Passive disapproval of norm violators

Consider a very common situation: you need to cross the street, there are no cars or police around, but the crosswalk sign says ‘don't walk’ and there are several people waiting for it to change. You know you are supposed to wait. You also expect that if you break the norm and cross the street, the bystanders will likely disapprove of you. However, you are in a rush. What do you do?

To approach this question theoretically, consider a focal individual who can either follow the injunctive norm and wait for the crosswalk light to turn green (x = 1) or jaywalk (x = 0). [In the models below, an injunctive norm is a behaviour to which at least some individuals assign some positive normative value.] Let b be the expected net material benefit of crossing the street rather than waiting. (The parameter b can also account for a cost of being observed by the police or being hit by a car when jaywalking.) Let v ⁺ be an intrinsic benefit of following the norm and v ⁻ the intrinsic cost of violating it. The net normative value v = v ⁺ + v ⁻ can be viewed as the strength of norm internalization (Gavrilets & Richerson, Reference Gavrilets and Richerson2017). Let p be the focal individual's estimate of the frequency of such people, e.g. based on previous observations. I posit that an individual violating the norm assumes that others who do follow it disapprove of his behaviour if they observe it (Fehr & Schurtenberger, Reference Fehr and Schurtenberger2018). The anticipated disapproval imposes an internal psychic cost on the norm violator even if the disapproval carries no direct cost. Assuming that this psychic cost increases with the anticipated number of people who disapprove, I define it as κp, where parameter κ is the maximum normative cost of passive disapproval by others. Then the utility of following the norm is u ₁ = v ⁺ while that of violating it is u ₀ = b − v ⁻ − κp. The individual is predicted to comply with the norm if u ₁ > u ₀ which is equivalent to a condition that their normative value v > v* where a threshold v* for compliance is

(1)$$v^\ast \, { = } \, b-\kappa p.$$

Note that an individual with a low normative value v relative to the potential material benefit b will still comply with the norm if the expected normative cost of disapproval κp is high enough. The latter increases with the estimated frequency p of people following the norm.

Consider now a population of individuals repeatedly and simultaneously facing the same dilemma. If all individuals are identical in their material and normative values and costs b, v, κ and everybody is able to estimate the previous frequency p of norm-compliant types and utilities u without errors, everybody will make the same decision and the population will move to a state with p = 0 or p = 1 in just one step. That is, the norm will not be obeyed at all or everybody will comply.

Naturally, individuals in the population can differ in b, v, κ, and their estimates of p. Let the normative value of compliance v have a certain distribution in the population with the corresponding cumulative distribution function (c.d.f.) F (z). For now, assume that all individuals have exactly the same values of b and κ and are able to estimate p precisely. Given b, κ and p, the frequency of individuals with v < v*, who, thus, will not comply, is F (v*). Therefore, the frequency of individuals who will choose to comply with the norm is

(2)$$p' = 1-F\lpar {b-\kappa p} \rpar .$$

Recursive equation (2) describes the dynamics of p in the population. Frequency p always evolves to an equilibrium. The equilibrium values of p can be found from the equality p* = 1 −F (b −κp*). There can be several equilibria and which one is eventually approached depends on initial conditions. An equilibrium p* is locally stable if κf (b − κp*) < 1 and is unstable otherwise. Here f is the probability density function corresponding to F (i.e. f = dF/dv). Given a specific c.d.f. F, one can study the corresponding dynamics analytically, graphically or numerically. A particularly illuminating method, which I will use below, is to plot ‘bifurcation diagrams’ which summarize the dependence of equilibria and their stability of parameters and initial conditions.

Uniform distribution of v. Assume first that v has a uniform distribution between 0 and v _max. Assume also that b > v _max (so that no one is willing to comply if nobody else is doing it, i.e. if p = 0) and that κ > b (so that, everyone complies if everybody else is complying, i.e. p = 1). Then there is a threshold initial frequency $\tilde{p} = {{{b-v}_{max}} \over {\kappa v_{max}}}$, and the population will converge to a state where the norm is lost (i.e. p → 0) if the initial frequency of compliance p < p̃, but it will ‘fix’ it (i.e. p → 1) if p > p̃ (see the Supplementary Information, SI). Decreasing the normative cost of disapproval κ or increasing material benefit b of not complying decreases p̃ and makes fixing the norm easier. In this model, the population quickly becomes homogeneous in its behaviour in spite of substantial variation in individual preferences.

Log–normal distribution of v. Alternatively, assume that the distribution of v is log–normal with mean v and variance σ ² (see the SI). One cannot find the equilibria of equation (2) and check their stability explicitly but it is straightforward to do it numerically.

Figure 1 shows the corresponding equilibrium values of p for different values of the average normative value v̅, normative cost κ and standard deviation σ. [In the terminology of the dynamical systems theory (e.g. Glendinning, Reference Glendinning1994), each subgraph in this figure is a ‘bifurcation diagram’ with σ being a ‘bifurcation parameter’.] The graphs show that the norm can be stably maintained at high frequencies and that the system can have up to two locally stable equilibria separated by an unstable one. Multiple equilibria seem to appear if v̅ + κ > b > v̅ and σ is small enough. Even with a high average normative value of compliance v̅, the population can still be at the no-norm state (e.g. top row, right, where v̅ = 0.9, but p is close to 0). Alternatively, even with a low average normative value v̅ the population can still exhibit high compliance (e.g. the bottom row, left, where v̅ = 0.4, but p is close to 1). The stability of these equilibria is assured by the self-fulfilling expectation of disapproval by the majority of others. Increasing standard deviation σ increases the norm frequency p if v̅ is low, but can decrease it when v̅ is large. Increasing the normative cost κ of (passive) disapproval increases the likelihood of multiple equilibria. Figures S2 and S3 in the SI explore the dependence of equilibrium values of p on v̅ and κ in more details.

Figure 1. Equilibrium values of frequency p for the model with passive disapproval of norm violators (predicted by equation (2)) when the distribution of v in the group is lognormal with mean v̅ and standard deviation σ. Different columns correspond to different values of v̅. Different rows correspond to different values of the maximum cost of disapproval κ. Standard deviation σ is used as the bifurcation parameter. Filled diamonds are stable equilibria. Open diamonds are unstable equilibria separating the two stable ones. Parameter b is set to 1 without loss of generality.

The location and stability of equilibria also depend on the shape of the distribution of v in the population. Figures S4–S6 in the SI show the corresponding bifurcation diagrams for three additional distributions of v: a normal distribution, a Laplace distribution and a logistic distribution, respectively. Although the overall patterns are similar, the specific values of parameters at which the structure of equilibria change can be different.

All four distributions of v considered so far were unimodal. Figure S7 in the SI corresponds to a bimodal distribution of v which may describe a situation when the focal population is a mix of two subgroups with different distributions of normative values. Note that bimodal distributions of normative values within a single population was predicted in Gavrilets and Richerson's (Reference Gavrilets and Richerson2017) evolutionary model while Kimbrough and Vostroknutov (Reference Kimbrough and Vostroknutov2016) demonstrated it empirically in an experimental economic game. In the case of bimodal distributions there can be up to three simultaneously stable equilibria. When the two subgroups are close to each other in their values, the structure of equilibria is naturally similar to that when the distribution of v is unimodal. At intermediate distances between the two subgroups and small σ, there appears a new equilibrium close to p = 0.5. At larger distances, the range of existence and stability of this equilibrium greatly expands while those of equilibria with small and large p shrink. Convergence to equilibria is typically quite fast – a few time steps – as illustrated in Figures S8–S10 in the SI.

Several conclusions emerge from these analyses:

• • Unpopular norms (i.e. norms with low v̅) can be stably maintained in the population whereas generally preferred norms (i.e. norms with high v̅) can be present at very low frequencies. Both these outcomes are related to a notion of ‘preference falsification’ (i.e. the act of communicating a preference and/or performing an action that differs from one's true preference under perceived social pressure, Kuran (Reference Kuran1989)).

• • Parameters and initial conditions have strong effects on the eventual population state. This implies that different groups can diverge in their state even if they are subject to similar social forces. Also important is the shape of the distribution of individual values/beliefs in the population. Predicting the population social dynamics requires a good knowledge of this distribution.

• • All this means that different groups/cities/communities may find themselves at different equilibria owing to differences in initial conditions even if everything else is the same. Moreover, groups/cities/communities can differ in parameter values (costs, benefits, etc.) and in the distribution of normative values. These differences will affect the outcomes of social dynamics.

• • The variance σ ² of the distribution of normative values has nonlinear effects on the frequency of norm-abiding behaviour p: increasing σ can increase or decrease p depending on other parameters. Also, larger σ typically means slower convergence to an equilibrium.

• • Small and/or slow changes in parameters (which, for example, can be brought by some policy interventions) can cause a quick and dramatic change in the population. Similar effects may be caused by stochastic forces. A prerequisite for dramatic changes is the existence of simultaneously stable equilibria.

• • Changes in individual and group behaviour can be achieved by changing material benefits and costs (e.g. b), normative values (e.g. v and κ) or by changing the expectation of what others do (e.g. their estimate of p), e.g. by providing/manipulating certain information. An ‘injection’ of certain information can shift the population to the domain of attraction of a different equilibrium.

Effects of population mixing

Stable maintenance of social norms in groups and communities can be endangered by the influx of individuals who do not share the corresponding normative values. Let m be a proportion of individuals in the whole population for whom v = k = 0, so that they are motivated only by material factors. Let F be the c.d.f. of v in the remaining part of the population and p be the frequency of individuals following the norm among in that part. Then the observed frequency of the normative behaviour in the whole population is (1 − m)p. The dynamics of p are described by the equation

(3)$$p' = 1-F\lpar {b-\kappa \lpar {1-m} \rpar p} \rpar .$$

Figure 2 shows that norms are relatively stable to a small infusion of newcomers but the frequency of norm followers p can be significantly reduced if m is sufficiently large.

Figure 2. Equilibrium values of frequency p in the model of population mixing (equation 3). Green, red and black diamonds correspond to three different values of the immigration rate: m = 0.2, 0.1, and 0, respectively. Filled diamonds are stable equilibria. Open diamonds are unstable equilibria separating the two stable ones. b = 1.

Both passive and active disapproval of norm violators

So far I have assumed that norm violators experienced only passive disapproval. Now assume that after making a decision about complying (i.e. choosing x = 1) or not (i.e. choosing x = 0) with the norm, individuals can also actively disapprove (or punish) norm violators, e.g. by verbally admonishing them (or just rolling their eyes or raising eyebrows). [Here, the difference between passive and active disapproval is that the latter is costly to the individuals expressing it.] The injunctive norm now is to both follow the prescribed behaviour and actively disapprove of norm violators; its normative value is denoted v as above. Let variable y = 0 and y = 1 specify the act of disapproval and let q be the frequency of individuals doing it. Then the utility of complying with the norm (i.e. choosing x = 1) is u ₁ = v ⁺ as before while that of violating it is b − v⁻ − κp − cq, where c is the maximum cost of being ‘actively’ disapproved (socially punished). Then, assuming complete knowledge of parameters, an individual chooses x = 1 if their normative value v ≡ v ⁺ + v⁻ > v*, where

(4a)$$v^\ast = b-\kappa p-cq.$$

If v < v*, the individual violates the norm.

Let p′' be the frequency of individuals who have followed the norm. To define the utility of active disapproval/punishment, we assume that only norm-compliant types (i.e. individuals with x = 1) can punish and that individuals who do not punish receive only passive disapproval from those who do. Let δ be the maximum cost of punishing which could be due to a punishment act itself or potential retaliation. Assume that individuals not punishing defectors suffer a normative cost κ owing to implicit disapproval by active punishers. Under these assumptions, the utility of punishing is v − (1 − p′)δ, where the term 1 − p′ can be viewed as the ‘need for enforcement’ (Centola et al., Reference Centola, Willer and Macy2005). (Indeed, it makes no sense to pay the cost and disapprove something that does not happen, i.e. if p′ = 1.) The utility of not punishing is κq. Then a norm-complying individual will chose y = 1, if their v > v**, where

(4b)$$v^{{\ast}{\ast} } = \lpar 1-p'\rpar \delta -\kappa q.$$

Assume as before that the normative value v has a distribution in the population with c.d.f. F (z). Then the dynamics of p and q are described by a couple of recurrence equations

(5a)$$p'= 1-F\lpar v^\ast \rpar \comma \;$$

(5b)$$q' = 1-F\lpar {\rm max}\lpar v^\ast \comma \;v^{{\ast}{\ast} }\rpar \rpar .$$

Note that individuals with v > max(v*, v**) will both follow the norm and punish norm violators.

Relative to the simpler model considered above, this model has one additional dynamic variable, q, and two new parameters: the cost of active disapproval/punishment c and the cost of actively disapproving/punishing others δ. Figure 3 illustrates the effects of these new parameters on the equilibrium frequency p. Figure S15 in the SI shows the corresponding equilibrium values of q. In both of these figures the top left graph shows the stable equilibrium values when active disapproval is absent. (Note that in contrast to Figures 1 and S11 which depict both stable and unstable equilibria, here I only show stable equilibria.) Figure 3 shows that allowing for active disapproval (i.e. increasing c from zero) leads to the appearance of stable equilibria with high norm compliance even if punishment is costly (i.e. δ > 0). There can be up to two new equilibria. Punishment can have asymmetric effects on the stability of equilibria affecting the sizes of their domain of attraction. The frequency of punishers q follows p closely if p is large. That is, most contributors also punish norm-violators. If, however, punishment if costly (i.e. δ is large), only a subset of contributors with high normative values v will punish, so that q will be smaller than p. Figure S15 in the SI shows that equilibrium values of q are close to those of p except when the cost of punishment δ is high. With δ = 2, punishment happens with a lower frequency (and q* is significantly smaller than p*).

Figure 3. Stable equilibria in the model with both passive and active disapproval of norm violators with σ as the bifurcation parameter for different values of the maximum cost of being punished c and the cost of punishing others δ. v̅ = 0.8, κ = 0.2. Lognormal distribution of v.

Although Figures 3 and S15 capture the effects of σ in great detail, they cannot convey information about the domains of attraction of different equilibria. The latter are illustrated in Figure 4 for the model in which the distribution of v is bimodal. This figure shows that there can be between one and four simultaneously stable equilibria. The existence of simultaneously stable equilibria implies strong dependence on the initial conditions. Interestingly, there are situations when simultaneously stable equilibria differ in the extent of both norm compliance and punishment.

Figure 4. Stable equilibria (marked by red stars) and their domains of attractions (painted by the same color) on the (p, q)-phase plane in the model with both passive and active disapproval for different values of parameters c, δ and σ. The underlying distribution of v is a sum of two lognormal distributions with mean values at v̅ and 1 − v̅ andthe same σ. v̅ = 0.2, κ = 0.8.

All conclusions from the models with only passive disapproval remain valid in models with active disapproval (punishment). Punishment brings additional effects. In particular:

• • The complexity of resulting dynamics is greatly increased. This concerns the number of equilibrium states and the extent of behavioural differences between them, e.g. in norm compliance or the level of punishment. These results imply a possibility of even greater variation between different groups and cultures (Gelfand et al., Reference Gelfand, Raver, Nishii, Leslie, Lun, Lim and Yamaguchi2011).

• • Punishment stabilizes cooperative equilibria (as noticed earlier by Boyd & Richerson, Reference Boyd and Richerson1992).

• • Costly punishment is largely administered by individuals with high norm internalization.

Similarly to the discussion above, it is straightforward to add additional costs and benefits to our modelling framework. For example, punishers of norm violators may expect to receive passive approval from other punishers. Alternatively, individuals who oppose the norm can actively punish norm followers. Capturing these effects in the model will modify the meaning of parameters but not the resulting dynamics.

Footbinding

The painful and dangerous practice of footbinding impaired most Chinese women for a thousand years and then ended, for the most part, in a single generation as a result of the campaign of the anti-footbinding reformers. The campaign to abandon this norm had three components (Mackie, Reference Mackie1996).

The first component was a persuasive effort which explained that the rest of the world did not bind women's feet and that China was ridiculed and losing respect in the world. The second component was an educational effort explaining the health benefits of natural feet and the costs of bound feet. The third was the establishment of natural-foot societies, whose members pledged not to bind their daughters’ feet nor to let their sons marry women with bound feet. The influence mechanism here was commitment and consistency. Once people have publicly committed to something, they are more likely to follow through than if they have not.

In terms of my modelling framework, there is a material benefit, b, to abandoning footbinding (i.e. improved health), but individuals have internalized the norm (i.e. assign a positive value v to it) and expect to be subject to public disapproval leading to both normative, κ, and material, c, costs of violating the norm. The latter are due to reduced mating opportunities for daughters. The ‘actors’ here are the parents or relatives of girls enforcing the corresponding actions. One can interpret the three components of the anti-footbinding campaign in the following way. The first component introduced a normative cost of footbinding (effectively increasing the benefit b of abandoning it). The second component directly increased the perceived material benefit b of abandoning footbinding. The third component decreased the costs κ and c of disapproval by people who still abide by the norm as well as added material costs of following the norm (by decreasing the corresponding mating opportunities). These changes in perceived costs and benefits led to a fast reduction in the frequency p of footbinding.

Female genital cutting

The practice of female genital cutting found in Africa, Asia and the Middle East results in significant physical and emotional risks for tens of millions of girls and women (Berg et al., Reference Berg, Underland, Odgaard-Jensen, Fretheim and Vist2014), especially in low- and middle-income countries (Kandala et al., Reference Kandala, Ezejimofor, Uthman and Komba2018). In an attempt to change this norm, a specific policy was adopted by national and international agencies. Along with other activities, the policy called for development workers to assemble in a short period of time a group of cutting families in a community willing to abandon cutting and to declare publicly that they had done so (Efferson et al., Reference Efferson, Vogt, Elhadi, Ahmed and Fehr2015). The policy was based on a game theory model which treated norm compliance as a coordination problem (Mackie & LeJeune, Reference Mackie and LeJeune2009) and the belief that the pressure for social conformity dominated all other possible effects. The model then predicted that, once a certain critical frequency of declaring families was exceeded, the remaining families who cut would realize that abandoning the norm was in their interests and would do so. As a result, the norm would disappear completely.

In terms of my model, there are material benefits b of abandoning cutting as well as normative cost κ (owing to disapproval) and material cost c (owing to reduced mating opportunities) of abandoning the norms. The overall effects of these costs are frequency-dependent. The public declaration by non-cutting families would then effectively decrease the perceived frequency p of families following the norm. However, because of the expected heterogeneity among families in the normative benefits and costs one should not expect that p will go to zero. Rather the most likely outcome will be that p will just shift and stabilize at some intermediate value. In fact, the analysis of the frequency of cutting across 45 communities in Sudan shows that cutting rates vary continuously between 0 and 1 rather than having a discontinuous distribution with peaks at 0 and 1 as predicted by the social coordination model (Efferson et al., Reference Efferson, Vogt, Elhadi, Ahmed and Fehr2015). Efferson et al. (Reference Efferson, Vogt, Elhadi, Ahmed and Fehr2015) argued that convincing families who already have low values of cutting to make a public declaration will probably not have a large effect on remaining families. Efferson et al. (Reference Efferson, Vogt, Elhadi, Ahmed and Fehr2015) conjectured that the effort of the development workers may be more effective if it focuses on the families least receptive to the idea of abandoning cutting.

In a recent follow-up paper, Efferson et al. (Reference Efferson, Vogt and Fehr2020) used the Shelling–Granovetter model to make these arguments stronger. In their model of conformity, families differ in their sensitivity to social pressure to maintain cutting; the social pressure declines with the proportion of families who have already abandoned it. Efferson et al. (Reference Efferson, Vogt and Fehr2020) assumed that a persuasive intervention makes families abandon cutting completely. They compared three different intervention strategies focusing on individuals most amenable to change or most resistant to change, or on a random sample from the population. They concluded that although interventions often target samples of the population most amenable to change, targeting a representative random sample is a more robust way to reduce cutting. My results reported in the section on ‘Persuasive interventions’ above back the validity of these conclusions in a more general framework. Overall, my results support earlier conclusions of Efferson et al. (Reference Efferson, Vogt, Elhadi, Ahmed and Fehr2015, Reference Efferson, Vogt and Fehr2020) that understanding heterogeneity in a population is essential for predicting the effects of interventions. As I argue here, evaluating the expected effectiveness of different campaigns requires information on the distribution of values and beliefs in the target population. (See figure S3 in Efferson et al. (Reference Efferson, Vogt, Elhadi, Ahmed and Fehr2015) for an empirical example of such a distribution.)

College students’ drinking

Heavy alcohol consumption and binge drinking is a serious problem in many colleges. Data show that drinking rates increase significantly during the transition from high school to college (Labrie et al., Reference Labrie, Lamb and Pedersen2009). A contributing factor to this increase is that students typically overestimate the frequency and amount that other students drink. As a result, many students are often under a strong social pressure to drink in excess of what they would prefer (Park et al., Reference Park, Klein, Smith and Martel2009).

There are three main methods of social norm interventions focusing on correcting misperceptions about risky behaviours and social norms (Miller and Prentice, Reference Miller and Prentice2016). Social norms marketing is the dissemination of a single factual message documenting the (high) incidence of some desirable behaviour. Personalized normative feedback is the information about themselves as well as their peers. Focus group discussions aim to achieve similar goals by capitalizing on a readily available reference group. Considerable research indicates that feedback on close referents has the strongest effect on behaviour, making the personalized normative feedback and focus group discussions more powerful. All three methods have been used in efforts to reduce students’ drinking.

In terms of my models, these methods aim to provide correct (or desirable) information about variable p. If p is lower than the students thought, it may also force them to increase their estimate of benefit b of abandoning the norm. (The logic is that if many others do not do it, there may be indeed high benefits of reduced drinking.) The information about discrepancies between individual behaviour and the average behaviour in their reference group may force the subjects to reduce their estimates of the level of social disapproval κq they expect to receive from peers. The most receptive individuals to change will be those who are drinking more than they want to because of a desire to be socially accepted. Information that p is low may also increase the likelihood that students who oppose heavy drinking will actively disapprove/punish back norm followers (i.e heavy drinkers). Moreover, manipulating identity cues may force individuals to reevaluate the normative value v of a particular behaviour. Observers usually interpret behaviours as freely chosen and reflecting the actor's private preferences and dispositions (Gilbert & Malone, Reference Gilbert and Malone1995). That is, high frequency p of drinking may be interpreted as evidence of high normative values v assigned to it. Correcting this misinterpretation can reduce drinking. Some interventions also attempt to change the perceived benefits of behaviour, e.g. by reports of how uncomfortable students feel with their drinking practices.

Pro-environmental behaviour

Social norms have a significant impact on a range of pro-environmental behaviours (Miller & Prentice, Reference Miller and Prentice2016; Farrow et al., Reference Farrow, Grolleau and Ibanez2017; Nyborg, Reference Nyborg2018; Jachimowicz et al., Reference Jachimowicz, Hauser, O'Brien, Sherman and Galinsky2018). Methods used to change human behaviour affecting the environment are similar to those mentioned above (e.g. social marketing, personalized normative feedback and focus group discussions). Proenvironmental behaviour is a kind of a public good. As stressed by Miller and Prentice (Reference Miller and Prentice2016), in the case of public goods, ‘perceived norms tend to be unclear or absent, rather than biased, and thus the interventions work primarily by making people more aware of their own behaviour and where it falls in the distribution’ (p. 348). For example, feedback in environmental interventions can focus on how people's weekly kilowatt use compares with that of their neighbours. Risky behaviour interventions are most effective when they utilize social identity considerations (e.g. same-gender friends, teammates, sorority sisters). In contrast, public-goods interventions invoke comparisons with the group with whom the focal individual shares public goods, e.g. nearby residents.

Two types of information have proved most useful when providing such feedback: (a) how common particular environmental behaviours are among group members (descriptive norms); and (b) the degree of approval of these behaviours by group members (injunctive norms). Informing people that their neighbours use less energy will convey to people that energy use reduction is possible. In terms of our models, this can make them reduce the perceived material cost/benefit ratio and simultaneously increase normative value v of pro-environmental behaviour. Informing people about the degree of neighbours’ approval (e.g. Jachimowicz et al., Reference Jachimowicz, Hauser, O'Brien, Sherman and Galinsky2018) accomplishes several things. It sends a better signal of their true intentions so that the focal individual will not feel like a sucker. This will decrease the normative costs of pro-environmental behaviour. [Note that in the model, the psychological cost of being a sucker is frequency dependent and can be described in a similar way to that of reduced mating opportunity for the footbinding and genital cutting norms discussed above.] It can also signal expected approval by others, characterized by parameter v_a in the model. Providing the information about neighbours’ preferences can also exploit existing preferences for conformity and the sense of belonging to the community measured by parameter v_c. Energy consumption by high users is reduced the most if the corresponding information is presented publicly rather privately (Delmas & Lessem, Reference Delmas and Lessem2014). This implies that people have normative concerns about their social standing and reputation. This effect can be captured by adjusting the normative value v of the behaviour.