2.1. Confirmation bias

As noted, confirmation bias is a blanket term for a set of behaviors where are unresponsive or resistant to evidence challenging their currently held beliefs (Klayman Reference Klayman1995; Nickerson Reference Nickerson1998; Mercier and Sperber Reference Mercier and Sperber2017). The models we present will not adequately track all forms of confirmation bias. They do, however, reflect behaviors seen by those engaging in what is called selective exposure bias, as well as those who selectively interpret evidence.

Selective exposure occurs when individuals tend to select or seek out information confirming their beliefs. This could involve avoidance of disconsonant information (Hart et al. Reference Hart, Albarracín, Eagly, Brechan, Lindberg and Merrill2009) or pursuit of consonant information (Garrett Reference Garrett2009; Stroud Reference Stroud and Kenski2017). The study by Chaffee and McLeod (Reference Chaffee and McLeod1973) where participants chose pamphlets to read about an upcoming election is an example of selective exposure bias. While selective exposure has been most frequently studied in the context of politicized information, it need not be. Johnston (Reference Johnston1996) observes it in participants seeking to confirm their stereotypes about doctors. Olson and Zanna (Reference Olson and Zanna1979) find selective exposure in participants’ art viewing preferences. Stroud (Reference Stroud and Kenski2017) gives a wider overview of these and related results.

As will become clear, our models can also represent confirmation bias that involves selective interpretation or rejection of evidence. Recall Lord et al. (Reference Lord, Ross and Lepper1979), where subjects received information both supporting and opposing the efficacy of the death penalty as a deterrent to crime. This information did little to change subjects’ opinions on the topic, suggesting they selectively rejected information opposing their view. Gadenne and Oswald (Reference Gadenne and Oswald1986) demonstrate a similar effect in subject ratings of the importance of information confirming vs. challenging their beliefs about a fictional crime. Taber and Lodge (Reference Taber and Lodge2006) gave participants pairs of equally strong arguments in favor of and against affirmative action and gun control, and found subjects shifted their beliefs in the direction they already leaned. In each of these cases, individuals seemed to selectively reject only the information challenging their views.

As noted, many previous authors have argued that confirmation bias may be epistemically harmful. Nickerson (Reference Nickerson1998) writes that “[m]ost commentators, by far, have seen the confirmation bias as a human failing, a tendency that is at once pervasive and irrational” (205). It has been argued that confirmation bias leads to irrational preferences for early information, which grounds or anchors opinions (Baron Reference Baron2000). In addition, confirmation bias can lead subjects to hold on to beliefs which have been discredited (Festinger et al. Reference Festinger, Riecken and Schachter2017; Anderson et al. Reference Anderson, Lepper and Ross1980; Johnson and Seifert Reference Johnson and Seifert1994; Nickerson Reference Nickerson1998; Lewandowsky et al. Reference Lewandowsky, Ecker, Seifert, Schwarz and Cook2012). Another worry has to do with “attitude polarization,” exhibited in Taber and Lodge (Reference Taber and Lodge2006), where individuals shift their beliefs in different directions when presented with the same evidence.

Further worries about confirmation bias have focused on communities of learners rather than individuals. Attitude polarization, for example, might drive wider societal polarization on important topics (Nickerson Reference Nickerson1998; Lilienfeld et al. Reference Lilienfeld, Ammirati and Landfield2009). For this reason, Lilienfeld et al. (Reference Lilienfeld, Ammirati and Landfield2009) describe confirmation bias as the bias “most pivotal to ideological extremism and inter- and intragroup conflict” (391).

Specific worries focus on both scientific communities and social media sites. Scientific researchers may be irrationally receptive to data consistent with their beliefs, and resistant to data that does not fit. Koehler (Reference Koehler1993) and Hergovich et al. (Reference Hergovich, Schott and Burger2010), for example, find that scientists rate studies as of higher quality when they confirm prior beliefs. If so, perhaps the scientific process is negatively impacted.

It has also been argued that confirmation bias may harm social media communities. Pariser (Reference Pariser2011) argues that “filter bubbles” occur when recommendation algorithms are sensitive to content that users prefer, including information that confirms already held views. “Echo chambers” occur when users seek out digital spaces—news platforms, followees, social media groups, etc.—that mostly confirm the beliefs they already hold. While there is debate about the impact of these effects, researchers have argued that they promote polarization (Conover et al. Reference Conover, Ratkiewicz, Francisco, Gonçalves, Menczer and Flammini2011; Sunstein Reference Sunstein2018; Chitra and Musco Reference Chitra and Musco2020), harm knowledge (Holone Reference Holone2016), and lead to worryingly uniform information streams (Sunstein Reference Sunstein2018; Nikolov et al. Reference Nikolov, Oliveira, Flammini and Menczer2015) (but see Flaxman et al. Reference Flaxman, Goel and Rao2016).

While most previous work has focused on harms, some authors argue for potential benefits from confirmation bias. Part of the thinking is that such a pervasive bias would not exist if it was entirely harmful (Evans Reference Evans1989; Mercier and Sperber Reference Mercier and Sperber2017; Butera et al. Reference Butera, Sommet and Toma2018). With respect to individual reasoning, some argue that testing the plausibility of a likely hypothesis is beneficial compared to searching out other, maybe less likely, hypotheses (Klayman and Ha Reference Klayman and Ha1987; Klayman Reference Klayman1995; Laughlin et al. Reference Laughlin, VanderStoep and Hollingshead1991; Oaksford and Chater Reference Oaksford and Chater2003). Lefebvre et al. (Reference Lefebvre, Summerfield and Bogacz2022) show how confirmation bias can lead agents to choose good options even when they are prone to noisy decision making. ^{Footnote 2}

Another line of thinking, more relevant to the current paper, suggests that confirmation bias, and other sorts of irrational stubbornness, may be beneficial in group settings. ^{Footnote 3} The main idea is that stubborn individuals promote a wider exploration of ideas/options within a group, and prevent premature herding onto one consensus. Kuhn (Reference Kuhn1977) suggests that disagreement is crucial in science to promote exploration of a variety of promising theories. Some irrational stubbornness is acceptable in generating this disagreement. Popper (Reference Popper and Harré1975) is not too worried about confirmation bias because as, he argues, the critical aspect of science as practised in a group will eliminate poor theories. He argues that “… a limited amount of dogmatism is necessary for progress: without a serious struggle for survival in which the old theories are tenaciously defended, none of the competing theories can show their mettle” (98). Solomon (Reference Solomon1992) points out that in the debate over continental drift, tendencies like confirmation bias played a positive role in the persistence and spread of (ultimately correct) theories. (See also Solomon Reference Solomon2007.) All these accounts focus on how irrational intransigence can promote the exploration of diverse theories, and ultimately benefit group learning.

In addition, Mercier and Sperber (Reference Mercier and Sperber2017) argue that when peers disagree, confirmation bias allows them to divide labor by developing good arguments in favor of opposing positions. They are then jointly in a position to consider these arguments and come to a good conclusion. This fits with a larger picture where reasoning evolved in a social setting, and what look like detrimental biases actually have beneficial functions for groups. All these arguments fit with what Smart (Reference Smart2018) calls “Mandevillian Intelligence”—the idea that epistemic vices at the individual level can sometimes be virtues at the collective level. He identifies confirmation bias as such a vice (virtue) for the reasons listed above.

The results we will present are largely in keeping with these arguments for the group benefits of confirmation bias. Before presenting them, though, we take some time to address previous, relevant modeling work.

2.2. Previous models

To this point, there seem to be few models incorporating confirmation bias specifically to study its effects on epistemic groups. Geschke et al. (Reference Geschke, Lorenz and Holtz2019) present a “triple filter-bubble” model, where they consider impacts of (i) confirmation bias, (ii) homophilic friend networks, and (iii) filtering algorithms on attitudes of agents. They find that a combination of confirmation bias and filtering algorithms can lead to segmented “echo chambers” where small, isolated groups with similar attitudes share information. Their model, however, does not attempt to isolate confirmation bias as a causal factor in group learning. In addition, they focus on attitudes or opinions that shift as individuals average with those of others they trust. As will become clear, our model isolates the effects of confirmation bias, and also models learning as belief updating on evidence, thus providing better structure to track something like real-world confirmation bias.

There is a wider set of models originating from the work of Hegselmann and Krause (Reference Hegselmann and Krause2002), where agents have “opinions” represented by numbers in a space, such as the interval $\left[ {0,{\rm{\;}}1} \right]$ . They update opinions by averaging with others they come in contact with. If agents only average with those in a close “neighborhood” of their beliefs they settle into distinct camps with different opinions. This could perhaps be taken as a representation of confirmation bias, since individuals are only sensitive to opinions near their own. But, again, there is no representation in these models of evidence or of belief revision based on evidence.

As noted, we draw on the network epistemology framework in building our model. While this framework has not been used to model confirmation bias, there have been some relevant previous models where actors devalue or ignore some data for reasons related to irrational biases. O’Connor and Weatherall (Reference O’Connor and Owen Weatherall2018) develop a model where agents update on evidence less strongly when it is shared by those with different beliefs. This devaluing focuses on the source of information, rather than its content (as occurs in confirmation bias). Reflecting some of our results, though, they find that devaluation at a low level is not harmful, but at a higher level eventually causes polarization. Wu (Reference Wu2023) presents models where a dominant group devalues or ignores information coming from a marginalized group. Wu’s model (again) can yield stable polarization under conditions in which this devaluation is very strong. ^{Footnote 4} In both cases, and, as will become clear, in our models, polarization emerges only in those cases where agents begin to entirely ignore data coming from some peers.

There is another set of relevant results from epistemic network models. Zollman (Reference Zollman2007, Reference Zollman2010) shows that, counterintuitively, communities tend to reach accurate consensus more often when the individuals in them are less connected. In highly connected networks, early strings of misleading evidence can influence the entire group to preemptively reject potentially promising theories. Less-connected networks preserve a diversity of beliefs and practices longer, meaning there is more time to explore the benefits of different theories. A very similar dynamic explains why, in our model, moderate levels of confirmation bias actually benefit a group. Zollman (Reference Zollman2010) finds similar benefits to groups composed of “stubborn” individuals, i.e., ones who start with more extreme priors and thus learn less quickly. Frey and Šešelja (Reference Frey and Šešelja2018, Reference Frey and Šešelja2020) generate similar results for another operationalization of intransigence. And Xu et al. (Reference Xu, Liu and He2016) yield similar results for another type of model. In our model, confirmation bias creates a similar sort of stubbornness. ^{Footnote 5}

One last relevant set of models find related results using NK-landscape models, where actors search a problem landscape for solutions. March (Reference March1991), Lazer and Friedman (Reference Lazer and Friedman2007), and Fang et al. (Reference Fang, Lee and Schilling2010) show how less-connected groups of agents may be more successful at search because they search the space more widely and avoid getting stuck at local optima. Mason et al. (Reference Mason, Jones and Goldstone2008) and Derex and Boyd (Reference Derex and Boyd2016) confirm this empirically. And Boroomand and Smaldino (Reference Boroomand and Smaldino2023), in draft work, find that groups searching NK-landscapes adopt better solutions when individuals have preferences for their own, current solutions. This is arguably a form of irrational stubbornness that improves group outcomes. (Their models, though, do not involve actors with preferences for confirmatory data the way ours do.)

3.1. Base model

As discussed, our model starts with the network epistemology framework (Bala and Goyal Reference Bala and Goyal1998), which has been widely used in recent work on social epistemology and the philosophy of science. Our version of the model builds off that presented in Zollman (Reference Zollman2010).

There are two key features of this framework: a decision problem and a network. The decision problem represents a situation where agents want to develop accurate, action-guiding beliefs about the world, but start off unsure about which actions are the best ones. In particular, we use a two-armed bandit problem, which is equivalent to a slot machine with two arms that pay out at different rates. ^{Footnote 6} The problem is then to figure out which arm is better. We call the two options A (or “all right”) and B (or “better”). For our version of the model, we let the probabilities that each arm pays off be ${p_{\rm{B}}} = 0.5$ and ${p_{\rm{A}}} = {p_{\rm{B}}} - \varepsilon $ . In other words, there is always a benefit to taking option B, with the difference between the arms determined by the value of $\varepsilon $ .

Agents learn about the options by testing them, and then updating their beliefs on the basis of these tests. Simulations of the model start by randomly assigning beliefs to the agents about the two options. In particular, we use two beta distributions to model agent beliefs about the two arms. These are distributions from 0 to 1, tracking how much likelihood the agent assigns to each possible probability of the arm in question. The details of the distribution are not crucial to understand here. ^{Footnote 7} What is important is that there are two key parameters for each distribution, $\alpha $ and $\beta $ . These can be thought of as tracking a history of successes ( $\alpha $ ) and failures ( $\beta $ ) in tests of the arms. When new data is encountered, say $n$ trials of an arm with $s$ successes, posterior beliefs are then represented by a beta distribution with parameters $\alpha + s$ and $\beta + n - s$ . It is easy to calculate the expectation of this distribution, which is $\alpha /\left( {\alpha + \beta } \right)$ .

Following Zollman (Reference Zollman2010), we initialize agents by randomly selecting $\alpha $ and $\beta $ from $\left[ {0,4} \right]$ . The set-up means that at the beginning of a trial, the agents are fairly flexible since their distributions are based on relatively little data. As more trials are performed, expectation becomes more rigid. For example, if $\alpha = \beta = 2$ , then the expectation is $0.5$ . Expectation is flexible in that if the next three pulls are failures, then expectation drops to $2/\left( {2 + 5} \right) \approx 0.286$ . However, if a thousand trials resulted in $\alpha = \beta = 500$ , three repeated failures would result in an expectation $500/\left( {500 + 503} \right) \approx 0.499$ (which is still close to $0.5$ ). In simulation, if the agents continue to observe data from the arms, their beta distributions tend to become more and more tightly peaked at the correct probability value, and harder to shift with small strings of data.

As a simulation progresses we assume that in each round agents select the option they think more promising, i.e., the one with a higher expectation given their beliefs. This assumption corresponds with a myopic focus on maximizing current expected payoff. While this will not always be a good representation of learning scenarios, it represents the idea that people tend to test those actions and theories they think are promising. ^{Footnote 8} Each agent gathers some number of data points, $n$ , from their preferred arm. After doing so, they update their beliefs in light of the results they gather, but also in light of data gathered by neighbors. This is where the network aspect of the model becomes relevant. Agents are arrayed as nodes on a network, and it is assumed they see data from all those with whom they share a connection.

To summarize, this model represents a social learning scenario where members of a community (i) attempt to figure out which of two actions/options/beliefs is more successful, (ii) use their current beliefs to guide their data-gathering practices, and (iii) share data with each other. This is often taken as a good model of scientific theory development (Zollman Reference Zollman2010; Holman and Bruner Reference Holman and Bruner2015; Kummerfeld and Zollman Reference Kummerfeld and Zollman2015; Weatherall et al. Reference Weatherall, O’Connor and Bruner2020; Frey and Šešelja Reference Frey and Šešelja2020) or the emergence of social consensus/beliefs more broadly (Bala and Goyal Reference Bala and Goyal1998; O’Connor and Weatherall Reference O’Connor and Owen Weatherall2018; Wu Reference Wu2023; Fazelpour and Steel Reference Fazelpour and Steel2022).

In this base model, networks of agents eventually settle on consensus—either preferring the better option B, or the worse option A. If they settle on A, they stop exploring option B, and fail to learn that it is, in fact, better. This can happen if, for instance, misleading strings of data convince a wide swath of the group that B is worse than it really is.

3.2. Modeling confirmation bias

How do we incorporate confirmation bias into this framework? As noted, confirmation bias is varied and tracks multiple phenomena (Klayman Reference Klayman1995). For this reason, we develop a few basic models of confirmation bias that track the general trend of ignoring or rejecting evidence that does not accord with current beliefs. The goal is to study the ways such a trend may influence group learning in principle, rather than to exactly capture any particular version of confirmation bias.

For each round of simulation, after trial results are shared according to network connections, agents have some probability of accepting and updating their beliefs based on the shared results. This probability is based on how likely they believe those results are given their prior beliefs, $\lambda $ . This likelihood is a function of the agent’s current beta distribution parameters, $\alpha $ and $\beta $ , as well as the details of the results, successes, $s$ , per number of draws, $n$ . ^{Footnote 9} An agent calculates $\lambda $ separately for each set of results shared via a network connection. Examples of these probabilities as a function of an agent’s $\alpha $ and $\beta $ values are shown in figure 1.

Figure 1. The probability mass functions of beta-binomial distributions for different values of $\alpha $ and $\beta $ .

Additionally, the model includes an intolerance parameter, $t$ , that impacts how likely agents are to accept or reject results for a given prior probability of those results occurring. The probability of an agent accepting a set of results is ${p_{{\rm{accept}}}} = {\lambda ^t}$ . When $t$ is low, agents are more tolerant of results they consider unlikely, and when $t$ is high they tend to reject such results. For example, suppose an agent thinks some shared results have a $5{\rm{\% }}$ chance of occurring given their prior beliefs (i.e., $\lambda = 0.05$ ). Then, for $t = 1$ , the agent has a probability of accepting ${p_{{\rm{accept}}}} = 0.05$ . For $t = 2$ , the agent is extremely intolerant with ${p_{{\rm{accept}}}} = {0.05^2} = 0.0025$ . ^{Footnote 10} For $t = 0.5$ , the agent is more tolerant and ${p_{{\rm{accept}}}} = {0.05^{0.5}} = 0.22$ . And when $t = 0$ the probability of acceptance is always 1, i.e., our model reverts to the base model with no confirmation bias. Whenever evidence is accepted, agents update their beliefs using Bayes’ rule as described. Agents never reject evidence they generated themselves. ^{Footnote 11} This feature mimics confirmation bias by representing either (i) a situation in which agents are selectively avoiding data that does not fit with their priors, or (ii) engaging with, but rejecting, this data and thus failing to update on it.

Notice that, for a given tolerance $t$ , agents with the same expectation do not typically have the same probability of accepting evidence. For example, $\alpha = \beta = 2$ gives the same 0.5 expectation as $\alpha = \beta = 50$ , but for any $t \ne 0$ , an agent with the former beliefs will be more likely to accept a 1000-test trial with 650 successes. The latter agent finds this data less likely because of the relative strength of their beliefs (see figure 1). In general, stronger beliefs in this model will be associated with a higher likelihood of rejecting disconsonant data. This aspect of the model neatly dovetails with empirical findings suggesting that confirmation bias is stronger for beliefs that individuals are more confident in (Rollwage et al. Reference Rollwage, Alisa Loosen, Hauser, Dolan and Fleming2020).

We consider several different simple network structures, including the cycle, wheel, and complete networks (see figure 2). We also consider Erdös–Rényi random networks, which are generated by taking some parameter $b$ , and connecting any two nodes in the network with that probability (Erdős and Rényi Reference Erdös and Rényi1960). In general, we find qualitatively robust results across network structures. For each simulation run we initialize agents as described, and let them engage in learning until the community reaches a stable state.

Figure 2. Several network structures.