2.1 The inference task and the less-is-more effect

I first define the inference task: There exist N objects that are ranked, without ties, according to a numerical criterion. For example, the objects may be cities and the criterion may be population. A pair of objects is randomly sampled and the task is to infer which object has the higher criterion value. When recognition memory is perfect, a person’s information is modeled by the number of objects she recognizes, n, where 0 ≤ n ≤ N. The person’s accuracy is the probability of a correct inference and it is a function of her information, Pr(n). I next define the less-is-more effect.

The less-is-more effect may at first appear to be impossible: Of course, whatever processing can be done with less information (recognizing n ₁ objects), could also be done when adding information (recognizing the same n ₁ objects and an extra n ₂ − n ₁ objects); so, how can less information lead to more accuracy? The catch is that different amounts of information may lead to different processing. For example, when the population of two cities is compared, recognizing the name of one of the two cities enables the recognition heuristic (Reference HickGoldstein & Gigerenzer, 2002):

“If one object is recognized and the other object is not, the recognized object is inferred to have the higher criterion value.”

The recognition heuristic cannot be used when both objects are recognized so that some other inference rule has to be used, such as a linear rule with unit weights (Reference Dawes and CorriganDawes & Corrigan, 1974). The processing done with less information may be more accurate than the processing done with more information. For example, the recognition heuristic uses one cue (recognition) and there are conditions under which using one cue is more accurate than summing many cues (Reference Hogarth and KarelaiaHogarth & Karelaia, 2005; Reference Katsikopoulos and MartignonKatsikopoulos & Martignon, 2006; this point has also been made specifically for the recognition cue by Davis-Stober, Dana, & Budescu, 2010).

To test empirically the occurrence of the less-is-more effect, one can compare the accuracy of (i) two agents (individuals or groups) who recognize different amounts of objects out of the same set (e.g., American cities), or (ii) the same agent who recognizes different amounts of objects in two different sets (e.g., American and German cities).

Pachur (in press) reviewed a number of studies and concluded that there is some evidence for the less-is-more effect in some experiments, but not in others. I agree with this conclusion: Reference HickGoldstein and Gigerenzer (2002) had about a dozen American and German students infer which one of San Diego or San Antonio is more populous, and found that the Germans were more accurate (1.0 vs. .67). They also found that 52 American students were equally accurate (.71) in making 100 population comparisons of German, or American cities. Reference Reimer and KatsikopoulosReimer and Katsikopoulos (2004) had three-member groups of German students perform 105 population comparisons of American cities. Out of seven pairs of groups, the groups who recognized fewer cities were more accurate in five cases, by .04 on the average. Pohl (2006) had 60 German students compare the populations of 11 German, 11 Italian, and 11 Belgian cities. The students recognized more German than Italian cities and more Italian than Belgian cities, and their accuracies had the same order: .78 for German, .76 for Italian, and .75 for Belgian cities. Reference Reimer and KatsikopoulosPachur and Biele (2007) asked laypeople and soccer experts to forecast the winners of matches in the 2004 European national-teams soccer tournament. In 16 matches, experts were more accurate than laypeople (.77 vs. .65). The correlation between the accuracy of 79 laypeople and the number of teams they recognized was positive (.34).

I believe that all of these tests of less-is-more-effect predictions have methodological problems and I will make this point and suggest a new method in Section 4.

2.2 The perfect-memory model

Reference HickGoldstein and Gigerenzer (2002) derived an equation for Pr(n) based on a model of how a person makes inferences, which I now describe. The first assumption of the perfect-memory model is the following:

It is easy to criticize this assumption as it is known that recognition memory is not perfect (Reference ShepardShepard, 1967). Pleskac (2007) and Smithson (2010) proposed models of imperfect recognition memory, and I will discuss them together with a new model, in Section 3.

The following three assumptions specify the inference rules used for the different amounts of recognition information that may be available:

Based on Assumptions (2)–(4), if the person recognizes n of the N objects, she uses guessing, recognition heuristic, and knowledge with the following respective probabilities:

(1)

The last assumption of the perfect-memory model is the following:

Smithson (2010) pointed out that Assumption 5 could be potentially violated, and constructed plausible examples where this is the case.Footnote ¹ Reference Reimer and KatsikopoulosPachur and Biele (2007) reported that the correlation between α and n was .19 and the correlation between β and n was .22. Across ten experiments, Pachur (in press) reported that the average of the absolute value of the correlation between α and n was .27 and the average of the absolute value of the correlation between β and n was .18. In Section 4, I will argue that the estimates of α and β used in these studies are incorrect, and the reported correlations should be interpreted with caution.

From Assumption 5 and Equation (1), it follows that the accuracy of a person who recognizes n objects is given as follows:

(2)

It is straightforward to study Equation (2) and derive the following characterization of the less-is-more effect (Reference HickGoldstein & Gigerenzer, 2002, p. 79):

3.1 An imperfect-memory model

In this model, an experienced object that is recognized is called a hit; an experienced object that is not recognized is called a miss; a non-experienced object that is recognized is called a false alarm; and, a non-experienced object that is not recognized is called a correct rejection. A main assumption of my imperfect-memory model is the following:

Assumption 1 of the perfect-memory model can be obtained from Assumption 6 by setting h = 1 and f = 0. The differences between the other assumptions of the imperfect- and perfect-memory models are due to the fact that the role played by the recognition cue when memory is perfect is played by the experience cue when memory is imperfect. A person with imperfect memory cannot use the experience cue (they have access only to the recognition cue), but let us still define the experience heuristic:

“If one object is experienced and the other object is not, the experienced object is inferred to have the higher criterion value.”

The experience heuristic is a convenient device for analyzing the less-is-more effect. The following is assumed:

Assumption 7 generalizes Assumption 5 of the perfect-memory model because when memory is perfect it holds that A = α and B = β .

Now I specify the processing used for the different amounts of experience information that may be available. There are three types of pairs of objects that can be sampled, according to whether the number of experienced objects in the pair equals zero, one, or two. As in (1), these types occur with respective probabilities g(n_e), r(n_e), and k(n_e). As Pleskac (2007) pointed out, accuracy depends not only on which of guessing, experience heuristic, or experience-based knowledge is used, but also on if each object in the pair is a hit, miss, false alarm, or correct rejection.

For example, assume that object 1 is experienced and object 2 is not experienced. There are four possibilities: (i) object 1 is a hit and object 2 is a correct rejection, (ii) object 1 is a hit and object 2 is a false alarm, (iii) object 1 is a miss and object 2 is a correct rejection, and (iv) object 1 is a miss and object 2 is a false alarm. In (i), the agent uses the recognition heuristic to make an inference because she recognizes only object 1. Because in this case the recognition and experience cues have the same value on both objects, it is as if the agent used the experience heuristic, and her accuracy equals A Footnote ³.

Similarly, Pleskac (2007, p. 384-385) showed that accuracy equals 1 − A in (iv), in (iii), and zA + (1 − z)() in (ii) (z is the probability that an experienced object has at least one positive value on a cue other than experience). Similarly, when the agent has experienced both objects, it can be shown that accuracy equals B if both objects are hits and otherwise. When none of the two objects is experienced, it can be shown that accuracy always equals .

Pleskac interpreted h as the proportion of experienced objects that are recognized and f as the proportion of non-experienced objects that are recognized, and did not derive a simple equation for Pr(n_e). When h and f are interpreted as probabilities, it is straightforward to do so according to the logic above, as follows:

Rewriting this, we get the main equation of the imperfect-memory model:

(3)

where , and

Equation (3) says that the inference task with imperfect recognition memory can be viewed as an inference task with perfect recognition memory where (i) the accuracy of the recognition heuristic α _e equals a linear combination of the accuracy of the experience heuristic A and , and (ii) the accuracy of recognition-based knowledge β _e equals a linear combination of the accuracy of experience-based knowledge B and . It holds that α _e and β _e are well defined in the sense that they lie between 0 and 1.

Figure 1:

The conditions under which the less-is-more effect is and is not predicted for the imperfect-memory model (A is the accuracy of the experience heuristic, B is the accuracy of experience-based knowledge, h is the probability of a hit, f is the probability of a false alarm, z is the probability that an experienced object has at least one positive value on a cue other than experience). For simplicity, the figure was drawn assuming that Kh/(1 − hz) > 0 and h/(1 − hz) < 1, but this is not necessarily the case.

Assume h − f + hfz > 0. Result 1 applies and the less-is-more effect is predicted if and only if α _e > β e. The condition α _e > β _e can be rewritten as f < Kh/(1 − hz), where K = 1 − h(B − )/(A − ). The condition h − f + hfz > 0 is equivalent to f < h/(1 − hz), which, because K < 1, is weaker than f < Kh/(1 − hz). Thus, if f < Kh/(1 − hz), the less-is-more effect is predicted.

The above reasoning also implies that if Kh/(1 − hz) ≤ f < h/(1 − hz), the less-is-more effect is not predicted. Also, if f = h/(1 − hz), then α _e = 0, and the effect is not predicted.

Assume f > h/(1 − hz). Then, it holds that α _e < and Result 1 does not apply. The second derivative of Pr(n_e) equals (1 − 2α _e) + 2(β _e − α _e), which is strictly greater than zero because α _e < and α _e < β _e. Thus, Pr(n_e) is convex, and a less-is-more effect is predicted.

3.2 Full-experience and below-chance less-is-more effects

The predicted less-is-more effect is qualitatively different in each one of the two conditions in Result 2. If (i) is satisfied, Pr(n_e) has a maximum and there exists a n_e* such that Pr(n_e*) > Pr(N), whereas if (ii) is satisfied, Pr(n_e) has a minimum and there exists a n_e* such that Pr(0) > Pr(n_e*)Footnote ⁴. In other words, in (i), there is a person with an intermediate amount of experience who is more accurate than the person with all experience, and in (ii), there is a person with no experience who is more accurate than a person with an intermediate amount of experience. I call the former a full-experience less-is-more effect and the latter a below-chance less-is-more-effect. The effects studied in the literature so far were of the full-experience (or full-recognition) type, interpreted as saying that there are beneficial degrees of ignorance (Reference Reimer and KatsikopoulosSchooler & Hertwig, 2005). The below-chance effect says that there could be a benefit in complete ignorance.

Result 2 tells us that the less-is-more effect is predicted, but not its magnitude. To get a first sense of this, I ran a computer simulation varying A and B from .55 to 1 in increments of .05, and h, f, and z from .05 to .95 in increments of .05 (and N = 100). There were 10² 20³ = 800,000 combinations of parameter values. For each combination, I checked whether the less-is-more effect was predicted, and, if yes, of which type. The frequency of a less-is-more effect type equals the proportion of parameter combinations for which it is predicted. For the combinations where an effect is predicted, two additional indexes were calculated.

The prevalence of a less-is-more effect equals the proportion of pairs (n _e,1, n _e,2) such that 0 ≤ n _e,1 < n _e,2 ≤ N and Pr(n _e,1) > Pr(n _e,2) (Reference Reimer and KatsikopoulosReimer & Katsikopoulos, 2004). I report the average, across all parameter combinations, prevalence of the two less-is-more-effect types.

The magnitude of a less-is-more effect equals the average value of Pr(n _e,1) − Pr(n _e,2) across all pairs (n _e,1, n _e,2) such that 0 ≤ n _e,1 < n _e,2 ≤ N and Pr(n _e,1) > Pr(n _e,2). I report the average, across all parameter combinations, magnitude of the two less-is-more-effect types.

The simulation was run for both imperfect- and perfect-memory (where h = 1 and f = 0) models. The results are provided in Table 1. Before I discuss the results, I emphasize that the simulation assumes that all combinations of parameters are equally likely. This assumption is unlikely to be true, and is made because of the absence of knowledge about which parameter combinations are more likely than others.

Table 1:The frequency, average prevalence, and average magnitude of the full-experience and below-chance less-is-more effects (see text for definitions), for the imperfect-memory model (varying A and B from .55 to 1 in increments of .05, and h, f, and z from .05 to .95 in increments of .05; and N = 100), and for the perfect-memory model (h = 1 and f = 0).

The first result of the simulation is that the imperfect-memory model predicts a less-is-more effect often, abo3ut two-thirds of the time, 29% for the full-experience effect plus 37% for the below-chance effect. The perfect-memory model cannot predict a below-chance effect, and it predicts a lower frequency of the less-is-more effect (50%) than the imperfect-memory model. The second result is that, according to the imperfect-memory model, the below-chance effect is predicted to have higher average prevalence than the full-experience effect. Note also that the distribution of the prevalence of the below-chance effect is skewed: almost 50% of the prevalence values are higher than 45% (the prevalence distribution was close to uniform for the full-experience effect). The third result of the simulation is that the average magnitude of both less-is-more-effect types is small (.01 or .02); for example, in the imperfect-memory model, only about 5% of the predicted less-is-more effects have a magnitude higher than .05.Footnote ⁵ This result is consistent with conclusions from empirical research (Pohl, 2006; Reference Reimer and KatsikopoulosPachur & Biele, 2007; Pachur, in press). I would like to emphasize, however, that even small differences in accuracy could be important in the “real world”, as, for example, in business contexts.

3.3 The accurate-heuristics explanation

In the predictions of the less-is-more effect in Example 2, we had A = B. This seems curious because a necessary and sufficient condition for predicting the effect when memory is perfect is α > β (see Result 1 and Example 1). In fact, Pleskac (2007) has argued that the condition A > B is necessary for the less-is-more effect when memory is imperfect.

The conditions α > β or A > B express that a heuristic (recognition or experience), is more accurate than the knowledge used when more information is available. If α > β or A > B, the less-is-more effect can be explained as follows: “Less information can make more likely the use of a heuristic, which is more accurate than knowledge.” This is an explanation commonly, albeit implicitly, proposed for the effect (e.g., Reference Hogarth and KarelaiaHertwig & Todd, 2003, Theses 2 & 3), and I call it the accurate-heuristics explanation.

Result 2 speaks against the accurate-heuristics explanation because it shows that A > B is neither necessary nor sufficient for predicting the less-is-more effect. The condition for the full-experience effect, f < Kh/(1 − hz), can be interpreted as indicating a small f and a medium h, where f and h can compensate for A ≤ B.Footnote ⁶ The condition for the below-chance effect, f > h/(1 − hz), is independent of A and B, and can be interpreted as indicating a large f and a small h Footnote ⁷ (simulations showed that z has a minor influence on both conditions).

In sum, Result 2 shows that it is the imperfections of memory (probabilities of misses and false alarms) that seem to drive the less-is-more effect, rather than whether the enabled heuristic (the experience heuristic) is relatively accurate or not.

I illustrate the evidence against the accurate-heuristics explanation by using parameter values from the recognition memory literature. Reference Jacoby, Woloshyn and KelleyJacoby, Woloshyn, and Kelley (1989) provide estimates for h and f for the recognition of names.Footnote ⁸ In each of two experiments, a condition of full attention and a condition of divided attention were run. In the divided-attention condition, participants were distracted by having to listen long strings of numbers and identify target sequences. In the full-attention condition, the average value of h was (.65 + .63)/2 = .64, and I used this value as an estimate of a high probability of a hit. In the divided-attention condition, the average h was (.43 + .30)/2 =.37, and this is my estimate of a low hit probability.

As an estimate of a low probability of a false alarm, I used the average value of f in the full-attention condition, (.04 + 0)/2 = .02. I did not, however, use the average value of f in the divided-attention condition as an estimate of a high probability of a false alarm. This value (.11) does not seem to represent situations where recognition accuracy approaches below-chance performance (Reference RoedigerRoediger, 1996). Reference Koutstaal and SchacterKoutstaal and Schacter (1997) argue that high probabilities of false alarms can occur when non-experienced items are “…broadly consistent with the conceptual or perceptual features of things that were studied, largely matching the overall themes or predominant categories of earlier encountered words” (p. 555). For example, false recognition rates as high as .84 have been reported (Reference Roediger and McDermottRoediger & McDermott, 1995), with false recognition rates approaching the level of true recognition rates (Reference Koutstaal and SchacterKoutstaal & Schacter, 1997). I chose a value of .64 (equal to the high estimate of h in the Jacoby et al. experiments) as a high estimate of f. This choice is ad-hoc and serves to numerically illustrate the below-chance less-is-more effect. If .11 were chosen as a high estimate for f, then a full-experience effect would be predicted instead of a below-chance effect (see right graph of lower panel in Figure 2 below).

Figure 2:

Illustrations of conditions under which the less-is-more effect is and is not predicted. In all graphs, N = 100, z = .5 (results are robust across different values of z), A = .8, and B equals .75, .8, or .85. In the two graphs of the upper panel, a full-experience effect is predicted for f = .02 and h = .64 or .37 (the squares denote maximum accuracy). In the left graph of the lower panel, no less-is-more effect is predicted for f = h = .64. In the right graph of the lower panel, a below-chance effect is predicted for f = .64 and h = .37 (the squares denote minimum accuracy).

To allow comparison with the perfect-memory case where predictions were illustrated for α = 8, I set A = .8; B was set to .75, .8, and .85. Results were robust across z, so I set z = .5 . In Figure 2, there are illustrations of predicting and not predicting the less-is-more effect. In the two graphs of the upper panel, the full-experience effect is predicted: Accuracy is maximized at some amount of experience n_e*, between 60 and 80, that is smaller than the full amount of experience N = 100. In the left graph of the lower panel, no less-is-more effect is predicted. In the right graph of the lower panel, the below-chance effect is predicted: Accuracy is higher at no experience n _e,1 = 0 than at a larger n _e,2 > 0, until n _e,2 equals approximately 50.

I now discuss other less-is-more effect predictions in the literature. Smithson (2010) analyzed a perfect- and an imperfect-memory model where knowledge consists of one cue. This implies that A and B are not necessarily constant across n_e, contradicting Assumption 7; on the other hand, Smithson modeled h and f as probabilities constant across n_e, agreeing with Assumption 6. He showed that the less-is-more effect can be predicted even if α ≤ β or A ≤ B. These results speak against the accurate-heuristics explanation. More specifically, Smithson also showed that the prediction of the less-is-more effect is largely influenced by aspects of memory such as the order in which objects are experienced and recognized and not so much on whether, or not, the experience and recognition heuristics are more accurate than recognition-based- or experience-based knowledge.

How can one reconcile Smithson’s and my results with Pleskac’s (2007) conclusion that A > B is necessary for the less-is-more effect when memory is imperfect? There are at least two ways. First, Pleskac studied a different model of imperfect memory from Smithson’s and the model presented here. In Pleskac’s model, recognition memory is assumed to be a Bayesian signal detection process. As a result of this assumption, the false alarm and hit rates are not constant across n_e, thus contradicting Assumption 6 (which both models of Smithson and myself satisfy). On the other hand, in Pleskac’s model A and B are independent of n_e, thus agreeing with Assumption 7 (which Smithson’s model does not satisfy). Second, Pleskac (2007) studied his model via simulations, and it could be that some predictions of the less-is-more effect, where it was the case that A ≤ B, were not identified.

This concludes the discussion of the theoretical predictions of the less-is-more effect. In the next section, I develop a method for testing them empirically.

4.1 What do estimates of α and β in the literature (α _Lit and β _Lit) measure?

Following Reference HickGoldstein and Gigerenzer (2002), the α _Lit of a participant in an experiment has been estimated by the proportion of pairs where she recognized only one object, and in which the recognized object had a higher criterion value; and β _Lit has been estimated by the proportion of pairs where the participant recognized both objects, and in which she correctly inferred which object had a higher criterion value (the definitions are formalized in the result that follows). Result 3 shows what these estimates measure.

(4)

Using the logic preceding the derivation of Equation (3), it also holds that:

(5)

Let also:

(6)

Equations (4), (5), and (6)Footnote ⁹ imply α _Lit = pqB + p(1 − q)A + (1 − p)q(1 − A) + (1 − p)(1 − q)(), and this can be rewritten as in part (i) of the result.

Let R and R ^′ be recognized objects (both randomly sampled), with criterion values C(R) and C(R ^′). Also, assume that the participant infers that C(R) > C(R ^′). Then it holds that:

(7)

As in deriving (5), it holds that

and

R is not experienced, R ^′ is not experienced)=.

But we do not know

R is experienced, ,R ^′ is not experienced)

and

R is not experienced, R ^′ is experienced),

because we do not know which of R and R ^′ has the higher criterion value. We can, however, reason that one of this probabilities equals A and the other one equals 1 − A.

From the above and Equation (7), it follows that β _Lit = p ²B + (1 − p)²() + 2p(1 − p)(A + 1 − A), which can be rewritten as part (ii) of the result.

To complete the proof, I compute p and q. To do this, first let O be a randomly sampled object, and define e = Pr(O is experienced). Let also r = Pr(O is recognized), which, by definition, equals n/N. It holds that:

Solving the above equation for e, we get e = (r − f )/(h − f ).

Note that p = Pr(O is experienced ∣ O is recognized). By Bayes’ rule, this probability equals Pr(O is recognized ∣ O is experienced) × Pr(O is experienced)/Pr(O is recognized), which turns out to be he/[he + f(1 − e)].

Similarly, q = Pr(U is experienced) = Pr(O is experienced ∣ O is not recognized), and this turns out to be (1 − h)e/[(1 − h)e + (1 − f )(1 − e)].

Table 2:Numerical illustration of the difference between α_Lit and α_e, and β_Lit and β_e, based on the average n, α_Lit, and β_Lit for each one of 14 groups in an experiment by Reimer and Katsikopoulos (2004), where participants had to compare the populations of N = 15 American cities. I also set h = .9, f =.1, and z = .5. For two groups, the estimates of α_e were not between 0 and 1. On the average, α_e was larger than α_Lit by .05, and β_e smaller than β_Lit by .04.

In Table 2, I used the average n, α _Lit, and β _Lit for each one of 14 groups in an experiment by Reference Reimer and KatsikopoulosReimer and Katsikopoulos (2004) where participants had to compare the populations of N = 15 American cities. I also set h = .9, f =.1, and z = .5Footnote ¹⁰. To compute α _e and β _e, I followed three steps: First, I computed p and q as in Result 3. Second, I solved for A and B from (i) and (ii) of Result 3, and B = [ β _Lit − (1 − p)(1 + 3p)()]/p ², A = [ α _Lit − pqB − (1 − p)(1 + q)()]/(p − q). Third, I used Equation (3) to compute α _e and β _e.

The difference between α _Lit and α _e, or β _Lit and β _e exceeded .01 in 24 out of 26 cases. The difference was as large as .11. On the average, α _e was larger than α _Lit by .05, and β _e was smaller than β _Lit by .04Footnote ¹¹. I also performed a sensitivity analysis, varying h from .9 to 1 in increments of .01 and f from .1 to 0 in decrements of .01. There were (14)11² = 1694 cases. On the average, α _e was larger than α _Lit by .04, and β _e was smaller than β _Lit by .02. One may expect these differences to increase if h and f are less indicative of a very good recognition memory than they were here.

In fact, correlations between α _Lit and n, or β _Lit and n, are predicted even if A, B, h, and f are constant across n. For example, I computed the correlations between α _Lit and n, and β _Lit and n with the six parameter combinations used in the upper panel of Figure 2, where A = .8, B = .75, .8, or .85, h = .64 or .37, and f = .02 (N = 100). For each n from 0 to 100, I used the equations in the statement of Result 3 in order to compute α _Lit and β _Lit, and then computed their correlations with n.Footnote ¹²

As can be seen in Table 3, correlations can be very substantial, varying from −.59 to .85. The average of the absolute value of the correlation between β _Lit and n is .65 (two correlations were negative and four were positive) and between α _Lit and n is .24 (all six correlations were negative).

Table 3:Numerical illustration of correlations between α_Lit and n, and Litβ_Lit and n, even when A, B, h, and f are constant (N = 100). The average of the absolute value of the correlation between α_Lit and n is .65, and between Litβ_Lit and n is .24.

4.2 A method for testing less-is-more-effect predictions

Based on the points made in the previous paragraph, I claim that, unless it can be established that recognition memory was perfect in an experiment, a correct empirical test of the less-is-more effect in that experiment should not use the estimates of α and β in the literature (α _Lit and β _Lit).

There is one more problem with empirical tests of the less-is-more effect in the literature. The way some of these tests are carried out often provides no evidence for or against any theory of the conditions under which the less-is-more effect is predicted. To provide such evidence, it does not suffice to just check if an effect is found when the conditions in Results 1 or 2 are satisfied: Even if a condition for predicting the less-is-more effect holds, the prediction is not that all pairs of agents that have amounts of information n ₁ and n ₂ such that n ₁ < n ₂ would also have Pr(n ₁) < Pr(n ₂). For example, in the upper left panel of Figure 2, the less-is-more effect is predicted but it is also predicted that an agent who has experienced 40 objects would be less accurate than an agent who has experienced 100 objects. One cannot conclude that “no evidence for the less-is-more effect is found even if a condition that is sufficient for the effect holds”, in the case that a person who has experienced 40 objects is less accurate than another person who has experienced 100 objects.

For example, consider Pohl’s (2006) Experiment 3, which he interpreted as providing “no evidence for a less-is-more effect” (p. 262). For 11 German and 11 Italian cities, he measured the average, across participants, n, α _Lit, and β _Lit. Pohl observed that n was larger in German (11) than in Italian (9.5) cities, and α _Lit = .82, β _Lit = .74 for Italian cities; for German cities, α _Lit was not defined and β _Lit = .79. The less-is-more effect was not found: The accuracy for German cities (.78) was higher than the accuracy for Italian (.76) cities. But this is not evidence against the theory that, under the condition α > β, an effect is predicted: For the particular values of n, α _Lit, and β _Lit, applying Equation (2) does not predict a less-is-more effect, but rather that Pr(n) is higher for German (.79) than for Italian cities (.76), as it was indeed found.

In order to determine whether there is evidence for the less-is-more effect or not from an experiment, Reference RoedigerSnook and Cullen (2006), and Pachur and his colleagues (Reference Reimer and KatsikopoulosPachur & Biele, 2007; Pachur, in press) searched for non-monotonic trends in the best-fitting polynomial to all data points {n, Pr(n)}. This partly addresses the issue I raised above because typically a large number of data points are considered, and it is likely that among them there are some pairs for which the effect is predicted. Remaining problems are that (i) the average prevalence and magnitude of the full-experience less-is-more effect are predicted to be small (see Table 1), and even the best-fitting polynomials of idealized curves are basically monotonic,Footnote ¹³ and (ii) no out-of-sample-prediction criteria were used to identify these polynomials.

I now propose a method for testing the theoretical predictions of the less-is-more effect that avoids the issues discussed above and in the previous paragraph. The method consists of (i) computing the predicted accuracies of pairs of agents (individuals or groups), (ii) comparing the accuracies to determine whether a less-is-more effect is predicted or not, and (iii) checking the predictions against the observations. I first specify what data are assumed to be available.

The computation of the accuracy of an agent, Pr(n_e), given α _Lit, β _Lit, n, N, h, f, and z, is a straightforward, albeit cumbersome, application of Result 3 and Equations (1) and (3):

I now illustrate the method. I use data from an experiment by Reference Reimer and KatsikopoulosReimer and Katsikopoulos (2004) where three-member groups had to perform a population-comparison task with N = 15 American cities. In this research, seven pairs of groups were identified so that (i) the variability in n, α _Lit, and β _Lit across the three group members was “small”, (ii) the difference in the average α _Lit and β _Lit between the two groups in a pair was “small”, and (iii) the difference in the average n between the two groups in a pair was “large” (Reference Reimer and KatsikopoulosReimer & Katsikopoulos, 2004, pp. 1018-1019). I used the average n, α _Lit, and β _Lit for each one of 14 groups (the values are provided in Table 2). I also set h = .9, f =.1, and z = .5 (see comments in Example 3).

In the Reimer-and-Katsikopoulos experiment, the less-is-more effect was observed in five out of the seven pairs (1-5) and not observed in two pairs (6, 7). As can be seen in Table 4, according to the method, the theory of the less-is-more effect, as summarized in Result 2, correctly predicts the effect in four pairs (1, 2, 4) and correctly predicts that there would be no effect in both pairs 6 and 7Footnote ¹⁴ (for one pair (3), the estimates of α _e were not between 0 and 1, and the method was not applied). I also let h vary from .9 to 1 in increments of .01 and f vary from .1 to 0 in decrements of .01. The theory correctly predicted the effect in 402 out of 550 cases, correctly predicted no effect in 203 out of 242 cases, and was not applied in 55 cases. More generally, it should be studied further how robust the results of the method are when there is noise in the parameter estimates. This is a concern because of the nonlinear terms in various equations of the method.Footnote ¹⁵

Table 4:Numerical results of the method with data from Reimer and Katsikopoulos (2004; seven pairs of groups compared populations of N = 15 American cities). The method used the n, α_Lit, and β_Lit of this study (see Table 2), and h = .9, f = .1, z = .5 (see comments in Example 3), to predict Pr(ne). For one pair (3), the estimates of α_e were not between 0 and 1, and the method was not applied. The less-is-more-effect predictions were correct for five pairs (1, 2, 4, 6, and 7) and incorrect for one pair (5).