2.1 Individual versus Group Analysis

The mathematical analysis (and the application of the computer programs) is the same for iTET and gTET; however, theoretical interpretations differ. In the case of iTET, it is assumed that a mixture of true preference patterns can arise over the course of many sessions because a person may change personal parameters over time between sessions. Perhaps these parameters change as a result of internal factors (thinking about the task, momentary biological variations producing changes in optimism, mood, etc.) or as the result of external factors (information acquired between sessions, experiences and events that occur between sessions, etc.).

In gTET, it is assumed that a mixture of true preference patterns can arise from individual differences among people, who may have different parameters or different decision rules for making the choices. Such differences could arise from genetic differences or differential experiences that affect personality, risk-taking attitudes, or other individual difference factors.

In both iTET and gTET, it is assumed that variation in response to the same choice problem by the same person in the same brief session (block of trials) is due to random error. In order to give the same response to the same choice problem in the same session, a person must make no errors in reading and remembering the information, evaluating the probabilities and prizes, aggregating the information, comparing the alternatives, remembering the decision, and physically executing the proper motor response to indicate the decision.

It is reasonable to allow that error rates might differ between choice problems. For example, “simpler” choice problems, such as “would you prefer $50 or $20?” seem cases where it is “easier” to be consistent than in more “complex” choice problems, such as “would you prefer a 30% chance to win $100 otherwise receive $1 or instead a 40% chance to win $40 and otherwise receive $20?” Although it seems intuitively reasonable that increasing the amount of information to read, to remember, and to aggregate should increase the rates of error, such intuitions are not assumed into the model. The model allows such hypotheses to be investigated empirically.

In addition to allowing different error rates for different choice problems, it is also possible that the likelihood of an error may depend on a person’s mental state at the moment of decision (Reference BirnbaumBirnbaum, 2018). For example, in iTET, the individual who momentarily becomes a risk-seeker may also become impulsive and thus have a higher error rate when in a risk-seeking state than when in a risk-averse state of mind. In gTET, those people who truly prefer “risky” options might be people with different personalities who have higher error rates than those risk-averse people who prefer “safe” alternatives.

In previous applications of TE models, it has been assumed that the likelihood of an error is independent of a person’s true preference state (e.g., Reference BirnbaumBirnbaum, 2007). Thus, the “new” TET models used here are more general than models used in some previous research, but they include the older models as special cases. It would be a mistake to confuse these newer extensions with their special cases.

2.2 Parameters of TE Models

With two choice problems, there are four possible true preference patterns (RR ^′, RS ^′, SR ^′, and SS ^′), and sixteen possible observed response patterns (SS ^′ SS ^′, SS ^′ SR ^′, …, RR ^′ RR ^′). We desire to estimate the probabilities of the four true preference patterns, which are denoted p _{RR ^′}, p _{RS ^′}, p _{SR ^′}, and p _{SS ^′}, respectively, from the observed frequencies of response patterns. According to EU, no one should have the true preference pattern RS ^′ or SR ^′. Therefore, EU requires that p _{RS ^′} = p _{SR ^′} = 0. Such a combination of responses could occur in EU, but only by error.

Let e represent the probability of erroneously responding “S” given a true preference for R. Similarly, let f represent the probability of making an error (responding “R”) given that a person truly prefers S in the S versus R choice problem. Let e ^′ and f ^′ represent the probabilities of error given that a person truly prefers R ^′ or S ^′ in the S ^′ versus R ^′ problem, respectively. Error probabilities are assumed to fall between 0 and ½, and to be mutually independent.

Figure 1 illustrates how the overt responses depend on the true states and on random errors that may depend on a person’s true preference state.

Figure 1: True and Error model with 2 choice problems and 4 error terms. A true preference for the “Safe” or “Risky” alternative (S or R, respectively) may result in an overt response that contains error. The probabilities of error given a true preference for R or R ^′ in Choice Problems 1 and 2 are denoted e and e ^′, respectively. The probabilities of error given a true preference for S or S ^′ are denoted f and f ^′, respectively. From Reference BirnbaumBirnbaum (2018).

Since there are two choice problems and two error rates for each problem, there are four error rates in this model. Hence, in this situation, the model is termed TE-4 . A special case of this model, denoted TE-2, assumes that e = f and e ^′ = f ^′.

A further special case assumes that all choice problems have the same error rates; that is, e ^′ = e, denoted TE-1. TE-1 has sometimes been called the “constant error,” “tremble” or “trembling hand” model (e.g., Reference Loomes, Moffatt and SugdenLoomes, Moffatt & Sugden, 2002; Reference ConliskConlisk, 1989), since the errors are independent of the choice problem, as if they can be attributed to error between the decision and the response.

2.3 True and Error Model Predictions

According to TE-4, the probability to show the RS ^′ response pattern on both replications is as follows:

(1)

where P(RS ^′, RS ^′) is the theoretical probability to observe RS ^′ response pattern on both replications; p _{SS ^′}, p _{SR ^′}, p _{RS ^′}, and p _{RR ^′}, are the probabilities of the four possible true preference patterns; and the error rates, e, f, e ^′, and f ^′, are as defined in Figure 1. Note that in each of the four possible true preference states, there is a pattern of errors that can produce the observed response pattern. For example, when a person has the true pattern of RR ^′, then that person can respond RS ^′ RS ^′, (RS ^′on two replications) by making no error on the two presentations of the choice between R and S and by making errors on both presentations of the choice between R ^′ and S ^′.

There are 16 equations (including Equation 1) for the 16 possible response patterns. The 16 corresponding observed frequencies (counts) of these response patterns have 15 degrees of freedom (df), because the 16 frequencies sum to the total number of response patterns. In gTET with two replicates in one session, this total is the number of participants; in iTET, where one individual served in a number of sessions, it is the number of sessions for that individual.

The four probabilities of the four possible true response patterns (SS ^′, SR ^′, RS ^′, and RR ^′) sum to 1 (p _{SS ^′} + p _{SR ^′} + p _{RS ^′} + p _{RR ^′} = 1), so they contain only 3 degrees of freedom (df).

In TE-4, there are 4 true pattern probabilities (using 3 df) and 4 error terms, so the parameters of this model consume 7 df, leaving 15 − 7 = 8 df to test the model.

The TE-2 model is the special case of TE-4 in which e = f and e ^′ = f ^′; In this case, there are 6 parameters that require 5 df, leaving 10 df to test the model.

The TE-1 model is the special case in which it is assumed that e = f = e ^′ = f ^′. In this case, there are 11 df remaining.

As noted above, EU is a special case of TET, in which p _{RS ^′} = p _{SR ^′} = 0. EU-4, EU-2, and EU-1 are special cases of TE-4, TE-2, and TE-1, respectively. Each of these models thus has two fewer parameters than the TE model of which it is a special case.

2.4 Index of Fit

The fit of a model to the 16 observed frequencies can be assessed by the Chi-Square formula:

where O _i and P _i are the observed and predicted frequencies (counts) of each cell’s response pattern.

The G index (sometimes called G ²) is similar to χ², but can have theoretical advantages over it:

The G test is equivalent to a likelihood ratio test, and is also asymptotically Chi-Square distributed with the same degrees of freedom as χ².Footnote ²

2.5 Testing TE models and Substantive Theories as Special Cases

The EU-4 model is the special case of TE-4 in which p _{RS ^′} = p _{SR ^′} = 0. The difference in fit between EU-4 and TE-4, χ² diff = χ²(10)−χ²(8), is theoretically distributed as a Chi-Square with 2 df. The same property also holds for G. Similarly, difference between the fit of TE-2 and EU-2 is also theoretically Chi-Square with 2 df, as is the difference in fit between TE-1 and EU-1.

EU-4 might provide a means by which the EU model might be saved from data that might otherwise seem to refute it. In particular, when four error parameters are allowed, it is possible that EU can imply that P(S) > .5 AND P(S ^′) < .5, or vice versa; thus, it could potentially account for data such as in Case D of Table 1 (Reference BirnbaumBirnbaum, 2018).

Previous studies used TE-2, which led to the rejection of EU and CPT (e.g., Reference BirnbaumBirnbaum, 2008). However, by allowing four error terms in TE-4, one might be adopting a more complex error model as a way to rescue a “simpler” or more “rational” model of decision-making. Because TE-2 and EU-4 have the same number of degrees of freedom, one is tempted to compare these to see if EU with four errors might come off better than a model that has fewer errors but rejects EU. Of course, making a scientific decision to prefer one theory over another should depend on more than just comparing indices of fit and numbers of parameters.

But if EU-4 can be rejected in the context of TE-4 it means that one cannot save the simpler decision model even with the extra parameters. Thus, allowing a greater number of parameters to the EU model might (potentially, if the data warrant) either allow the model to be salvaged or (potentially) provide a stronger refutation of it.

2.6 Example: Data for Reanalysis

Table 2 shows the frequency of each response pattern for 107 participants of Birnbaum, Schmidt and Schneider (2017, Experiment 2, Sample 2), each of whom responded twice to each of Choice Problems 1 and 2 above. These data will be used to illustrate the program and some of the output it generates.

Table 2: Data used to illustrate the model and program. From Birnbaum, Schmidt & Schneider (2017, Experiment 2, Sample 2).

3.1 Running the Program

After checking to ensure that the program, TEMAP2.R, and the data file, Example.xlsx, are in the same directory (set as the working directory), run the program. This can be done (with the appropriate path) by the command:

> source(“C:/Users/Name/Docs/TE/TEMAP2.R”)

As set up in the example file, the program will run for several minutes and create 41 new files that contain output from the program.

Three files created by the program contain the original data for each case, parameter estimates of the three TE models (TE-1, TE-2, and TE-4), best-fit predicted values of those data, best-fit Chi-Square index of fit, and the conventional p-value for this value of Chi-Square. A fourth file contains the same information for the assumption of response independence (which can be violated according to TE models when there is a mixture of true preferences within a group of people or within an individual).

The next three files contain Monte Carlo simulated p-values for the three TE models by means of the conservative and refit simulation methods. For each model, the conservative method uses best-fit parameters to the observed data (either maximum likelihood, minimizing G or minimum χ²). These original parameters are used for both simulation of new samples (from the theory) and to calculate the index of fit in each new simulated sample.

The refit procedure uses these same, best-fit parameters to the original data to generate simulated samples; however, it estimates best-fit parameters in each new simulated sample before calculating the index of fit in each sample. The re-fit method always yields the same or better fits in the simulated samples, and therefore leads to smaller estimated p-values; it is thus more likely to reject the null hypothesis (Reference Birnbaum, Navarro-Martinez, Ungemach, Stewart and Quispe-TorreblancaBirnbaum, et al., 2016).Footnote ³

Three files contain results of bootstrapping for the three TE models; these list the lower and upper values corresponding to (bootstrapped) 95% confidence intervals on the estimated parameters for the (restricted) model specified in the data file. Fourteen pdf files are also created for the first case, which graph bootstrapped sampling distributions of the parameters of the restricted model in TE-4 and TE-2. When confidence intervals are desired for the full model as well, one can run the program again with all parameters free, in order to get bootstrapping results for full (unrestricted) models.

Three files contain results of Monte Carlo simulations of the distribution of differences in Chi-Square (or G) comparing the full model to the restricted model for the three TE models. These files contain separate Chi-Squares for full and restricted models, the difference, the conventional p-value for this difference, and the Monte Carlo simulated p-value. Figures of the Monte Carlo simulated distributions (pdf) are also saved for the TE-2 and TE-4 models for the first case.

When a restricted model is specified, as in the example file, three files are produced that summarize predictions and index of fit for both full and restricted models. In addition, a text file containing a summary of the main results of the analysis is generated.

3.2 Data Input in Excel File

The Excel file used for input to the program contains three worksheets. The “READ ME” sheet contains information on how to organize the data and how to specify the inputs. The “Inputs” worksheet contains values that can be adjusted by the user to request that the program analyze one or more of TE-4, TE-2, or TE-1, to specify either G or χ², to allow parameters to be free or fixed, to request Monte Carlo simulations, and to request bootstrapping analysis. The notation in the program is a bit different from the notation used here for the example of the Allais paradox: The notations 0 and 1 are used to denote first or second responses, respectively, which in this example are choice of the “risky (R)” or “safe (S)” alternatives. The notations, a_00, a_01, a_10, and a_11 in the program correspond to p _{RR ^′}, p _{RS ^′}, p _{SR ^′}, and p _{SS ^′}, respectively. To set up EU, fix the values of a_01 and a_10 to 0.

The “participant responses” worksheet contains the data: response frequencies (counts) for the 16 possible response patterns. The first column is the case number. The first case of Example.xlsx contains the data of Table 2. Several cases can be analyzed in the same computer run. Each line represents a different case, which may represent aggregated data for a group of participants (for gTET) or for an individual (iTET).

The R-program is documented by many comments, statements on a line following #. The section beginning with line 2330 is used to create the output of the program, and this section should be easiest to modify by those familiar with R. Comments include suggestions for revising this section to access additional information generated by the program.

The example file, Example.xlsx, has been configured to request only 100 samples to illustrate the program. Once the program is running properly, the 100 on the “Inputs” worksheet of Example.xlsx can be changed to a higher value for better accuracy of Monte Carlo simulation and bootstrapping. Sample results in the next section are based on the setup in Example.xlsx, for the first case (the data in Table 2), except using 10000 instead of 100.

3.3 Selected Results

Table 3 presents the parameter estimates and the index of fit for six models to the data of Table 2, based on minimizing χ² index of fit. The data, best-fit predictions, and parameter estimates are found in the files named “restricted and unrestricted models…”. The Example.xlsx file has been set up so that the “restricted” model in each case is EU, in which a_01 and a_10 are fixed to zero; i.e., p _{RS ^′} = p _{SR ^′} = 0; in the “unrestricted” models (TE), all parameters are free.

Table 3: Parameter estimates and index of fit of six models to the data of Table 2. TE-4, TE-2, and TE-1 are True and Error models with 4, 2, and 1 error rate parameters. EU-4, EU-2, and EU-1 are their respective special cases in which violations of EU are assumed to have zero probability. Entries shown in parentheses are either fixed or constrained.

Table 3 shows that all three of the (unrestricted) TE models fit acceptably, by conventional standards (p > .1), and that all of the models in which EU has been imposed can be rejected (p < .01), comparing the observed χ² to the Chi-Square distribution.

TE-4 does not fit much better than TE-2 or TE-1 (the pairwise differences in fit are theoretically Chi-Square distributed with 2, 3, or 1 df, and all differences fall well below the critical thresholds for significance), so there are no reasons to reject TE-1 in favor of TE-2 or TE-4, but keep in mind that both choice problems used here involve choices between two similar, two-branch gambles. It might be that in other research, TE-2 or TE-4 might be required for more complex choice problems, or cases where one choice problem is “simpler” than the other.

Appendix A presents comparable results when the index G is used instead of χ²; all of the main conclusions remain the same. Appendix B describes an Excel workbook, TE_calcs_2_choices.xlsx, which also fits TE models, and is included in the JDM Website with this article.

3.4 Predictions Versus Data

To gain insight into the performance of a model, it is useful to compare predictions against the empirical data. Tables 4 and 5 show the best-fit predictions of EU-4 and TE-2, which can be compared to the data in Table 2 (The predictions of TE-1, TE-2, and TE-4 were very similar to each other). The most frequent response pattern in Table 2 is the RS ^′ RS ^′ response pattern, which has a frequency of 43. EU-4 predicts only 21 for the frequency of this RS ^′ RS ^′ response pattern, whereas TE-1, TE-2, and TE-4 predict 40.9, 40.9, and 41.5, respectively. Because this pattern can arise only via combinations of errors in EU-4, EU-2, or EU-1, those models under-predict its value and are forced to over-estimate the frequencies of other patterns that involve the same errors such as RS ^′ SS ^′ and SS ^′ RS ^′, which are also much better fit by the TE models.

Table 4: Best-fit predictions of EU-4 for data of Table 2, minimizing χ².

Table 5: Best-fit (min. χ²) predictions of TE-2 for data of Table 2. Predictions of TE-4 are similar and slightly more accurate.

3.5 Independence Model

The assumption of response independence assumes that the probability of each of the 16 response patterns is the product of binary choice probabilities. A standard Chi-Square test of this independence property is provided. The R-program by Reference BirnbaumBirnbaum (2012) performs other tests of iid properties (assumed by random preference choice models); that program should also be run on the data when assumptions of iid are an issue. The TE models do not imply these independence properties in either iTET or gTET, except in special cases (Reference Birnbaum and BahraBirnbaum, 2013): in iTET, independence follows when the individual has only a single true preference pattern, and in gTET, independence follows when all participants have the same true preferences and error rates.

Best-fit predictions and index of fit of the response independence model are included in the file, “predictions of independence…”. The Chi-Square test of independence χ²(11) = 50.2 for the data of Table 2, which is significant. For comparison, TE-1 has the same number of free parameters and, χ²(11) = 9.19, ns. The best-fit predictions of independence (Table 6) imply that the sum of the major diagonal of Table 2 (cases where people are perfectly consistent between replications) should have been only 42.3, whereas the observed value of this sum is 67 in Table 2. By comparison, TE-1, TE-2, and TE-4 predict 65.1, 65.2, or 65.2, so the TE models give a better fit to the finding that people are more consistent than allowed by response independence.

Table 6: Best-fit predictions of response independence for data of Table 2 (Reference Birnbaum, Schmidt and SchneiderBirnbaum, et al., 2017, Experiment 2, Sample 2). This property does not impose EU, nor does it imply symmetry in the table.

3.6 Monte Carlo Simulations

When the sample sizes are small, the theoretical Chi-Square distribution may be only an approximation of the distribution of the test statistics, χ² or G. Monte Carlo methods can be used to simulate these distributions for more accurate p-values.

Figure 2 shows a histogram of 10,000 simulated test statistics under the null hypothesis of TE-2, using the refit method. The observed value of χ²(10) = 9.11 for the empirical data, is shown as the vertical line in Figure 2, which falls well inside the distribution; therefore, TE-2 provides a statistically plausible description of the data. According to the Chi-Square distribution, the probability to exceed 9.11 is 0.52; in the conservative and refit simulations, 87% and 46% simulated statistics exceeded this value. All three TE models had acceptable fits by the Chi-Square distribution and by both conservative and the refit simulation methods. All three EU models can be rejected according to p-values from the three methods; in no case did a simulated value of χ² exceed the value observed in the data via the refit method.

Figure 2: Histogram of Monte Carlo simulated χ² values for the data of Table 2, based on TE-2, using 10000 simulated samples, using the re-fit method. The vertical line at 9.11 shows the empirical value for the original data.

Figure 3 shows the simulated distribution of differences in χ² between TE-4 and its special case, EU-4. In theory, this distribution should be asymptotically Chi-Square distributed with 2 degrees of freedom. For the empirical data (Table 3), this difference is 48.96 − 8.68 = 40.28. By the Chi-Square distribution, this value is significant. This conclusion is confirmed by Monte Carlo simulations, shown in Figure 3: not one of the 10,000 simulations exceeded the observed value, shown as the vertical line in the figure. Therefore, one can confidently reject EU-4 in favor of TE-4. Similar results were obtained within each of the other two TE models: the difference test rejects EU in any of the TE models.

Figure 3: Histogram of simulated differences in χ² between EU-4 and TE-4, using 10000 simulations via the re-fit method. None of the simulated samples yielded a value as great as that observed in the empirical data, shown as the vertical line at 40.28.

3.7 Bootstrapping

The program uses bootstrapping to estimate 95% confidence intervals for the parameters by drawing random samples of the empirical data and refitting parameters in each sample. The results are in the files, “bootstrapped confidence intervals…” To obtain bootstrapping results for the full TE models, one must revise the setup in the Example.xlsx file to let all parameters be free and to specify 10000 samples.

For the TE-2 model, the estimated value of p _{SR ^′} is 0.65, with a 95% confidence interval from 0.53 to 0.76. Figure 4 shows the bootstrapped distribution for this parameter (p _{SR ^′}) under TE-2. According to EU, p _{SR ^′} should be zero; however, the bootstrapping results provide confidence that it exceeds 53%. If we accept the assumptions of the bootstrapping and of TE-2, we would conclude with 99% confidence that more than half of those tested violated EU with this SR ^′ pattern of responses.

Figure 4: Bootstrapped density function for the parameter, p _{RS ^′} based on TE-2, estimated from 10,000 samples from the data of Table 2.

Reference EfronEfron (2012) has derived theoretical relationships between bootstrapping distributions and Bayesian posterior distributions under particular non-informative priors and shown empirical cases where there is good agreement between parametric bootstrapping and Bayesian posterior distributions (given those priors).

A second set of data is also included in the Example.xlsx file: data from Reference BirnbaumBirnbaum (2007, Experiment 1, Series A) for 200 participants who chose between S = ($1M, 0.11; $2, 0.89) and R = ($2M, 0.10; $2, 0.90), and who chose between S ^′ = ($1M, 0.10; $1M, 0.01; $2, 0.89) and R ^′ = ($2M, 0.10; $2, 0.01; $2, 0.89). Note that S ^′ = S and R ^′ = R, except for coalescing (if we combine branches of the gamble leading to the same consequences by adding probabilities, the choice problems are equivalent). These data had previously been analyzed by Reference BirnbaumBirnbaum (2008, p. 483) using TE-1, with the conclusion that neither CPT nor EU can account for the results. Reanalysis via TEMAP2.R shows that the main conclusions do not change when TE-2 or TE-4 are fit to the data; namely, we can reject CPT because it implies that people should make the same responses in both choice problems but they apparently do not, even allowing for 4 error terms. Therefore, the cases against CPT and EU have been made stronger by the reanalysis.