Conjoint Analysis and Cattle Traits

Conjoint analysis arose from the consumer theory developed by Lancaster (Reference Lancaster1966) that expresses that consumer utility is a function of the characteristics of a good. This suggests that it is possible to decompose the total utility associated with a good into separate “part-worth” utilities of its constituent characteristics (Louviere, Hensher, and Swait Reference Louviere, Hensher and Swait2000). A number of beef demand valuation studies (Umberger et al. Reference Umberger, Feuz, Calkins and Killinger-Mann2002; Loureiro and Umberger Reference Loureiro and Umberger2003; Lusk, Roosen, and Fox Reference Lusk, Roosen and Fox2003; Lusk and Parker Reference Lusk and Parker2009; Steiner, Gao, and Unterschultz Reference Steiner, Gao and Unterschultz2010) have used conjoint analysis to estimate consumer preference for various beef attributes.

For the case of cattle selection, conjoint analysis allows for analysis of producer preferences for cattle characteristics of the animals they purchase for finishing. These preferences are likely to be based primarily on the benefits they perceive to result from raising animals with those characteristics (Tano et al. Reference Tano, Kamuanga, Faminow and Swallow2003). Each beef producer has unique preferences for the traits embodied in cattle. Studies using conjoint analysis to estimate producer preferences for cattle traits include Sy et al. (Reference Sy, Faminow, Johnson and Crow1997), Scarpa et al. (Reference Scarpa, Ruto, Kristjanson, Radeny, Drucker and Rege2003), Ouma, Abdulai, and Drucker (Reference Ouma, Abdulai and Drucker2007), and Ruto, Garrod, and Scarpa (Reference Ruto, Garrod and Scarpa2008). None of these studies have focused on the grass-fed segment of cattle production. A more recent study using conjoint analysis to examine livestock producer preferences for breeding animal traits focused on the meat goat industry (Nyaupane et al. Reference Nyaupane, Gillespie, Harrison, McMillin and Sitienei2017).

A list of 15 cattle traits that could potentially impact producer choice of animals for grass-finishing was developed based upon discussion with Louisiana GFB producers who were cooperators in the study, knowledge of the industry, and literature review. With this many traits, however, use of a choice-based conjoint analysis where respondents choose among hypothetical product profiles would be infeasible due to the large number of choices respondents would have to make. To retain the most important traits while reducing the number of attributes and their levels, the most relevant attributes were determined by the authors who represent the fields of animal science and agricultural economics and have worked closely with project-cooperator and grass-fed beef producers since 2010. By considering the most important traits as well as overlap among several of the traits, the number of attributes was reduced to seven. Furthermore, the number of levels considered for each trait was reduced. Follow-up farm visits with four Louisiana GFB producers to discuss the selected attributes confirmed the appropriateness of these attributes and their levels for the study.

Of the seven attributes included in the final questionnaire, five consisted of three levels each and the remaining had two levels each. Selected attributes included: (1) Weight in pounds at which the animal is introduced to the forage finishing phase (550, 650, and 750 lbs); (2) Body Frame, referring to the animal's skeletal size based on its hip height (small, medium, and large); (3) Temperament, referring to how easy or difficult it is to handle the animal; (4) Gender (heifer, steer, or intact male); (5) the Source of the animal (retained from own cows, purchased at auction, or purchased via private treaty); (6) the animal's Color, referring to its coat color, which was generalized to two levels, black or non-black, on the basis of a general preference in the grain-fed beef sector for black angus cattle; and (7) Price representing the value of the animal per hundredweight (cwt)—the price to purchase the animal or the market value of the retained animal for producers raising their own animals. Based on market prices for calves in the year the survey was conducted and the previous two years, three price levels were chosen: $120, $140, and $160/cwt.

Given the five 3-level and two 2-level traits, a full factorial design would yield (3⁵ × 2²)  = 972 profiles. It would be impracticable to work with such a large number of profiles in a conjoint analysis, as the respondent would be requested to respond to too many questions, leading to respondent fatigue and response bias (Louviere, Hensher, and Swait Reference Louviere, Hensher and Swait2000), as well as low response. To reduce the number to a manageable level, an orthogonal fractional factorial design including 18 profiles was used (Harrison, Stringer, and Prinyawiwatkul Reference Harrison, Stringer and Prinyawiwatkul2002; Hair et al. Reference Hair, Black, Babin, Anderson and Tatham2006). The orthogonal fractional factorial experimental design package in Statistical Product and Service Solutions (SPSS) was used to recover the main effects consisting of 18 cattle profiles. A randomized selection of nine choice sets (pair-wise comparisons of the 18 cattle profiles) to be presented to respondents was obtained. The fractional factorial design ensures that independence among the hypothetical product levels (orthogonality) is maintained (Hair et al. Reference Hair, Black, Babin, Anderson and Tatham2006).

For each of the nine choice sets, respondents were asked to select the animal they would retain/purchase for forage finishing. The survey question was framed as, “Suppose you are selecting animals to bring into your herd to raise to slaughter/harvest weight. These could be either purchased or could have been produced from your own cows (retained). ‘Animal A’ and ‘Animal B’ will represent hypothetical profiles of animals that could be brought into your herd for forage finishing. You will be asked to choose between these two animals based on the characteristics provided. Other than the characteristics provided, imagine that the animals are identical. If neither is acceptable, then the ‘neither’ option can be chosen.” For example, each choice option shown in Figure 1 represents a hypothetical animal profile described in terms of animal traits and their levels. In this case, respondents were asked to select one of the three options: “Animal A,” “Animal B,” or “Neither.” There were nine such choice sets.

Figure 1. Sample of a Choice Experiment Question.

Econometric Methods Used in Part-Worth Estimation

McFadden's (Reference McFadden1986) random utility theory provides insight for designing a study to estimate producer preferences using conjoint analysis. We assume producers derive utility from cattle traits. A general utility functional form U _ij = V _ij + ε _ij for producer i is specified where U _ij is the i ^th producer's utility associated with choosing attribute j, V _ij is the non-stochastic portion determined by the cattle attributes and their levels, and ε _ij is the identically and independently distributed (IID) error term.

We use a mixed logit model (MLM) to estimate producer preferences for cattle traits, assuming there are N agents facing J alternatives on T choice occasions. Individual i is assumed to consider the full set of offered alternatives in choice situation t and to choose the alternative with the highest utility. The kernel for the MLM is the logit formula for a given choice or repeated choices made by an agent (Revelt and Train Reference Revelt and Train1998; Train Reference Train2008). McFadden and Train (Reference McFadden and Train2000) showed the advantages of using the MLM to approximate a random utility model to any degree of accuracy with clear specification of variables and a mixing distribution. It is a flexible logit model that allows parameters associated with the observed variable to vary across individuals having a known population distribution. Among the multinomial logit models, MLMs are the most flexible (Revelt and Train, Reference Revelt and Train1998; McFadden and Train, Reference McFadden and Train2000; Bhat, Reference Bhat2003; Greene and Hensher, Reference Greene and Hensher2003).

Introduction of the choice occasions slightly modifies the general McFadden (Reference McFadden1986) random utility model. The utility that individual i derives from choosing alternative j on choice occasion t is defined as:

(1)$$U_{ijt} = {\rm \beta} _ix_{ijt} + \epsilon _{ijt}\comma \; $$

where x _ijt is a vector of non-stochastic alternative-specific attributes and ε _ijt is a random term not observed by the analyst and assumed to be IID extreme value. Each β_i in vector β^′ is assumed to be random with unconditional density $f\lpar {\rm \beta} _i\vert \emptyset \rpar$ where $\emptyset$ is the distribution of parametersβ in the population—such as its mean and covariance (Train Reference Train2008). The traditional McFadden choice model provides the probability of a sequence of choices made by agent i:

(2)$$Pr_i\lpar {\rm \beta} \rpar = \mathop \prod \limits_{t = 1}^T \mathop \prod \limits_{\,j = 1}^J \left({\exp \lpar {\rm \beta}_ix_{ijt} \rpar \over \mathop \sum \nolimits_{l = 1}^M \exp \lpar {\rm \beta}_ix_{ilt} \rpar} \right)^{d_{ijt}}\comma \; $$

where d _ijt is a binary variable that equals 1 if respondent i chooses alternative j in time t and 0 otherwise. Conditional on knowing β_i, the probability of respondent i choosing alternative j on occasion t is given by the following conditional logit formula (McFadden Reference McFadden1974):

(3)$$L_{ijt}\lpar {{\rm \beta}_i} \rpar = \displaystyle{{{\rm exp}\lpar {{\rm \beta}_ix_{ijt}} \rpar } \over {\mathop \sum \nolimits_{l = 1}^M {\rm exp}\lpar {{\rm \beta}_ix_{ilt}} \rpar }}$$

Train (Reference Train2000) discusses the relevance of Halton draws in MLM model estimation. To select the number of Halton draws required to secure a stable set of parameter estimates, the MLM was estimated over a range of draws from 50 to 1,000 during our initial specification search. Hensher and Greene (Reference Hensher and Greene2003) discussed the importance of stability in selecting an optimum number of Halton draws in a MLM. Bhat (Reference Bhat2001) and Train (Reference Train2000) found lower simulation variance using 100 than when using 1,000 Halton draws. Both studies found that simulation error increased as the number of Halton draws increased. Hensher and Greene (Reference Hensher and Greene2003) recommended a smaller number of draws to reduce length of run time and simulation error. To reduce estimation time and simulation error, 500 Halton draws were selected for our final model.

All seven cattle traits were treated as random parameters for the MLM. Specification of random parameters in a MLM can take a number of predefined forms: normal, triangular, uniform, and/or lognormal (Hensher and Greene, Reference Hensher and Greene2003). Decision on the type of distribution to use depends on the type of the expected response parameter and the data source (Hole Reference Hole2007). For example, if a non-negative sign is expected on the response parameter, then a lognormal form will be used (Hensher and Greene Reference Hensher and Greene2003). We used a uniform distribution with a (0, 1) bound for the dummy coded variables, implying that traits may plausibly have either a positive or negative response parameter.

The random parameters logit model can be used to estimate heterogeneous preferences by allowing model parameters to vary over respondents. A problem is that it cannot account for the sources of heterogeneity (Boxall and Adamowicz Reference Boxall and Adamowicz2002). Latent class models (LCM) can be used to estimate both the observable and unobservable heterogeneity caused by factors that can and cannot be observed by the analyst, respectively (Greene and Hensher Reference Greene and Hensher2003).

Understanding the form and source of heterogeneity in cattle preferences among GFB producers is of interest to our study. Thus, the LCM is used to estimate the sources of preference heterogeneity among producers. Various segments are likely to be present among GFB producers, each segment characterized by relatively homogenous preferences. As discussed by Boxall and Adamowicz (Reference Boxall and Adamowicz2002), attitudinal measures and quantifiable demographic characteristics are the determinants of membership in different classes or segments.

To account for preference heterogeneity, some economists have included demographic characteristics in demand functions (Boxall and Adamowicz, Reference Boxall and Adamowicz2002). A limitation to this approach is that it requires a priori selection of key individual characteristics and attributes. Researchers have limited access to such individual-specific variables (e.g., income, debt-to-asset ratios). Some researchers have taken advantage of their a priori knowledge of variables (Morey, Rowe, and Watson Reference Morey, Rowe and Watson1993) by explicitly incorporating them into indirect utility functions. However, in the case of random utility models, estimation of heterogeneity is difficult because individual characteristics are invariant among a set of choices (Boxall and Adamowicz Reference Boxall and Adamowicz2002) and some important individual-specific variables may be unobservable to the researcher. Latent class logit models have been developed to address this issue.

Using LCMs, we assume that preference heterogeneity across classes can be sufficiently explained by a discrete number of classes (Shen Reference Shen2009). The probability of individual i belonging to class s choosing alternative j in the t ^th choice situation is:

(4)$$P_{ijt \vert s} = \mathop \prod \limits_{t = 1}^T \displaystyle{{\exp \lpar {{\rm \beta}_sx_{ijt}} \rpar } \over {\mathop \sum \nolimits_{l = 1}^M \exp \lpar {{\rm \beta}_sx_{ilt}} \rpar }}\; \; s\; = \; 1\comma \; \; . \; . \; . \; \comma \; \; S\comma \; $$

where β_s is the class-specific parameter used to capture heterogeneity in preference across classes, x _ijt is a vector of alternative-specific traits for individual i, and t is the number of choice occasions for individual i. Letting z _it denote individual i's specific choice made on the t ^th occasion, a linear probability relation for the specific choice of individual i can be formulated as:

(5)$$P_{ijt} = {\rm Prob}\lpar {z_{it} = j{\rm \vert class} = s} \rpar .$$

This is a panel data application, since we assume that the same individual is observed on several choice occasions (Greene and Hensher Reference Greene and Hensher2003). With class assignments, it is possible to estimate the contribution of individual i to the likelihood function which is the joint probability of the sequence z _i = [z _i1, z _i2, …, z _iT]:

(6)$$P_{i \vert s} = \mathop \prod \limits_{t = 1}^{T_i} P_{it \vert s}\comma \; $$

where P _i|s is the probability of individual i being in group s, which is the product of individual i belonging to group s on T occasions.

The researcher must determine the optimal number of classes to use for the LCM. Roeder, Lynch, and Nagin (Reference Roeder, Lynch and Nagin1999) suggest using Bayesian Information Criteria (BIC) to determine the optimal number of classes. Louviere, Hensher, and Swait (Reference Louviere, Hensher and Swait2000) suggested other information theoretic criteria that have been widely used, such as the Akaike Information Criteria (AIC) and its variant the Consistent Akaike Information Criteria (CAIC). The optimum number of classes is determined where the values of the BIC, AIC, and/or CAIC are minimized. The CAIC was used for this study because it provides a standardized way to balance sensitivity and specificity (Dziak, et al. Reference Dziak, Coffman, Lanza and Li2012).

Using Likert Scale Questions to Assess Animal Selection

In addition to conjoint questions to assess why producers selected certain animals for grass-fed beef production, Likert scale questions were used to provide further insight. Respondents were asked, “How important are each of the following attributes in your selection of grass-fed beef animals to produce on your farm? For each attribute, please circle the number that best represents your opinion.” Four responses were provided, including (1) Not Important at All, (2) Somewhat Important, (3) Very Important, and (4) Highly Important. Attributes assessed included Breed, Expected Average Daily Weight Gain, Frame Score/Body Frame, Expected Carcass Yield, Disease Resistance, Expected Reproductive Performance, Temperament, Heat Tolerance, Hide/Coat Color of the Animal, and Parents Were Never Fed Grain. These questions allowed us further insight into the cattle attributes most valued by grass-fed beef producers, with results to be compared and contrasted with those obtained via the conjoint analysis. Some attributes included in the Likert scale questions were not included in the conjoint questions. In several cases, these represented traits that would not be readily apparent when viewing an animal, such as average daily weight gain, parents were never fed grain, etc. While breed was also not explicitly included in the conjoint analysis, breed may be considered as a composite attribute since it is likely to be composed of a number of specific attributes such as body frame, coat color, and in some cases temperament.

Responses to Likert scale questions were analyzed using the ordered probit model. The use of ordered probit models has been rather common in the agricultural economics literature in recent years, so we refer the reader to Greene (Reference Greene2003) for a fuller discussion of the model. Independent variables used in the ordered probit models to determine the impact of producer demographics and farm characteristics on animal attribute importance were: Cow-Calf, whether the producer was a cow-calf producer, breeding cows and raising calves to weaning weight; Number of Beef Animals, indicating the size of the grass-fed beef operation; Sell Grass-Fed Beef as Meat, a dummy variable indicating whether or not the producer sold grass-fed beef as meat (as opposed to selling only grass-fed beef animals); percent Income Grass-Fed Beef, indicating the percentage of net farm income coming from the grass-fed beef operation; the producer's Age; Years of Operation, the number of years the producer had operated the grass-fed beef enterprise; College Degree, whether or not the producer held a college Bachelor's degree; and region of the U.S. where the farm was located including Northeast (MA, NY, PA), Midwest, Southeast, Northwest, and Southwest.

Data Collection

The survey questionnaire was mailed to 1,052 U.S. grass-fed beef producers on August 10, 2013, following the Tailored Design Method as recommended by Dillman, Smyth, and Christian (Reference Dillman, Smyth and Christian2009). The names of these producers had been collected via an extensive Internet search. Sources included www.eatwild.com, the American Grass-fed Association, Market Maker, and a search for individual farms advertising their beef online. The first mailing contained a personally addressed, signed cover letter explaining the purpose of the survey; the ten-page questionnaire; and a postage-paid return envelope. A postcard reminder was sent approximately 1.5 weeks later, followed by a third mailing, 1.5 weeks after the postcard, that included another personally addressed and signed cover letter, replacement questionnaire, and a postage-paid return envelope. Finally, another postcard reminder was sent approximately 1.5 weeks later.

A total of 384 usable responses were received. Returns from individuals no longer in the grass-fed beef business and incorrect addresses totaled 117. After adjusting for returns from incorrect addresses and those who were no longer in the grass-fed beef business, a 41.1 percent return rate was obtained. This rate is compared with past studies that have used similar approaches, such as for Louisiana crawfish producers, 15 percent (Gillespie and Nyaupane, Reference Gillespie and Nyaupane2010); dairy farmers, 15 percent (Paudel et al. Reference Paudel, Gauthier, Westra and Hall2008); and meat goat producers, 43 percent (Gillespie,Nyaupane, and McMillin Reference Gillespie, Nyaupane and McMillin2013). We have a convenience sample with no known recent studies from which to compare for representativeness. Given our thorough search of the Internet for names and addresses of grass-fed beef producers and relatively strong return rate, we believe our sample reasonably represents grass-fed beef producers who advertise their product via the Internet.