner, Lovell, and Schmidt (Reference Aigner, Lovell and Schmidt1977) and Meeusen and van den Broeck (Reference Meeusen and van den Broeck1977), was modified by Battese and Coelli (Reference Battese and Coelli1995) to specify stochastic frontiers for TE effects and simultaneously estimate all parameters involved. For the present study, because the treatment effects test conducted in LIMDEP was statistically conclusive, we use LIMDEP to estimate drivers for TE without treatment effect bias in the second-stage estimation procedure rather than follow the model described in Battese and Coelli (Reference Battese and Coelli1995).

Potential inefficiency drivers included in the model are whether the operator held a 4-year college degree (COLLEGE); the operator’s age (AGE); the year the operator began farming (YEAR); whether artificial insemination, embryo transplants, or sexed semen were used to breed dairy cows (AI); whether a dairy parlor was used (PARLOR); the number of hours the operator worked off-farm (PR-OPOFFFARM); the number of hours the spouse worked off-farm (PR-SPOFFFARM); degree of specialization of the farm in dairy production, measured as the value of dairy products divided by the total value of farm production (SPECIALIZE); farm size as measured using two dummy variables, MEDIUM indicating the farm milked 175–749 cows and LARGE indicating the farm milked ≥750 cows, with small farms of <175 cows as the base; and regional discrete variables for the HEARTLAND, EAST, and SOUTH, with the combined Mountain States and Pacific regions serving as the base; the level of accessibility to urban areas (URBAN), and index that increases with greater accessibility to urban areas as developed and discussed by Livanis et al. (Reference Livanis, Moss, Breneman and Nehring2006); and a dummy variable for the level of heat and humidity in the farm’s location, measured as a temperature-humidity index as used by Key and Sneeringer (Reference Key and Sneeringer2014), assuming levels above the median (HEAT-HUMID).

Greater operator education is expected to lead to higher TE if investment in human capital through education enhances farm decision-making. Qushim et al. (Reference Qushim, Gillespie, McMillin and Paudel2016) found that operator education was associated with higher TE for meat goat farms. Operator age and experience farming may impact farm efficiency. If older producers are utilizing older technology, they may be less efficient; however, greater experience is likely to positively impact farm efficiency. Featherstone, Langemeier, and Ismet (Reference Featherstone, Langemeier and Ismet1997) found operator age to be associated with lower TE for cow–calf farms. The use of specific technologies and production systems may also impact TE. Artificial insemination, embryo transplants, and sexed semen require expertise by the operator or hired labor to implement, but use allows access to superior genetics, may substitute for the use of a bull on the dairy operation, and in the case of sexed semen, allows for a higher percentage of (usually) female births. Use of a dairy parlor represents a different production system than around-the-barn milking.Footnote ³

Operator off-farm hours and spouse off-farm hours may be endogenous to the system, meaning that the independent variable may be correlated with the error term in the regression model. For U.S. dairy operations, off-farm operator and spousal work can provide a significant portion of the farm household income and may impact the farm labor input and/or the efficiency with which inputs are used. Previous research has suggested that off-farm operator labor lowers TE while off-farm spousal labor increases TE (Nehring et al., Reference Nehring, Gillespie, Sandretto and Hallahan2009). We use instrumental variables to predict operator and spousal off-farm labor. The following instruments are used to predict the level of operator and spousal off-farm hours. For operator off-farm hours, the instruments are operator age, operator education, quantity of milk sold, total debt, and acres operated. For spousal off-farm hours, we use spouse age, spouse education, acres operated, the farm debt-to-asset ratio, and total debt. Resulting predicted values of these two variables are included in the inefficiency effects model.

Specialization in the dairy enterprise may positively impact TE if the focus of the operator and labor on one enterprise leads to more efficient use of inputs and the dairy is not technically complementary with other enterprises. Featherstone, Langemeier, and Ismet (Reference Featherstone, Langemeier and Ismet1997) found lower TE among more specialized cow–calf farms, while Qushim et al. (Reference Qushim, Gillespie, McMillin and Paudel2016) found higher TE among more specialized meat goat farms. Farm size may positively impact TE if capital, labor, and management can be more efficiently utilized over greater output. Featherstone, Langemeier, and Ismet (Reference Featherstone, Langemeier and Ismet1997), Morrison-Paul et al. (Reference Morrison-Paul, Nehring, Banker and Somwaru2004a), and Samarajeewa, Hailu, and Jeffrey (Reference Samarajeewa, Hailu and Jeffrey2012) found higher TE for larger farms. Region may also impact TE due to different production or market conditions. Nehring, Barton, and Hallahan (Reference Nehring, Barton and Hallahan2017) found higher TE among U.S. dairy farms in areas of higher heat and humidity, and lower TE among dairy farms that were closer to urban areas.

2.4. Farm Categories and Measures for Comparison

We compare economic and productivity measures of eight combinations of organic status and farm size in this study. Farms are first divided by organic status, with those farms selling organic milk or transitioning to organic being classified as organic; otherwise they are classified as conventional. Organic farms are further broken into the following size categories: <75 cows, 75–174 cows, and ≥175 cows. Given the greater number of observations for conventional farms, especially for larger dairies, this group is broken into more size categories: <75 cows, 75–174 cows, 175–749 cows, 750–1,499 cows, and ≥1,500 cows. These size categories allow for comparisons of farm efficiency measures as estimated from the SPF as well as additional financial, productivity, and economic measures by organic status and farm size. Because ARMS uses a complex sampling procedure and weights to represent the U.S. population of dairy farms, the delete-a-group Jackknife procedure is used in this study for statistical comparisons of means among categories (Dubman, Reference Dubman2000). It is noted that few very large organic dairy farms are included in the dairy ARMS sample. USDA-NASS’s 2016 Certified Organic Dairy Survey reports six organic dairy operations in Texas in 2016 with a total inventory of 27,948 milk cows, for an average of 4,658 cows per farm. This is compared with averages of 473 cows per farm on 106 farms in California, 61 cows per farm on 455 farms in Wisconsin, and 54 cows per farm on 486 farms in New York (USDA-NASS, 2018).

In addition to SPF efficiency measures, production measures that are compared by farm size and system include the number of pasture acres used per cow, pounds of milk produced per cow per year, the use of a dairy parlor, the use of artificial insemination, and the producer keeping individual cow records. Pasture use is measured in the survey as the sum of owned and rented acres used to graze dairy cattle. Because of pasture requirements for organic dairy production, organic farms are expected to have higher pasture use than conventional farms. Furthermore, because of the increased effort and associated higher cost of gathering larger numbers of animals for milking in a pasture-based operation, it is expected that larger farms rely less on pasture than smaller farms. Gillespie et al. (Reference Gillespie, Nehring, Hallahan and Sandretto2009) showed that smaller-scale dairy farms were more likely to operate pasture-based dairy farms than larger-scale farms. Milk produced per cow is expected to be higher for conventional than organic, and for larger farms. This is due in part to the greater use of pasture on organic and smaller dairy farms, with pasture-based operations producing on average less milk per cow (Gillespie and Nehring, Reference Gillespie and Nehring2014). Larger-scale dairy operations also tend to be greater adopters of productivity-enhancing technology (Khanal, Gillespie, and MacDonald, Reference Khanal, Gillespie and MacDonald2010), which tends to increase milk produced per cow. We chose dairy parlor, artificial insemination, and individual cow record-keeping to represent production system, technology, and management practices, with all expected to be more heavily adopted by larger-scale producers, as found by Gillespie, Nehring, and Sitienei (Reference Gillespie, Nehring and Sitienei2014).

Farm financial measures compared by system and farm size include farm net return on assets, household net return on assets, and farm debt-asset ratio, all of which are whole-farm and not limited to the dairy enterprise. The first two ratios provide measures of farm profitability, the former for the farm business and the latter for the farm household. Net return on assets is defined as net farm income divided by total farm assets. Household net return on assets is defined as (net farm income + total household off-farm income) ÷ (total household assets). Debt-asset ratio is the total farm debt divided by the total value of farm assets, a measure of the proportion of the value of farm assets that is financed with debt. With economies of size in dairy production, larger-scale farms can be expected to have greater net return on assets and household return on assets. Different costs and returns for organic versus conventional producers could result in different profitability measures by production system.

Costs and returns for the dairy enterprise are compared among system and size categories using 2016 estimates developed from the 2016 ARMS Phase 3, dairy version. We use the following measures for comparison, as defined in the USDA-ERS Commodity Costs and Returns (2020) and Milk Cost of Production Estimates (2020) for the dairy enterprise on a per-hundredweight of milk produced basis: total gross value of production, purchased feed cost, total feed cost, other operating costs, total operating costs, total allocated overhead, value of production less total operating costs, and value of production less total costs. Total gross value of production includes milk sold, dairy cattle sales, and other dairy income. Total feed costs include purchased feed, the value of homegrown harvested feed used, and the value of grazed feed which is valued as the rental rate for pasture. We report purchased feed costs, with homegrown and grazed feed making up the difference between total feed and purchased feed costs. Other operating cost includes costs for veterinarian and medicine; bedding and litter; marketing; custom services; fuel, lube, and electricity; repairs; interest on operating costs; and for organic farms third-party organic certification costs. Allocated overhead costs include hired labor, opportunity cost of unpaid labor, capital recovery of machinery and equipment, the opportunity cost of land (rental rate), taxes and insurance, and general farm overhead. Total gross value of production is expected to vary by system, with organic farms having higher returns per hundredweight due to the higher price paid for milk. Operating costs are expected to be higher for organic dairies due primarily to the higher cost of organic feeds. Allocated overhead costs are expected to be lower for larger-scale farms due to economies of size.

Cost and return estimates for 2016 U.S. milk using 2016 ARMS data are provided by USDA-ERS Organic Costs and Returns (2020). The estimates provided in this paper differ from those provided by USDA-ERS Organic Costs and Returns (2020) in the following ways: (1) the size categories differ and (2) statistical differences in costs and returns among size categories and organic/conventional status are provided.