2. Model

The theoretical model used in this article is a modified version of the model in Borges and Thurman (Reference Borges and Thurman1994). The modification relates to the lack of opportunities for Icelandic dairy farms to carry over their unused milk quota to a subsequent production period.Footnote ² In the remainder of this section, the Borges and Thurman (Reference Borges and Thurman1994) model based on an aggregate input is presented first. A discussion on the construction of the aggregate input follows.

2.1. Probability of Surplus Production and Relative Marginal Importance of Price Changes

Let y be the milk yield per unit of an aggregate input x, and Y be the total milk that is produced by a dairy farm, which is constrained by a farm-level quota q. Then, q/x is the yield that is required per unit of an aggregate input to meet the quota exactly or the yield requirement. Yield is random, and f(y) is its probability density function. Consequently, Y = x · y, and the production problem of the farm reduces to a choice of aggregate input quantity. In this setting, the observed levels of the aggregate input provide information concerning the unobservable planned production given the yield density, which then allows evaluation of planned production relative to each farm's quota. For example, if the yield requirement is smaller than the expected yield at the chosen level of the aggregate input, then we can infer that the dairy farm must have planned to overproduce its quota.

Under risk neutrality, no price uncertainty, and no carryover of unused quota, the economic problem of the dairy farm can be presented as a maximization of expected profit, as given in Borges and Thurman (Reference Borges and Thurman1994):

(1) $$\begin{eqnarray} E\left( \Pi \right) &=& \int_0^{q/x} {\left[ {p_q^{}xy} \right]f\left( y \right)} \,dy \nonumber\\ && +\,\int_{q/x}^{\infty} {\left[ {p_q^{}q + {p_a}\left( {xy - q} \right)} \right]} \,f\left( y \right)dy - C\left( x \right), \end{eqnarray}$$

where p_q is the milk price in the quota milk market, p_a is the milk price in the surplus milk market, and C(x) is the cost of employing x. That is, the expected profit is the excess of a weighted sum of revenues over production cost. The probabilities that the milk yield will be within or above the quota are used as weights. As in Borges and Thurman (Reference Borges and Thurman1994), Φ = ∫^∞ _q/x f(y) dy is an estimate of the probability that planned production may exceed the farm's quota.

Following the same procedure as in Borges and Thurman (Reference Borges and Thurman1994), the relative marginal importance of price changes in the quota and surplus milk markets would be the following:Footnote ³

(2a) $$\begin{equation} \Theta _q = \frac{{{{\partial x} / {\partial p_q}}}}{{{{\partial x} / {\partial p_q}} + {{\partial x} / {\partial p_a}}}} = \frac{{\int_0^{q/x} {yf\left( y \right)dy} }}{{\int_0^{\infty} {yf\left( y \right)dy} }}, 0 \le \Theta _q \le 1, \end{equation}$$

(2b) $$\begin{equation} \Theta _a = 1 - \Theta _q. \end{equation}$$

Θ _q measures the relative marginal importance of a price change in the quota milk market relative to an equivalent and simultaneous price change in the quota and surplus milk markets. Therefore, Θ _q implies the increasing importance of price changes in the quota milk market as it gets closer to unity and vice versa. Furthermore, as noted by Borges and Thurman (Reference Borges and Thurman1994), $\mathop {\lim \,}_{{q / {x \to 0}}} \Theta _q = 0$ and $\mathop {\lim \,}_{{q / {x \to \infty }}} \Theta _q = 1$ . This outcome is intuitive because for a given quota size, the relative marginal importance of a price change in the quota milk market decreases as q/x gets smaller, which indicates a producer that is planning to overproduce its quota. In contrast, when a producer seeks to avoid overproduction, q/x increases and the relative marginal importance of a price change in the quota milk market increases.

2.2. Construction of Aggregate Input

In this section, the construction of weights required to compute an aggregate input is presented. Given that yield data imply a technical relation between an input and an output, an obvious candidate for generating aggregation weights is a production frontier. A production frontier represents the best available technique for transforming inputs into outputs. To obtain an econometric estimate of the production frontier, a mathematical relation between inputs and an output is specified in a translog form, which provides a second-order approximation to any unknown function (Christensen, Jorgenson, and Lau, Reference Christensen, Jorgenson and Lau1973):

(3) $$\begin{eqnarray} \ln {Y_{it}} &=& {\alpha _0} + \sum_{j = 1}^n {{\alpha _j}} \ln {x_{jit}} + \rho t + \frac{1}{2}\sum_{j = 1}^n {\sum_{k = 1}^n {{\alpha _{jk}}\ln {x_{jit}}\ln {x_{kit}}} } \nonumber\\ && +\, \sum_{j = 1}^n {{\alpha _{jt}}} t\ln {x_{jit}} + \frac{1}{2}{\rho _{tt}}{t^2} + {\varepsilon _{it}}. \end{eqnarray}$$

The x_jit ’s are the j inputs used to produce milk, t is a time trend introduced to capture the effect of technical change, and ε _it is a composite error term that contains a random noise component, v_it , and a nonnegative time-varying technical inefficiency component, u_it , or ε _it = v_it − u_it . The farm- and time-specific technical efficiency scores (TE_it ) for each farm are obtained by TE_it = exp (− u_it ). Following Battese and Coelli (Reference Battese and Coelli1992), the temporal pattern of technical inefficiency is specified as u_it = exp { − η(t − T)} · u_i , where η is a decay parameter and T is the terminal period in the data. When η > 0, technical efficiency increases over time, and it decreases when η < 0. Furthermore, the random noise term v_it is symmetrical and assumed to be normally distributed—that is, v_it ~ N(0, σ² _v ). In contrast, technical inefficiency is assumed to follow a truncated normal distribution; that is, u_i ~ N ⁺(μ, σ² _u ), which also nests the commonly used half-normal distribution or u_i ~ N ⁺(0, σ² _u ). Therefore, one can use nested hypothesis testing to choose the distributional assumption that fits the data best. In addition, the two error terms are assumed to be independently and identically distributed and orthogonal to one another as well as the independent variables of the model.

Given the parameters of the production frontier, the aggregate input is constructed as follows:

(4) $$\begin{equation} {x_{it}} = \sum_{j = 1}^n {\left( {{{{\delta _{jit}}} / {{\delta _{it}}}}} \right)} \cdot {x_{jit}}, \end{equation}$$

where ${\delta _{jit}} = \frac{{\partial \ln {Y_{it}}}}{{\partial \ln {x_{jit}}}}$ and δ _it = ∑ ⁿ _{j = 1}δ _jit . When markets are competitive, inputs are paid their marginal product, and profits are maximum, the weights can be understood as follows (Kim, Reference Kim1992):

(5) $$\begin{equation} \frac{{{\delta _{jit}}}}{{{\delta _{it}}}} = \frac{{{{\partial \ln {Y_{it}}} / {\partial \ln {x_{jit}}}}}}{{\sum_{j = 1}^n {{{\partial \ln {Y_{it}}} / {\partial \ln {x_{jit}}}}} }} = \frac{{{w_{jt}}{x_{jit}}}}{{{C_{it}}}}, \end{equation}$$

where w is the input price and C is the minimum cost of production. Therefore, the weights that are attached to each input can also be understood as the cost share of the input from total cost.

3. Empirical Strategy

Under the methodology specified, a milk yield density function has to be estimated. However, two problems arise for this estimation. First, ideally, farm-level yield densities should be estimated (Ker and Coble, Reference Ker and Coble2003). However, a common problem is that yield observations per farm are usually too few to support reliable estimation (Goodwin and Ker, Reference Goodwin, Ker, Just and Pope2002). Therefore, data pooling under certain assumptions, such as equal yield variance, or using yield data from some aggregate levels, such as counties, is commonly considered to ensure sufficient observations for yield density estimations (Borges and Thurman, Reference Borges and Thurman1994; Ker and Coble, Reference Ker and Coble2003). The number of observations per farm is also too few in the data used here, and thus data pooling in some form is unavoidable. We start by assuming that the yield density is identical for all farms in a given year, although it may vary across years, for example, because of technical change. However, technical efficiency can vary across farms in a given year as well as over time.Footnote ⁴ This can be addressed using farm- and time-specific technical efficiency scores that are obtained from equation (3). In particular, the observed output levels are corrected for technical inefficiency as $Y_{it}^* = {\raise0.7ex\hbox{${{Y_{it}}}$} \!/ \!\lower0.7ex\hbox{${\exp ( { - {u_{it}}} )}$}}$ , where Y* _it is the output level that will be observed if the farms are technically efficient or TE = exp (− u_it ) = 1. Given the emphasis to learn about planned production, generating the yield data based on Y* rather than Y is logical because no rational farm will choose input levels aiming to be technically inefficient.

Under the assumption that technical change affects the expected yield only, while leaving higher moments unaffected, a simple approach is used to handle the effect of technical change. This approach involves three steps: First, the annual average yields are computed and subtracted from the yield data of the respective years. Second, the lowest annual average yield is added back to the demeaned yield data. Finally, the pooled data are used to estimate the yield density function of the year with the lowest annual average yield. Yield density functions of the other years are then recovered by scaling the yield density function of the year with the lowest annual average yield by the difference in average yields between the year under consideration and the least productive year. This approach is the same as the one used by Borges and Thurman (Reference Borges and Thurman1994) to control for assumed differences in technical efficiency between counties.

A second problem concerning estimating yield densities parametrically relates to the choice of functional form. The literature employs several functional forms to model crop yield densities (Goodwin and Ker, Reference Goodwin, Ker, Just and Pope2002; Ramirez, McDonald, and Carpio, Reference Ramirez, McDonald and Carpio2010). However, the estimation of yield densities for dairy production is not as common as it is for crop production. One alternative for minimizing a specification error is to use a flexible functional form, such as the Johnson distribution system (Johnson, Reference Johnson1949; Johnson, Kotz, and Balakrishnan, Reference Johnson, Kotz and Balakrishnan1994). The Johnson distribution system is a system of four distributions that can accommodate any finite and feasible combination of the first four moments. Consequently, it can approximate a wide range of distributions, including those that are commonly used for modeling crop yield data. Another alternative is to use nonparametric estimation (e.g., see Ker and Coble, Reference Ker and Coble2003; Ker and Goodwin, Reference Ker and Goodwin2000).

The distributions that form the Johnson family are identified by a set of normalizing transformations that were proposed by Johnson (Reference Johnson1949). In particular, given a continuous random variable with an unknown density function, Johnson (Reference Johnson1949) proposed a set of normalizing transformations with the general form:

(6) $$\begin{equation} Z = \gamma + \delta \cdot g\left( u \right), \end{equation}$$

to obtain a unit normal distributed variable Z. The parameters γ and δ > 0 are shape parameters, whereas $u = \frac{{y - \xi }}{\lambda }$ , where ξ and λ > 0 are location and scale parameters, respectively. The parameter g(u) is a transformation function that assumes different forms to define the distributions in the Johnson family. These forms are the following (Johnson, Reference Johnson1949; Johnson, Kotz, and Balakrishnan, Reference Johnson, Kotz and Balakrishnan1994):

(7) $$\begin{equation} g\left( u \right) = \left\{ {\begin{array}{l@{\qquad}l} {\ln \left( u \right),}&{{\rm{for\; the\; }}{S_L}\left( {{\rm{the\; log - normal}}} \right)\;{\rm{ family, }}\,}\\ {{\rm{ln}}\left[ {u + \sqrt {{u^2} + 1} } \right],}&{{\rm{for\; the\; }}{S_U}\left( {{\rm{unbounded}}} \right)\;{\rm{ family, }}\,}\\ {{\rm{ln}}\left[ {\frac{u}{{\left( {1 - u} \right)}}} \right],}&{{\rm{ for\; the\; }}{S_B}\left( {{\rm{bounded}}} \right)\;{\rm{family,\; and }}\,}\\ {u,}&{{\rm{for\; the\; }}{S_N}\left( {{\rm{normal}}} \right)\;{\rm{family}}{\rm{. }}} \end{array}} \right. \end{equation}$$

As suggested by Hill, Hill, and Holder (Reference Hill, Hill and Holder1976), the estimated skewness and kurtosis coefficients of the data determine the particular distribution that fits the data best. However, such moment-matching estimators are criticized, for example, because of the sensitivity of the third and fourth moment estimates to outliers (Slifker and Shapiro, Reference Slifker and Shapiro1980). However, other estimators also exist, such as the quantile-based estimator that is suggested by Wheeler (Reference Wheeler1980) where the best distribution is selected based on five quantiles rather than the first four moments.

Given the previously discussed strategy, the milk yield density function is estimated twice: first based on the yield per aggregate input data and second based on the yield per cow data. The implication of allowing for multiple inputs is then evaluated by comparing the results from the two empirical yield density functions.

4. Data

The empirical analysis is based on production data from 324 Icelandic dairy farms that cover the period from 1998 to 2006.Footnote ⁵ Icelandic dairy farms are small family-owned enterprises with an average herd size of 31 cows in 2006. Iceland is among the countries identified with high support for agricultural producers (Organization for Economic Cooperation and Development, 2007). Consequently, the excess production problem that has followed farm support programs elsewhere also occurred in Iceland in the 1970s, and the need for production control measures had become more apparent by the end of the decade (Agnarsson, Reference Agnarsson2007).

Nontradable farm-level marketing quotas were then introduced in 1980. However, after the third milk agreement (1992–1997) between the Farmers Association of Iceland and the Ministry of Agriculture, the dairy quota has been freely tradable (Bjarnadottir and Kristofersson, Reference Bjarnadottir and Kristofersson2008). This change has resulted in the restructuring of the dairy sector toward fewer but larger dairy farms (Bjarnadottir and Kristofersson, Reference Bjarnadottir and Kristofersson2008). The quota entitles dairy producers to direct payments from the government and higher prices for all milk that is delivered inside the quota according to its composition and hygienic quality. Surplus milk can be sold in a surplus milk market at usually much lower prices that are determined by market forces. Additionally, the quota system requires that dairy farms fill their quota every 2 years or risk losing it. However, it is also possible to obtain permission not to use the quota for a certain time period (Agnarsson, Reference Agnarsson2007). See Atsbeha, Kristofersson, and Rickertsen (Reference Atsbeha, Kristofersson and Rickertsen2012) for more details of the Icelandic dairy sector.

Of the total sample, there are 63.1% instances of overproduction. However, surplus production by the average Icelandic farm is small, and it amounts to 3.8% of the average quota size. To get an idea of how systematic surplus production is, as opposed to optimization error, one can use the Norwegian case. Until 1997, Norway used a two-tier price system and subsequently replaced it with a levy system. Under the levy system, farmers pay penalties for surplus production. However, to allow for optimization errors, a farm can deliver milk up to 102% of its allocated quota before penalties apply. If the same allowance is used for Icelandic dairy farms, one can easily see that surplus production by choice may not be significantly high for the average Icelandic dairy farm. However, as shown in Table 1, there is significant variation across farms and over time. For the 83.4% of farms that exceeded their quota in some year, the average surplus production was 11.4% of the corresponding quota size during 1998–2006.

Table 1. Descriptive Statistics, 1998–2006

Note: 1 USD = ISK 111.2 on November 3, 2016 (http://www.sedlabanki.is).

The translog production function for milk was specified with six inputs and a trend variable. The inputs are concentrates, capital, veterinary services, land, number of cows, and labor. Concentrates, capital, and veterinary services are measured in monetary units that are deflated to 1998 prices using the consumer price index for agricultural products. Land is measured in hectares, and the number of cows is measured in cow-years, which is a weighted aggregate of the number of cows on a farm. The number of days in a year a cow has been active in milk production, or days in milk, is used for weighting. Labor use is measured as labor months per year. The descriptive statistics of these inputs are provided in Table 1.

The use of all inputs except for labor has increased over time. The largest increase is in capital and concentrates, which have increased by 15.6% and 6.5% per year, respectively. The number of cows increased by 1.7%, and quota size increased by 5.6% per year. These changes in input use are indicative of the significant structural adjustment that has occurred in the Icelandic dairy sector since 1992.