4.1 Descriptive data analysis

We initially consider the success rate (choice of the queue with the higher profit, with ties excluded) across treatments. Of all the decisions made in the treatment without any time limitation (NTL) only 73% is optimal. This rate decreases to 68% when 10 seconds of time limitation is introduced and as the limitation becomes more stringent (5 seconds) it drops to 65%. Hence, looking at the aggregate data immediately shows that time limitation impairs decision performance.

In order to gain more insight into the subjects’ behavior, we deepen our analysis by examining the success rate when it is optimal to join each queue separately. The first row of Table 1 presents the success rates of the trials for which it is optimal to join the fee-free queue. In other words, the trials for which the profit of joining the slower with no entry fee queue (π(NEF)) is higher than the profit of joining the faster with an entry fee queue (π(EF)). The second row gives the complementary rates concerning the trials where it is optimal to join the faster queue. The success rate increases as the time limitation is relaxed even when we consider trials separately depending on the identity of the optimal queue. However, a comparison between the rows of Table 1 shows that in each treatment, the success rate is higher when the optimal decision is to join the queue with no entry fee. This observation suggests that there may be a bias to join the queue without an entry fee.

Table 1: Success rates across treatments

To attain a finer grain of analysis, we further examine success rates by introducing an additional criteria on top of the identity of optimal queue. The new criteria is the identity of the shorter queue. Excluding the cases where both queues have the same length or are equally profitable, we have four categories of task variants whose success rates are reported in Table 2, where the length of a queue is denoted by |·|.

Table 2: Success rates across categories of variants

The best performed variant category is the one given in the first cell of Table 2, where the optimal decision is to join the no entry fee (NEF) queue, which is also shorter. The second best performed variant type lies in the second cell on diagonal. This time, the faster queue with entry fee (EF) is more profitable and shorter. In the off-diagonal cells, the success rate drops considerably. Thus the better performed task variants are the ones in which it is optimal to join the shorter queue. What one might deduce from this observation is that there may be a bias to join the shorter queue.

The following subsection introduces the mixture model. A mixture approach is used here to verify whether there are subjects who efficiently use the information they can extract, and thus make the optimal queueing decision, in contrast to subjects who behave inefficiently.

4.2 The mixture model

Let us assume that there are G different types of decision maker in the population, denoted by the subscript g. Types differ in the decision rules adopted, that is, in the variables they consult when choosing their preferred queue. Let i indicate the subject and τ ∈{5sec, 10sec, NTL} denote the experimental treatment. In each trial, subject i is faced with the choice between two queues: a slower queue with no entry fee (NEF) and a faster queue with entry fee (EF).

If we let d^{τ *} _igt be the latent dependent variable representing subject i’s propensity to choose queue NEF in treatment τ and trial t, subject i’s decision could be formulated as follows:

(1)

Here, γ^τ_g is a type-specific intercept; X _it is a vector of explanatory variable describing the characteristics of the two queues and β^τ_g is a vector of coefficients on such variables; δ^τ_ig is a subject-specific time-invariant intercept, which follows a Normal distribution with mean 0 and variance σ_g^{τ 2}; finally, ε^τ_ig is a Standard Normal distributed idiosyncratic error term.

We do not observe d ^{τ *}_igt directly, but we observe whether subject i chooses the NEF queue in a specific trial. In other words, we observe whether her propensity to choose NEF queue is positive. This relationship can be mathematically formulated by a {−1,1} indicator as follows:

This is the well-known random-effects probit model, whose assumptions lead to subject i’s likelihood contribution, given that she is of type g∈ 1,…,G, being

(2)

Here, Φ[.] is the Standard Normal Cumulative Distribution Function and φ(δ^τ_g;0,σ^{τ 2}_g) is the Normal Density Function with mean 0 and variance σ^{τ 2}_g, evaluated at δ^τ_g.

Our aim here is to isolate types, i.e., groups of subjects who adopt similar decision rules when choosing between NEF and EF queues. For this purpose, we adopt a finite mixture model approach and assume that there are only two types (G=2): (i) “profit maximizer”, who uses all the relevant information and decides rationally, as suggested by the theory; (ii) “naïve”, who uses the provided information in a less-than-efficient way. Note at this point that we classify any behavior that is not rational as naïve and do not further characterize it by isolating different decision rules used by non-rational subjects. The reason is that we are primarily interested in the impact of time limitation on decision performance. Moreover, deepening the investigation of non-standard behaviors would require a much larger pool of subjects in order to attain a robust analysis.

We assume that each subject is either profit maximizer or naïve, and does not change type within a treatment. As data from each treatment are analyzed separately, the mixture model hypothesis made here does allow subjects to change type (decision rules) but only across treatments. Verifying whether subjects change type and understanding the evolution of decision rules across treatments are indeed among the main scopes of our analysis.

The likelihood contribution of subject i in treatment τ is then

(3)

Here, π_g, termed “mixing proportion”, represents the fraction of the total sample who are type g∈{prof.max., naïve}, so that ∑_gπ_g=1. The mixing proportions are estimated along with the other parameters of the model by maximizing the full sample log-likelihood,

(4)

The mixture model is estimated using the method of Maximum Simulated Likelihood for each treatment τ ∈{5sec, 10sec, NTL} separately. In each component g of the mixture, integration over δ^τ_g is performed by simulation using 100 draws for each subject based on Halton sequences (Train [2009]).

4.3 Estimation results

The results from the maximization of Equation (4) are reported in Table 3. For each treatment, there are two columns displaying the parameter estimates of the model for each type included in the mixture. The behavior of a profit maximizer is captured by the difference in profits of the two queues (Δ(profit)=π(NEF) − π(EF)), which we use as the only explanatory variable. On the other hand, the sub-optimal behavior of a naïve decision maker is modeled by means of the average waiting times and the lengths of the two queues, and we also control for the entry fee level of the EF queue.

Table 3: Maximum simulated likelihood estimates of the mixture model’s parameters

The estimated mixing proportion, π _g, is statistically significantly different from 0 for both types in all treatments. This indicates that the two types of systematic behavior can be clearly separated. Furthermore, when the time constraint becomes more stringent, the fraction of profit maximizers decreases and thus the decision performance impairs. When no time limitations are imposed, 65% of subjects are estimated to be profit maximizer. This ratio declines to 50% under the loose time constraint of 10 seconds. Finally, there seem to be mildly more naïve subjects than profit maximizers in treatment 5sec.

Our results show that the coefficient on the variable of interest for the profit maximizer, i.e., Δ(profit), is of the expected sign and statistically significant in each treatment (^***, ^** and ^* denote p-values <0.01, <0.05 and <0.10, respectively). It amounts to saying that subjects of this type use the difference in profits as their decision criterion, and consequently join the queue that provides higher profit in each treatment. Also the naïve behavior appears to be consistent across treatments. This type’s decision criterion seems to include the length of the two queues and the entry fee but not the information on average waiting times. In treatment 5sec, however, in addition to the previously named variables, the coefficient on the NEF queue’s average waiting time is also significant but only slightly so. Furthermore, all the significant variables are of the expected sign. A possible explanation for naïve subjects’ behavior could be that they filter the available information, concentrating only on a subset that they perceive as important. According to this explanation, the information on average waiting times is apparently seen to be relatively less important. An alternative explanation can be that some naïve subjects opt for a simpler strategy (for example, that of following the shorter queue or joining the no entry fee queue, or even a mixture of the two), rather than analyzing the situation normatively. We cannot clearly determine which explanation is more plausible since, as mentioned earlier, we classify any non-rational behavior as naïve.

Note that a mixture model assigns subjects to types probabilistically. Therefore, it does not specify which subject is assigned to which type directly. Furthermore, the model is run separately for each treatment. This implies that the model does not help us determine whether a subject assigned to a specific type in one treatment is also assigned to the same type in the other treatments. The next subsection investigates this issue and examines how behaviors evolve across treatments.

4.4 The evolution of decision rules

We start investigating the evolution of decision rules by calculating for each subject the posterior probability of being a specific type in each treatment τ ∈{5sec, 10sec, NTL}. We derive these probabilities using Bayes’ rule and the estimation results from our mixture model (see Table 3). Subject i’s posterior probability of being type g∈{prof. max., naïve} in treatment τ is given by

(5)

where obs^τ_i represents the observations collected from subject i in treatment τ. In practice, π^τ_g, l ^τ_ig and L ^τ_i are replaced by their estimated counterparts, obtained by maximizing Equation (4) from treatment τ data. Obviously, subject i’s posterior probability of being naïve type is obtained by pp ^τ _i,naïve=1−pp ^τ_i,prof.max., for all τ.

The histograms of the posterior probabilities of being profit maximizer type are displayed in Figure 1. The resulting posterior probabilities are consistent with the mixing proportions estimated by the mixture model. In treatment 5sec, the naïve type is mildly preponderant. When the time allowance is 10 seconds, the posterior probabilities of being one of the two types are almost equal. With no time limitations, the naïve type is decidedly recessive. Most of the subjects are concentrated at the extremes of the distributions. This finding testifies that our mixtures are rather powerful at segregating subjects, except for a small number of them for whom there is some uncertainty. We assign subjects to types according to the maximum posterior probability. Figure 2 shows the cumulative percentage of subjects assigned to a type with maximum posterior probability less than the probability indicated on the horizontal axis, for each treatment. The figure confirms that the power of our mixture model at segregating subjects is quite impressive: 60%, 70% and 85% of them are assigned to a type with posterior probability larger than 0.90 in treatment 5sec, 10sec and NTL, respectively. Overall, the assignment to a type is remarkably good in the treatment with no time limitation, only marginally less in the other two cases.Footnote ¹

Figure 1: Histograms of posterior probabilities of being profit maximizer type.

Figure 2: Cumulative proportion of subjects assigned to a type with maximum posterior probability < posterior probability indicated on the horizontal axis, by treatment.

Having assigned each subject to a type in each treatment, now we are ready to consider subjects’ profiles throughout the experiment. We have overall eight possible profiles since there are three treatments and two types in each treatment. Table 4 reports proportions for these eight profiles. Previous works (Stiensmeier-Pelster and Schuuml;rmann,Verplanken [1993]) suggest that individuals exhibit differences in how they react to time limitation. Table 4 not only supports this idea but also provides further evidence of heterogeneity in the way that subjects change their reactions due to different levels of time limitation.

Table 4: Behavioral profile proportions

The most popular profile (accounting for 30% of our sample) is the one where subjects are assigned to the naïve type in treatments 5sec and 10sec, but to the profit maximizer type in treatment NTL (second row of Table 4). When there are time limitations, 30% of our sample fails to make the optimal decision but manages to do so when no limitation is imposed. A possible explanation for this behavior could be that the given time allowances are not long enough to think thoroughly and evaluate which queue is more profitable. However, when time limitations are removed, subjects can take the necessary time and make the optimal decision. Another possibility is that it is not the tightness of the time allowances (especially for treatment 10sec) that causes these subjects to perform badly in treatments 5sec and 10sec but the presence of a limitation tout court . Under time limitation, they might panic and use their time inefficiently, therefore fail to follow the optimal decision strategy. We postpone the investigation of this issue to the next subsection, where we consider decision times.

Table 4 reveals that the second most popular profile, representing 29% of our subject pool, is being profit maximizer type in each treatment. These subjects behave consistently throughout the experiment, and the different time limitations do not seem to affect their making rational decisions. The other profile that is consistent throughout the experiment is the one in which subjects are assigned to the naïve type in each treatment. It represents 11% of our sample. In total 40% of the subjects behave consistently and do not change type across treatments. This amounts to saying that time limitation does not have any sort of effect on the performance of these subjects.

One possible explanation that might account for the results presented in Table 4 holds that people are diversely able/willing to pursue optimal information processing. Eleven percent of the sample never implements the optimal strategy, while 30% is able to do so only when there is no time limitation. Moreover, 29% of our subjects is able to pursue the optimal strategy under any treatment condition and 18% are able to do so except in treatment 5sec.

This explanation accounts not only for our 4 most popular types, which make up 88% of all subjects, but can also be viewed as an implication of the results by Stiensmeier-Pelster and Schuuml;rmann. They show that, when coping with time pressure, some subjects accelerate their information processing while others adapt by filtering the information. Those who manage to accelerate under a certain time limitation, say 10sec, may implement the optimal strategy since they are able to optimally process information at a faster pace. However, those who cannot accelerate may filter the information, and focus only on a subset of it that is perceived as the most important. This focus, in turn, may make them fail to pursue the optimal strategy not only in treatment 10sec but also in the 5sec one. Furthermore, this explanation chimes nicely with the hierarchical responses argument of Payne et al. [1988]. People first engage in acceleration and try to respond by working faster. If the pressure is too high and acceleration does not suffice, they may next filter the available information and consider only a subset of it. The results presented in Table 4 could be interpreted as follows: our subjects are diverse in their ability or willingness to switch from acceleration to filtration. Some filter always, some others switch from acceleration to filtration whenever there is a time limitation (treatments 10sec and 5sec) and some switch only when the limitation is too stringent (treatment 5sec). Finally, there are also those who can cope with time limitation without changing strategy.

In the next subsection, we analyze decision times to verify whether profit maximizers adapt to time limitation by acceleration. Moreover we investigate whether the impairment of decision performance is due to the tightness of time allowances or due to (the stress caused by) the presence of a time limitation.

4.5 Decision times

In treatment 5sec, 13 out of 97 subjects failed to complete the task only in one trial, 2 subjects did so in two trials and only one subject in three trials; whereas, in treatment 10sec, 7 subjects failed to do so only once. Thus, we have a total of 27 missing observations out of 11640 (97 subjects × 120 trials) data points (that is, only 0.2% of data are missing). In these few cases, for the tables and the tests reported in this subsection, we have replaced the missing decision times with the upper time limit. Even if we neglect these missing observations, the reported tests’ results do not alter.

Table 5 presents descriptive statistics of decision times across three treatments and reveals that subjects use more time as time limitations are relaxed, on average. Paired t-tests confirm that these differences are statistically significant.Footnote ² We already know that subjects perform best in the no time limitation treatment (see Table 3), and Table 5 reveals that the average decision time in this treatment is around 8.3 seconds. Under a mild time limitation (10sec), however, subjects use only one-third of the given time allowance, on average. This indicates that the presence of a time limitation puts a great deal of subjects under pressure and hinders them from using the given time efficiently. Likewise, under the stringent time limitation of 5 seconds, subjects use only half of the given time, on average.

Table 5: Summary statistics of decision times

We deepen our analysis by examining how decision times of profit maximizer and naïve subjects change across treatments. The descriptive statistics given in Table 6 show that our previous observation that subjects take more time to decide when the limitations are relaxed holds regardless of types. Furthermore, profit maximizers spend more time than naïve subjects no matter what the time limitation is. In fact, a two-sample t-test with unequal variances, whose statistics and p-values are reported in the table, confirms that regardless of the treatment we can reject the hypothesis that both types spend the same amount of time, on average, to arrive at a decision. Thus, a naïve subject uses a decision strategy that is faster relative to the one used by a profit maximizer.Footnote ³

Table 6: Summary statistics of decision times by types

In the previous subsection we have seen that there are mainly 4 common profiles in our population (see Table 4). Thirty per cent of subjects can implement the optimal strategy when there is no time limitation, spending 9 seconds, on average. However, when under the mild time limitation of 10 seconds — which is more than what they spend under no limitation — they use only a quarter of the given time (or one-third of what they use under treatment NTL) and fail to implement the optimal strategy. Thus under a mild time limitations, 30% of subjects seem to switch to a strategy that requires less time but impairs decision performance. Such an alternative strategy may be pursued, for example, by filtration, following the shorter queue or joining the queue with no entry fee. Another 18% of subjects show a similar pattern, but they switch to an alternative only under the stringent time limitation of 5 seconds. These subjects spend on average 4 seconds (1.5 times more than the previously mentioned group) and implement the optimal strategy in treatment 10sec. One could interpret this result by using the hierarchical response argument of Payne et al. [1988]: these subjects adapt to time limitation first by accelerating but when the pressure is too high and acceleration does not suffice, they use filtration or another simpler strategy.

An interesting observation concerning the subjects who switch strategy under time limitation is that they show this behavior even though the given time allowance is more than what they spend before switching. As noted earlier, profit maximizers arrive at a decision in about 9 seconds under treatment NTL. Although in treatment 10sec they still have enough time to pursue their strategy, almost 44% (=(30+7)/(30+7+18+29), see Table 4) of them switch and fail to pursue the optimal strategy. Likewise, profit maximizers of 10sec treatment make their decisions in about 4 seconds. In treatment 5sec, almost 39% (=(1+18)/(1+18+1+29), see Table 4) of them alter their strategy of treatment 10sec even though they still have enough time to follow it. Hence what impairs subjects’ decision performance is apparently not the tightness of time constraint but rather the existence of such a constraint.

The other two common profiles do not involve any switches. The one that assigns subjects to the profit maximizer type in each treatment is adopted by 29% of the population. These subjects spend less time under time limitation but still manage to pursue the optimal strategy. Thus they seem to adapt to time limitation by acceleration. Finally, 11% of subjects are assigned to the naïve type in each treatment. They are not willing or able to implement the optimal strategy even in the absence of time limitation, and the presence of such limitations does not impair their performance.