2 Preliminary definitions

Similar to many previous approaches (e.g., Davis-Stober, 2009; Reference Iverson and FalmagneIverson & Falmagne, 1985; Reference Myung, Karabatsos and IversonMyung, Karabatsos, & Iverson, 2005), we model stochastic choice between two choice alternatives a and b as a fixed probability, _ab, i.e., the probability that a is chosen over b. If we model each paired comparison in a two-alternative forced choice task as a Bernoulli process then, assuming independence between trials, a DM’s choice responses follow a binomial distribution. Let n _ab be the number of times the DM chose a over b and let N _ab be the total number of times the pair was presented to the DM. Let K be the set of all distinct choice pairs under consideration.Footnote ³These assumptions give the following likelihood,

(1)

where 0<θ _ab<1, ∀ (a,b) ∈ K. To further simplify notation, let θ = (_ab)_{∀ (a,b) ∈ K} and n = (n _ab)_{∀ (a,b) ∈ K}. Note that (1) can easily be extended to ternary choice by using a trinomial distribution, and, more generally, to k-ary choice, where k ∈ ℕ, using the appropriate multinomial distribution.

Let m be the number of distinct decision strategies under consideration. To each candidate strategy we assign a vector, denoted z, that encodes that strategy’s prediction for each choice pair. Thus, each vector z is of size |K| × 1 with coefficients of 1 (predicts a is preferred to b for the respective choice pair), 0 (predicts b is preferred to a for the respective choice pair), or .5 (predicts guessing between a and b).

We model the different strategy-specification pairs under the common likelihood framework of (1) by placing a series of systematic constraints upon the θ parameters. Let Θ denote the parameter space of all possible θ. By placing these models under a common likelihood structure, we are, in a sense, placing these different strategy-specification pairs on a “common ground” and can carry out model selection to find the best account of the data.

2.2 Mixtures specifications

One of the most general frameworks for modeling multiple strategies is equivalently termed either a random preference model (Reference Loomes and SugdenLoomes & Sugden, 1995; Reference Marschak, Arrow, Karlin and SupperMarschak, 1960) or a distribution-free random utility model (e.g., Davis-Stober, 2009; Reference FalmagneFalmagne, 1978; Reference Niederée, Heyer and MarleyNiederée & Heyer, 1997; Reference RegenwetterRegenwetter, 1996; Reference Regenwetter and MarleyRegenwetter & Marley, 2001). This stochastic specification models both preference and choice as probabilistic, with a DM’s observed choices being governed by a (possibly unknown) probability distribution over a set of strategies. As an example, suppose a DM eats at a restaurant and tends to follow two different strategies. On some days, he wants to spend as little money as possible and orders the cheapest meal on the menu, at other times he chooses by food quality and therefore chooses the more expensive dishes. This DM’s choices could be well-modeled by a probability distribution over these two strategies (choose by price or food quality).

This type of mixture specification has a very nice geometric interpretation within our framework. Let {z ₁, z ₂, …, z _m} be the vector representations of a set of m strategies to be considered as a mixture specification, i.e., a stochastic specification in which the DM’s choice probabilities are modeled as an arbitrary probability distribution over the m strategies. We can compactly represent the set of all probability distributions over a set of m strategies {z ₁, z ₂, …, z _m} as the set of all sums,

(2)

where w _i ≥ 0, ∀ i ∈ {1,2,…, m} and ∑_i=1^m w _i = 1.

The weights, w _i, are the corresponding probability weights for the mixture distribution over the m many decision strategies. The set of all such sums (sets of probability weights) corresponds to the convex hull of the set of vectors representing the strategies under consideration, thereby defining a convex polyhedron in the appropriate geometric space (Reference ZieglerZiegler, 1994). If we consider the points {z ₁, z ₂, …, z _m} as embedded within the parameter space Θ we obtain a polyhedron such that its interior corresponds to each and every possible probability distribution over the decision strategies {z ₁, z ₂, …, z _m}. This polyhedron can be uniquely associated with a set of linear inequality constraints on the parameter space Θ. Said another way, given a set of strategies to consider as a mixture specification, we can solve for the linear inequality constraints on the choice probabilities θ that provide necessary and sufficient conditions for these choice probabilities to be represented as a probability distribution over the strategies under consideration.

As an example, assume that K = {(a,b), (c,d)} with _ab and _cd as the choice probabilities corresponding to the two choice pairs in K. Consider three decision strategies with z ₁ = [ 1   1], z ₂ = [ 0    0], and z ₃ = [ 0   1]. The mixture specification over all three of these states can be written as the interior of the triangle formed by taking the convex hull of these points in the parameter space Θ. If we were to consider the mixture model of just z ₁ and z ₂ its convex hull would simply be the line segment joining these two points in Θ. Figure 1 presents these different mixture specifications plotted within the parameter space Θ along with the respective linear inequality constraints as a function of _ab and θ _cd. This perspective holds generally in that any mixture specification over a finite number of decision strategies can be represented as a polyhedron in the appropriate (possibly high-dimensional) probability space (e.g., Davis-Stober, 2009).

Figure 1: This figure plots the constraints placed on the parameter space Θ for the three-strategy mixture specification over z ₁, z ₂, and z ₃; as well as the two-strategy mixture specification over z ₁ and z ₂.

The researcher must specify a priori which strategies will be considered as mixture specifications.Footnote ⁴It is important to point out that under this mixture stochastic specification all choice variability is modeled as substantive “shifts” between different strategies, i.e., there is no “error” or “noise” component. Other types of mixture specifications are possible under our framework. One could model a mixture-error ‘hybrid’ specification, where the mixture specification is combined with the low and high-error specifications, by solving for the appropriate constraints on the θ parameters.

2.3 Maximum likelihood estimation

To carry out model estimation for the strategy(ies)-specification pairs, we define the maximum likelihood estimator in the standard way,

(3)

where the parameter space Θ is constrained according to the strategy-specification pair being considered.

If the stochastic specification is either the low or high-error case then θ is constrained to be a function of the single parameter, є, oriented according to the decision strategy being considered, z, and bounded accordingly. For the low and high-error specifications, (3) has a simple closed-form solution (e.g., Bröder & Schiffer, 2003a) with the parameter є estimated as follows,

(4)

where z _ab is the coefficient in z that corresponds to the pair (a,b). Note that the sums are only taken over the elements of z that do not predict guessing. For the low-error specification, let _ab = (1 − min{, .03}) for all choice pairs in z such that a is predicted to be preferred to b, let _ab = min{, .03} for all choice pairs such that b is predicted to be preferred to a, and let _ab = .5 if the strategy represented by z predicts guessing between a and b. For the high error specification, we proceed exactly the same way replacing .03 with .20, i.e., if a is predicted to be preferred to b then _ab = (1 − min{, .20}) and so on. It is routine to show that this estimation method yields the solution to (3) for the low and high-error specifications for any choice of z.

For the mixture case, assume that the choice probabilities of Θ are constrained such that they represent the mixture specification (polyhedron) over the strategies under consideration. The solution to (3) for the mixture cases can then be carried out using standard constrained optimization algorithms.Footnote ⁵For all of the stochastic specifications described above, the constraints placed on the θ parameters form a closed, convex set, thus the maximum likelihood estimator always exists and is unique (Reference Davis-StoberDavis-Stober, 2009).

3 Normalized maximum likelihood

How can we place the different strategy-specification pairs on an “equal footing” in order to carry out model selection and classification? Unfortunately, traditional model selection methods, such as the Akaike Information Criteria (AIC) (Reference Akaike, Petrov and CsákiAkaike, 1973) and the Bayesian Information Criterion (BIC) (Reference Stewart, Brehmer and JoyceSchwarz, 1978), are not appropriate in this situation. Conceptually, the problem lies in the fact that the complexity penalty terms of both the AIC and BIC are simple functions of the number of parameters and thus cannot fully measure the parametric complexity of the stochastic specifications we consider. Within our framework, all pairs comprised of the low-error and high-error specifications would have exactly the same complexity (penalty) term for either the AIC or BIC as both cases have only the single free parameter, є. Yet, the high-error case is able to accommodate a much wider range of data and, in fact, contains the low-error specification as a (greatly constrained) special case! If we consider mixture specifications, the AIC and BIC measures further break down as different mixture specifications may have the same “number” of parameters, but different linear inequality constraints on θ will be able to accommodate data in vastly different ways.

To solve this problem, we will make an appeal to the minimum description length principle (Reference RissanenRissanen, 1978). In contrast to many other methods, such as the Bayes factor, the minimum description length principle does not require the assumption of a “true” data generating distribution or process. As argued by Rissanen (2005), this property is a major strength of the minimum description length perspective, especially in cases where determining or estimating a “true” data generating model is difficult or impossible due to a lack of sample size or fundamental understanding of the phenomenon being observed. Rather, in accordance with Occam’s razor, the minimum description length principle states that the best model of a set of data is the one that leads to the most efficient compression of the data. (Grünwald (2005) provides an in-depth introduction and overview.) Several model selection criteria are derived from the minimum-description-length principle. The most general such derivation is the normalized maximum likelihood (NML) criteria (Reference Barron, Rissanen and YuBarron, Rissanen, & Yu, 1998; Reference RissanenRissanen, 2001) and is defined as follows,

(5)

where L(θ|n) is the maximized likelihood for the observed data n and X is the sample space of the model, i.e., the set of all possible data values. For the case of continuous data, the summation operator in the denominator is replaced by an integral. The NML criteria (5) can be described as a ratio of a model’s goodness-of-fit to its complexity with larger values indicating a superior model. The denominator in (5) is defined as the sum of maximized likelihoods for all possible data points, not just the data that were observed. In this way, the denominator accurately measures the stochastic complexity of a model, incorporating both the size of the parameter space as well as functional complexity (Reference Regenwetter and MarleyMyung, Navarro, & Pitt, 2006). For example, consider two models that provide an equally good fit to a set of observed data. If one of these models fit well many more data points than the other the denominator term in (5) for that model would be quite large and thus, ceteris paribus, the simpler model would be preferred. See Reference Regenwetter and MarleyMyung, Navarro and Pitt (2006) for a tutorial on the NML criteria.

To obtain an NML value for a strategy-specification pair within our framework, we first obtain the maximum likelihood estimate for the observed data, n, via (3) and then use this value to calculate L(|n). This forms the numerator of (5). We then carry out this process for all possible data points in the sample space corresponding to (1) for fixed values of N _ab. Taking the sum over all of these maximized likelihood terms gives the denominator in (5). We then carry out this process for each strategy-specification pair. Finally, we compare all NML values, selecting the strategy-specification pair with the largest NML value. To summarize, our methodology proceeds as follows:

1. 1. Given a set of candidate strategies, assign each strategy its corresponding prediction vector, z _i, and decide which stochastic specifications to consider for each z _i (or set of z _i in the case of mixture specifications).

2. 2. Given a set of observed choice data, n, calculate NML values for all strategy-specification pairs under consideration (including mixture specifications).

3. 3. Select the strategy-specification pair with the largest value of NML.

Calculation of the denominator term in (5) can be computationally difficult. All possible data points can be enumerated when both the number of choice pairs in K and the N _ab terms are relatively small, thereby allowing a direct computation of the NML terms. For cases when this is not feasible, estimation of the denominator of (5) can be carried out via Monte Carlo sampling (Reference Preacher, Cai, MacCallum, Little, Bovaird and CardPreacher, Cai, & MacCallum, 2007). It is important to note that, as the values of N _ab and/or the number of choice pairs in K increase, the larger the sample space becomes and therefore the more Monte Carlo random samples that are needed to estimate (5). We used 10,000 samples per strategy-specification pair for the empirical example in this article (Section 4). When using Monte Carlo sampling, it is often easier to estimate the average maximized likelihood value over the sample space and use this value in lieu of the sum in the denominator of (5) (Reference Preacher, Cai, MacCallum, Little, Bovaird and CardPreacher et al., 2007). This substitution will leave the model ordering unchanged. Throughout this article, we report NML values by taking the natural logarithm of (5).

4 Simulated data example

In this section, we illustrate our methodology with a set of candidate strategies and choice alternatives adapted from Bröder and Schiffer (2003a). We consider the following three decision strategies: Take The Best (TTB) (Reference Gigerenzer, Hoffrage and KleinböltingGigerenzer & Goldstein, 1996), Dawes Rule (DR) (Reference DawesDawes, 1979), and Franklin’s Rule (FR) (Reference DawesGigerenzer & Goldstein, 1999), see Table 2 for descriptions. We consider four choice alternatives each comprised of four binary cues with corresponding validities (denoted v).Footnote ⁶These choice alternatives are displayed in Table 3 where “+” or “–” denote the presence or absence, respectively, of a given cue for that choice alternative. We consider two paired comparisons of these four choice alternatives, i.e., |K| = 2 and each choice pair is labeled “Type I” and “Type II” respectively. Table 3 lists the predictions made by these strategies for both choice pairs. We will encode a prediction of alternative a preferred over b as “1” and b preferred over a as “0”. Therefore, z ₁ = [1     1] is the vector representation of TTB, z ₂ = [0     0] is the vector representation of DR, and z ₃ = [0     1] is the vector representation of FR. Again, these decision strategies and cues are chosen for purely illustrative purposes. Our framework can accommodate any decision strategy that makes predictions on binary (or k-ary) choice data.

Table 2: Decision strategies.

Table 3: Choice alternatives and decision strategy predictions

To illustrate how our methodology maps candidate strategy-specification pairs to individual DMs, we simulated data from 25 hypothetical DMs whose “true” choice probabilities, θ, were uniformly distributed over all possible choice probabilities. We carried out our methodology on the three decision strategies considering: both low and high-error specifications for each strategy, all two-strategy mixture specifications, and the single mixture specification over all three strategies. We assumed that each choice type was presented a total of 30 times each. Table 4 lists the NML values for each strategy-specification pair over the 25 simulated data sets. The optimal NML values are in bold. Due to the relatively small sample space, we were able to completely enumerate all possible data points and calculate the NML values exactly. Each data set yielded a unique optimal strategy-specification pair, although several NML values were close in value for some data sets indicating several “good” alternative models. The complexity terms (denominator in (5)) for the single strategy error specifications were approximately .56, both low and high-error specifications differing in the fifth decimal place. The complexity terms for the two-strategy mixture specifications were 2.015 for both {z ₁, z ₂} and {z ₁, z ₃}, and were 2.014 for {z ₃, z ₃}. The three-strategy mixture had a complexity of 3.05. The raw Matlab ^© code we used for this example is available as supplementary online material (http://journal.sjdm.org/vol6.8.html).

Table 4: NML values for simulated Data.

Figure 2 plots the observed choice proportions of the simulated data and labels each point according to the best-fitting strategy-specification pair for those data. The mixture polyhedron(s) are plotted in this space to give the reader a sense of the geometry of the different specifications. It is interesting to note that the amount of choice variability as well as the relative location of the data influence which strategy-specification pair yields the optimal NML value. The structure of the choice variability also plays a large role in determining which stochastic specification best accounts for the data. If the variability is roughly equal across paired comparisons then two-strategy mixture and single state error specifications perform well. If the choice variability is not uniform across paired comparisons then the three-strategy mixture specification tends to perform well.

Figure 2: Classification of the 25 simulated data points under all stochastic specifications for the TTB, DR, and FR strategies.

To illustrate the differences between using NML as compared to traditional model selection criteria, we calculated BIC values for each strategy-specification pair over all 25 simulated data sets.Footnote ⁷ Table 5 lists these BIC values with optimal values listed in bold, non-unique optimal values are in bold and underlined. The NML and BIC criteria select the same optimal strategy-specification pair for 76% of the simulated data sets. They disagree, however, in two systematic ways. First, several simulated data points are classified as two-strategy mixtures according to BIC, whereas NML classifies them as being best explained via a three-strategy mixture specification. This discrepancy comes from BIC “over-penalizing” the three-strategy mixture by only considering the number of parameters (two in this case) and not taking into account the constraints on that space, as NML does. Said another way, BIC penalizes the three-strategy mixture model as if its parameter space spanned the entire unit square as opposed to spanning only half of it—see Figures 1 and 2. Second, three of the simulated data sets select multiple optimal strategy-specification pairs. In all three cases, a high-error and two-strategy mixture specification have identical optimal BIC values and therefore cannot be distinguished, see Table 5. This problem arises because these two specifications produce identical maximized likelihood values, and, since the BIC criteria considers them equally complex (single parameter models), they are penalized equally. Normalized maximum likelihood, on the other hand, correctly determines that the two-strategy mixture specifications are more complex and thus makes the correct classification.

Table 5: BIC values for simulated Data