The deliberation stage

Set-up I introduce multiple senders, or experts, into the framework proposed by Dewatripont and Tirole (Reference Dewatripont and Tirole2005). A DM faces two simultaneous decisions, i = 1, 2.Footnote ⁶ Each decision i concerns whether to take a distinct action, A _i. For each decision, there is a distinct expert who gets a deterministic payoff d > 0 if the DM takes the action and zero otherwise. The DM's payoff $\tilde x_i $ from A _i takes the value $\bar{x}{\rm \;} \gt \; 0$ with probability α _i and otherwise the value x < 0. The probability α _i is common knowledge. The larger the α _i, the more attractive A _i seems to the DM and the more aligned are her interests with those of the expert vested in A _i. Everyone is risk-neutral. In the absence of additional information, the DM takes A _i if and only if its expected payoff is positive: $\alpha _i \gt \alpha ^{\rm *} \equiv \displaystyle{{ - \underline{x}} / \lpar {\bar x - \underline{x}}\rpar } $.Footnote ⁷

Before making any decision, the DM can learn more about the actions. For each action, the vested expert can provide information and the DM can devote attention to processing this information. Through such communication, the DM can learn the realization of $\tilde x_i $. The expert himself knows neither whether $\tilde x_i = \bar x$ or $\tilde x_i = \underline{x} $ nor whether the (truthful) information he provides will help the DM find out. Nevertheless, his information may persuade the DM to take A _i even though α _i < α*, since the DM may find out that $\tilde x_i = \bar x$. The probability that the DM learns $\tilde x_i $ is given by p(s _i, r _i), where s _i and r _i are, respectively, the expert's effort to communicate about A _i and the attention that the DM devotes to learning about A _i.

Successful communication is more likely the more effort the expert devotes to persuasion (p ₁( · ) > 0) and the more attention the DM devotes to his message (p ₂( · ) > 0). In short, communication is a team effort. Because communication efforts are complements (p ₁₂( · ) > 0), an expert's return from expending effort is higher when the DM listens more attentively and the DM's return from paying attention is higher when the expert makes a greater effort to explain. The formulation encompasses communication technologies with the property p(0, r _i) ≠ 0: even if an expert makes no effort to transmit information to the DM, it is possible for her to find the relevant information by herself.Footnote ⁹

Communication is costly to both parties. The DM's attention is scarce, $\mathop \sum \nolimits_i r_i \le 1$, so the cost is attention substitution: paying more attention to one action necessarily comes at the expense of others. An expert's cost of persuasion effort is given by c(s _i).

The persuasion efforts and the attention allocation are chosen simultaneously and non-cooperatively. I refer to the above game as the deliberation stage.

I determine the Nash equilibrium for this game and then analyze how the experts affect each other in equilibrium.

An expert's behavior hinges on whether the DM uses an opt-in rule or an opt-out rule for the decision in which he is vested. When α_i ≤ α*, the DM uses an opt-in rule with respect to A _i. Her default is not to take A _i, but she departs from this default – opts in – if she learns that $\tilde x_i = \bar x$. Hence, expert i has an incentive to communicate with her. Thus, when α₁, α₂ ≤ α*, each expert solves

$$\mathop {max} \limits_{s_i} {\rm \;} \left\{ {d{\rm \alpha} _i p\left( {s_i, r_i} \right) - c\left( {s_i} \right)} \right\},$$

and the DM's problem is

(1)$$\matrix{ {\mathop {max}\limits_{r_{1{\rm \;}} \in \left[ {0,1} \right]} \; \left\{ {\bar x\left( {{\rm \alpha} _1 p\left( {s_1, r_1} \right) + {\rm \alpha} _2 p\left( {s_2, 1 - r_1} \right)} \right)} \right\}{\rm.}} \cr} $$

In the unique equilibrium, both experts communicate and the DM pays attention to both. The Inada condition rules out corners; global concavity of p(s _i, r _i) guarantees uniqueness.

In contrast, when α_i > α*, the receiver uses an opt-out rule with respect to A _i. Her default is to take A _i, but she departs from this default – opts out – if she learns that $\tilde x_i = \underline{x} $. Because communication can only persuade the DM not to take A _i, expert i makes no effort. The DM can nevertheless devote attention to A _i; that is, she can engage in (one-sided) information acquisition. If α₁ ≤ α*, α₂ > α*, her problem is

$$\mathop {max}\limits_{r_{1{\rm \;}} \in \left[ {0,1} \right]} \; \left\{ {\bar x\alpha _1 p\left( {s_1, r_1} \right) + \alpha _2 \bar x + \left( {1 - \alpha _2} \right)\underline{x} - p\left( {s_2, 1 - r_2} \right)\left( {1 - \alpha _2} \right)\underline{x}} \right\}$$

In the unique equilibrium, expert 1 exerts effort, expert 2 is passive and the DM communicates with expert 1 about A ₁ and devotes some attention to acquiring information about A ₂. The distinction between one-sided and two-sided communication arises endogenously.

Crowding out How well an expert fares in the deliberation stage depends not only on how attractive his own action seems to the DM, but also on the other experts’ attractiveness.

As $r_2^* \left( {\alpha _1} \right) = 1 - r_1^* \left( {\alpha _1} \right)$, a change in α₁ that causes the DM to pay more attention to expert 1 in equilibrium crowds out attention to expert 2. When expert 2 wants the DM's attention, this crowding out harms him; otherwise, it benefits him. Thus, the presence of expert 1 imposes a negative or positive externality on expert 2 and the size of this externality is captured by $r_1^* \left( {\alpha _1} \right)$.

This follows from the fact that the attention the DM devotes to expert 1 in equilibrium, $r_1^{\rm *} \left( {\alpha _1} \right)$, is non-monotonic in α ₁: $r_1^{\rm *} \left( {\alpha _1} \right)$ increases for α ₁ ∈ (0, α*), falls at α* and decreases for α ₁ ∈ (α*, 1). If expert 2 wants the DM's attention (α ₂ ≤ α*), ${\bi E}U_{Exp_2} \left( {\alpha _1} \right)$ is negatively related to $r_1^{\rm *} \left( {\alpha_1} \right)$; otherwise, the reverse holds. This is illustrated in Figure 1.

Figure 1. Crowding out. The DM's attention devoted to expert 1 in equilibrium $r_1^* \left( {\alpha _1} \right)$ for a given α ₂ is non-monotonic in expert 1's attractiveness (left panel). This makes expert 2's utility non-monotonic in α ₁: when expert 2 desires attention (α ₂ ≤ α*), $r_1^* \left( {\alpha _1} \right)$ represents a negative externality on expert 2, so EU _Exp2(α ₁) is negatively related to $r_1^* \left( {\alpha _1} \right)\; $(middle panel). When expert 2 does not desire attention (α₂ > α*), $r_1^* \left( {\alpha _1} \right)$ represents a positive externality on expert 2, so EU _Exp2(α ₁) is positively related to $r_1^* \left( {\alpha _1} \right)$ (right panel).

The selection stage

We now add a pre-play stage by introducing cue communication, as in Dewatripont and Tirole (Reference Dewatripont and Tirole2005).

Set-up The DM can pay attention to two distinct actions in the deliberation stage.Footnote ¹⁰ When more than two experts seek the DM's attention, selection becomes an important issue. To capture this, I add a pre-play stage in which the DM must select at most two experts for the deliberation stage. I refer to the pre-play stage as the ‘selection stage’.Footnote ¹¹ $N = N_{\bar \alpha} + N_{\underline{\alpha}} $ experts can enter the competition to be selected. Of these, $N_{\bar \alpha} $ propose actions of high quality $\left( {\alpha = \bar \alpha} \right)$ and N _α; of low quality $\left( {\alpha = \underline{\alpha} \lt \bar \alpha} \right)$. $N_{\bar \alpha} \gt t$ is finite; N _α is infinite. I set parameters such that all experts want attention, $\underline{\alpha} \lt \bar \alpha \lt \alpha ^{\rm *} $.

As in Dewatripont and Tirole (Reference Dewatripont and Tirole2005), each expert's quality is his private information. Hence, an expert may be willing to signal the quality of his action if it helps him get selected and the DM may be willing to read such signals before choosing on which actions to deliberate; that is, with which experts to communicate. Specifically, at cost q _S > 0, an expert can send a cue (signal) that contains hard information about the quality of his action. Upon receiving a cue, the DM decides whether to process it, at cost q _R >0, to learn the action's quality. No expert can be selected without having sent a cue; hence, q _S can be thought of as an entry cost. As I explain below, this last assumption is not crucial.

I solve this game, deliberation stage plus selection stage, for a perfect Bayesian equilibrium. Furthermore, I focus on the equilibria favored by the DM; that is, those with the maximum number of high-quality entrants.

Information overload As would be expected, when the cost of entry decreases, the supply of experts – and hence the number of actions from which the DM can choose – increases. However, as the DM's choice set grows, her expected utility first increases, but then decreases. Proposition 2 states this key result.

It is instructive to describe how equilibrium behavior in the selection stage changes as the cost of sending cues, q _S, falls from prohibitively large to negligibly small. The impact on the DM's expected utility is illustrated in Figure 2, where a decrease in q _S represents a movement from right to left on the x-axis.

• • For high enough q _S, cues are so expensive that no expert enters.

• • As q _S falls, it at some point becomes sufficiently attractive for some high-quality experts to enter. Here, the cues in themselves are signals of high quality, so the DM need not process them, but can select her communication partner(s) for the deliberation stage at random from the pool of entrants. (This relies on the assumption that the DM can observe that a cue was sent even if she does not assimilate it. If we relax this, the economic insights remain valid, as I explain below.) In this signaling outcome, the DM's welfare increases as q _S falls so long as the number of entrants is smaller than two – or, more generally, smaller than the number of experts with whom she can communicate in the deliberation stage; otherwise, the DM's welfare remains constant. This is captured in Figure 2: as q _S decreases, the DM benefits from an expansion in information supply so long as $q_S \gt \overline {q_S} $. Then, as q _S falls further (but remains above q_S), the DM has access to (at least) two high-quality experts, but no low-quality experts, so her expected utility remains flat as q _S falls further.

• • As q _S falls below q_S, some low-quality experts find it attractive to enter as well. A signaling equilibrium, in which a random pick from among the entrants ensures a high-quality expert for the deliberation stage, no longer exists. The DM reacts in one of two ways: either she continues to randomize and simply accepts the lower (average) expert quality or, if q _R is not too high, she reads cues with positive probability to screen out low-quality experts. So as not to make the selection stage trivial, I focus on q _R that is low enough for the DM to engage in active screening. Clearly, her welfare decreases as q _S falls, as it becomes harder to spot high quality. Already, the arrival of more cues – essentially, access to more information – makes the DM worse off. The next stage is merely the copestone.

• • As q _S vanishes, the avalanche of low-quality cues reduces the average quality in the entrant pool so much that screening becomes futile – high quality becomes the proverbial needle in the haystack. As a result, there is neither signaling nor screening, just pooling: the DM gives up on active selection and accepts that she is all but bound to encounter low quality in the deliberation stage. Her expected utility thus approaches U*, her expected utility from communicating with two low-quality experts (on two low-quality actions) in the deliberation stage.

Thus, at a certain point, as the competition for the DM's attention increases and she gets more information, she processes less of it – or tunes out – and fares worse. I refer to this phenomenon – the more cues the DM gets, the fewer she processes and the worse she fares – as information overload.Footnote ¹²

Figure 2. Information overload. A movement from right to left on the x-axis represents a decrease in the cost of entry, q _S. As q _S decreases, the DM first benefits from an expansion in information supply (so long as $q_S \gt \overline {q_S} $). Then the DM has access to (at least) two high-quality experts, but no low-quality experts, so she obtains her maximum possible (decision) payoff, U*. As the cost of entry falls below q_S, low-quality experts join the battle for access to the DM's attention and her expected utility falls below U*. When q _S → 0, the number of low-quality experts who enter tends to infinity, so the DM ceases to screen experts. Her decision payoff falls, as she relies on information of lower quality on average. Thus, when information becomes cheap enough, the more information she gets, the less information she processes and the worse she fares.

It is instructive to make precise how (the idea of) information overload is related to (the idea of) limited attention. To this end, consider this quote by Simon (Reference Simon and Greenberger1971: 40–41):

Thus, attention, in limited supply, becomes a scarcer resource in relative terms when confronted with more information. But this does not imply information overload or that more information provided can decrease knowledge acquired. The idea of information overload is that a wealth of information not only “creates … a need to allocate that attention” (emphasis added), but actually impairs the ability to do so efficiently.

Alternative assumptions If I instead assume that the DM cannot observe that a cue was sent unless she incurs a cost to read it, the economic insights remain: she must open exactly two cues so long as only high-quality experts enter; then, she must either open exactly two cues but rely on information of lower quality or open more than two cues on average to identify two high-quality experts. In either case, her expected utility remains constant when only high-quality types enter and decreases with the number of low-quality types.

Further, the equilibria described above exist even if we relax the assumption that an expert must send a cue to enter. However, in that case, there is a further equilibrium for q _S → 0 in which the experts cease to send cues, aware that they are no longer processed, and the DM picks randomly from the entire pool of experts. Still, the DM favors the equilibrium in which she picks randomly from a subset of experts – which includes all high-quality experts – who send a cue, because it offers better odds of picking a high-quality expert.

Also, we need not assume differences in quality. Instead, suppose experts invest in quality. Specifically, suppose all N experts begin with low quality (α = α), but can invest in high quality $\left( {{\rm \alpha} = \bar {\rm \alpha}} \right)$ at some cost c > 0 before entering. Proposition 2 implies that information overload frustrates investment in high quality. Intuitively, the value of quality is reflected in the expected utility difference between a high-quality and a low-quality type. For prohibitive q _S, both types expect to earn zero, so there is no incentive to invest in quality. As q _S falls, if c is not too high, some invest in quality and send cues. But as q _S → 0, information overload erodes the premium on quality, so again no one invests. The supply of high quality collapses when it becomes too cheap to approach the DM. This is not because the DM ceases to value quality. On the contrary, she would like to treat high-quality experts preferentially; however, she in unable to do so when finding them amounts to looking for a needle in a haystack.

Externalities as the driving force of information overload The immediate cause of information overload is that the quality of proposed actions decreases with the quantity; actions worthy of deliberation become the proverbial needle in a haystack. The deeper cause, though, is negative externalities: entry is individually rational for each expert, even as it complicates the selection problem for the DM and spoils overall communication. This is because each expert ignores how his own entry affects the communication environment as a whole. If the expert were identical for all actions, he would send cues only for two high-quality actions. In the decentralized setting, however, sending cues remains individually rational even as each cue sent aggravates the complexity of the DM's selection problem up to a point where active selection breaks down. This, in turn, frustrates the incentives to produce quality. Intuitively, it is as if the low-quality experts, each seeking to be noticed, pollute the DM's attention field. Indeed, information overload is similar to pollution or congestion and, like them, may be amenable to efficiency-improving intervention. The next subsection addresses practical expressions of information overload and discusses the fact that a DM with limited attention may want to limit access to her attention space, even if that reduces her choice set. In a nutshell, she faces a trade-off between comprehensiveness and comprehensibility.

Information overload in practice

With recent advances in information technology, individuals face massive data via more channels (phone, Internet, email, instant messages, etc.) and on more platforms (Facebook, Twitter, blogs, etc.). In the presence of information overload, such an abundance of information can be counterproductive. Indeed, a business research firm nominated information overload as the ‘problem of the year’ in 2008, predicting that it would cost firms US$650 billion in lost productivity and innovation due to ‘unnecessary interruptions’. The main concern is that an escalating quantity of information comes with a decline in average quality and that this inverse relationship between amount and relevance makes it harder to find ‘good’ information.Footnote ¹³ This makes selection, as in my model, a daunting issue and suggests that consumers should value products that help reduce their choice sets and improve selection.

In this vein, several technology firms, including Microsoft, Intel, Google and IBM, recently formed a nonprofit organization, the Information Overload Research Group, to develop solutions to information overload.Footnote ¹⁴ Google's success formula, its ranking algorithm, implements pre-selection. And its ubiquity on the Internet, as gateway and gatekeeper, betrays the import of information overload. The logic of pre-selection also underlies solutions such as email filters, ranking inbox messages by imputed importance, compiling communication histories for every sender, displaying email portions to allow for fast screening and sophisticated filing and search functions. Such ranking of electronic messages minimizes information overload; that is, it reduces the “economic loss associated with the examination of a number of non- or less-relevant messages” and distinguishes “communications that are probably of interest from those that probably aren't” (Losee, Reference Losee1998).

Information overload is not just a matter of Internet and emails. In a seminal study, Jacoby et al. (Reference Jacoby, Speller and Kohn Berning1974) explored how the quality of consumption decisions depends on ‘information load’, measured as the number of brands as well as the amount of information per brand provided. Their experiment showed that the ability to pick the best product dropped off at high levels of information load. In Jacoby et al. (Reference Jacoby, Kohn Berning and Speller1973), a companion paper, they further showed that the subjects spent less time on processing information – or, in their words, ‘tuned out’ – once the information load exceeded a certain threshold.Footnote ¹⁵ Many other experiments in organization science, accounting, marketing and information science corroborate the notion that more information can impair cognitive processes and decisions (Edmunds & Morris, Reference Edmunds and Morris2000; Eppler & Mengis, Reference Eppler and Mengis2004).

Because information overload is a driving force behind innovations in communication and information management, it is connected to recent research on choice architecture; that is, how the presentation of choices affects decisions (Thaler & Sunstein, Reference Thaler and Sunstein2008). Cronqvist and Thaler (Reference Cronqvist and Thaler2004), for example, studied the introduction of a new retirement savings plan in Sweden in 1993. Eligible Swedes were encouraged to choose five out of 456 funds, to which their savings would be allocated. A third of all eligibles made no active choices; their savings were instead allocated to a default fund (essentially a pre-selection by the government). Information overload seems a likely reason that so many Swedes relied on the default choice: comparing hundreds of funds is a Herculean task for ordinary households, and one might expect many of them to resort to the default or make superficial active decisions. Indeed, studying the same Swedish reform, Karlsson et al. (Reference Karlsson, Massa and Simonov2006) showed that funds that (for exogenous reasons) were better represented in the fund catalogue – that is, had better ‘menu exposure’ – received more active contributions.Footnote ¹⁶

All of the above examples suggest that DMs can benefit from receiving less information, despite the associated decrease in choice set. Indeed, in the presence of information overload, there is a trade-off between variety and simplicity, or between comprehensiveness and comprehensibility. This evidence contrasts with models of decision-making under unlimited attention, where a larger choice set cannot make an individual worse off.

Modified setup: deliberation and selection stages

The DM communicates with a single expert about one action, A, which has many aspects. Specifically, suppose the DM's payoff from A can be expressed as the sum of N _R components: $\tilde x = \mathop \sum \nolimits_1^{N_R} \tilde x_i $. Each component takes the value $\bar x \gt 0$ with probability α _i and otherwise the value x < 0. So the expected payoff from A is $E\left( {\tilde x} \right) = N_R \left[ {\bar \alpha \bar x + \left( {1 - \bar \alpha} \right)\underline{x}} \right]$, where $\bar \alpha = \displaystyle{(1 / {N_R})} \mathop \sum \nolimits_1^{N_R} \alpha _i $. Similar to before, absent more information, the DM takes A in the deliberation stage if and only if $\bar \alpha \gt \alpha ^{\rm *} \equiv \displaystyle{{ - \underline{x}} / ({\bar x - \underline{x}})} $. Or, put differently, if the DM can obtain more information, she uses an opt-in rule if $\bar \alpha \; $≤ α* and an opt-out rule if $\bar \alpha$ > α*.

In addition to the N _R components of the action A that are relevant to the action's payoff, there exist additional $N_\emptyset $ components of A that are irrelevant to the DM's payoff. I assume that the DM does not know which components are relevantFootnote ¹⁷ and is potentially unaware of components per se. Intuitively, this captures a plausible situation: inclined toward a particular choice, the DM might yet discover (financially relevant) aspects that change her opinion. Thus, the DM is faced with two sets of questions: what components exist and which ones are relevant (selection stage)? And how much attention should a given component receive (deliberation stage)?

As before, the expert's communication incentives hinge on the DM's decision rule: if the DM follows an opt-in rule, the expert must persuade her to take the action. To maximize the chances that the DM revises her beliefs upward and so opts in, the expert seeks to draw her attention to those aspects that are most likely to yield favorable information; that is, he sends her cues about, and exerts persuasion effort on, the topics with the highest α _i.

By contrast, if the DM follows an opt-out rule, her default is to take action A, but she may depart from this default – and opt out – if she learns about any relevant aspects of the action that are unfavorable. Then, the expert wants to withhold the relevant information. In the model, this means that, on his own accord, he would never send a cue about any relevant aspect in the selection stage, since this could only induce the DM to devote attention to it in the deliberation stage and subsequently to change her mind and abandon the action after all. In this situation, a mandatory disclosure law would make a difference to the expert's communication strategy: by mandating that the expert (firm) reveals any relevant financial aspects of the product, it would be illegal to withhold this information.

To formalize what happens when the expert is subjected to such a mandate, assume for simplicity that there is one relevant topic, N _R = 1, that the number of irrelevant topics $N_\emptyset $ is infinite and that the DM can at most deliberate on two topics (as in the previous section). These assumptions are merely simplifying; indeed, the ‘strategic information overload’ result reported below holds as long as the DM can devote attention to only a limited number of topics in the deliberation stage and $N_\emptyset $ is sufficiently large relative to N _R. Finally, as before, it is costly for the DM to process cues: q _R >0. For convenience, I refer to cues about relevant (irrelevant) topics as relevant (irrelevant) cues.

Strategic information overload and the limitations of mandatory disclosure laws

When $\bar \alpha \gt \alpha ^{\rm *} $, the DM follows an opt-out rule. Thus, if the DM lacks access to – or is unaware of – the relevant topic, the expert has no reason to bring it to her attention by sending a relevant cue. In fact, the expert is best off sending no cues at all. Now suppose that, by a disclosure mandate, the relevant cue must be sent.

Proposition 3 is closely related to the information overload result in the previous section, yet the underlying economic mechanism is different. In the previous section, information overload resulted from various experts’ competition for attention. Proposition 3 shows that a single expert, who faces no competition for the DM's attention but who can communicate with the DM about multiple aspects of the action for which he advocates, strategically induces information overload in the DM when he is subjected to a disclosure provision that mandates drawing the DM's attention to the financially relevant aspect of the action (the product he tries to persuade the DM to buy).

Intuitively, the expert is afraid that the DM, by paying attention to the relevant topic, might discover unfavorable information about the action and opt out. To reduce the odds that the DM identifies – that is, selects – the relevant topic, the disclosure mandate thus gives the expert an incentive to supply irrelevant aspects in the selection stage by sending out irrelevant cues, even though this is costly for him. A swarm of mostly irrelevant cues, in turn, thwarts the DM's chances, and hence her incentives, to pinpoint the relevant topic. In other words, the expert intentionally induces information overload, which effectively conceals the inconvenient aspect that the firm was mandated to disclose in the first place. In a nutshell, the disclosure mandate, which is intended to raise the DM's awareness of the financially relevant aspect of the product that she considers, generates a response on the part of the expert that in practice renders the DM financially illiterate, or obfuscates her.

As a result, the disclosure mandate has no impact on the DM's final decision; she buys the product even if an understanding of the financially relevant aspect would have pushed her to opt out, since strategic information overload makes her as uninformed in the presence of a mandate as she is in its absence. This sharply illustrates that, when consumers’ attention is limited, simple disclosure rules can be completely impotent and have no impact on social welfare.

Strategic information overload in practice USA Today recently ran an internal study on the costs of maintaining a basic checking account at the ten largest US banks and credit unions. While the most basic fees were found to be disclosed on the institutions’ websites, many others were listed only in the ‘Schedule of Fees and Charges’. That, however, turned out to be difficult to find.

Note that the issue was not only that the ‘inconvenient’ information was at times unavailable, it was also that, even when provided, it was made available in a way that made it costly to locate the relevant information; that is, in a way that induced strategic information overload in the customer. Ordinary customers would be hard-pressed to know not only where to look for relevant items, but also what items to look for. Similar conditions prevail in other countries. In 2008, the website This Is Money cited a warning by the British consumer and competition authority, the Office of Fair Trading, that:

Note that the concern here is the complexity of information; even if a product itself is simple, information overload effectively presents it in an overly complex fashion by hiding it in very long disclosure statements. The financial products market seems rife with such practices.Footnote ²⁰ Credit cards are perhaps the most widely debated example. As quoted in a 2009 Reuters article, President Obama said, “No more fine print, no more confusing terms and conditions,” in a meeting with US credit card company executives on consumer protection regulation.Footnote ²¹

These examples underscore an interesting aspect that eludes many communication models: mandatory disclosure is not a panacea. In the above examples, the communication problem is neither a willful misrepresentation (‘cheap talk’) nor the withholding of facts (‘strategic non-disclosure’). Here, the banks are mandated to provide fee information; cheap talk and non-disclosure are illegal and would have serious consequences ex post. Still, this does not mean that consumers become well-informed. Even when information is hard and disclosed, senders can still – through strategic attention manipulation – conceal what is relevant by manipulating the sheer amount of information. Thus, simple disclosure rules like the Truth in Lending Act may prove completely ineffective when consumers’ attention is limited.Footnote ²²

Complexification and the limitations of ‘simple labels’ for consumer protection

The previous subsection illustrates that too much disclosure can be as concerning as too little; a surfeit of details can prove as uninformative as a dearth thereof. But if disclosure mandates can backfire because firms can induce information overload, intuition suggests an immediate solution: to mandate not only what firms disclose, but also that it is disclosed in an easy-to-understand way. Indeed, more recent disclosure rules often are of this flavor: credit card companies must now disclose key details of the products they offer in a salient fashion, health insurance companies must provide a Summary of Benefits and Coverage of each plan offered and food producers must adhere to standardized labeling regulations to declare all ingredients and the caloric content of each serving, for example.

In this subsection, I use the theoretical framework to analyze the strategic response on the part of an expert (firm) when faced with a mandate to provide easy-to-understand information about the product it sells. As we will see, even detailed mandates to disclose easy-to-understand information can backfire by inducing a ‘complexification’ of the underlying product itself. I show this by extending the model with a single expert to allow the DM's payoff from the (single) action to be composed of many components and to allow the expert to manipulate that composition so long as the total payoff stays constant. Intuitively, such payoff-equivalent variations amount to changing the number of financially relevant aspects of the product. Below, I formalize this.

To allow for complexification, I introduce an option enabling the expert to design A in a way that makes its payoff less transparent. As before, the DM's payoff is – at least initially – the sum of N _R components, $\tilde x = \mathop \sum \nolimits_1^{N_R} \tilde x_i $, and each component takes the value $\bar x$ > 0 with probability α _i and otherwise the value x < 0. However, the expert can now recompose the payoff structure into any form $\tilde y = \mathop \sum \nolimits_1^N \tilde y_J $, so long as the total (realized) payoff is invariant: $\tilde y = \tilde x$. I call $\tilde y$ a payoff-equivalent variation (of $\tilde x$). Crucially, I assume that the DM does not know the ‘original’ composition, $\left\{ {\tilde x_i} \right\}$.Footnote ²³ In any case, absent communication, such variation does not matter; it affects neither the DM's decision nor her welfare.

As an illustration, consider two simple mathematical operations the expert can use to create payoff-equivalent variations. One is to divide each $\tilde x_i $ into m parts, $\mathop \sum \nolimits_{h = 1}^m \tilde x_{ih} = \tilde x_i $, so that the new payoff structure has N = mN _R components: $\tilde y = \mathop \sum \nolimits_{i = 1}^{N_R} \mathop \sum \nolimits_{h = 1}^m \tilde x_{ih} = \mathop \sum \nolimits_{j = 1}^N \tilde y_j $. For example, instead of incorporating total expenses into one salient item, such as the monthly rent, a landlord might disaggregate them into various fees, such as for maintenance, utilities, move-in or move-out, parking, laundry room or other administrative services. The other operation is to add components that neutralize each other, as in $\tilde y = \mathop \sum \nolimits_{i = 1}^{N_R} \tilde x_i + \mathop \sum \nolimits_{i = 1}^{N_R} \tilde x_i - \mathop \sum \nolimits_{i = 1}^{N_R} \tilde x_i = \mathop \sum \nolimits_{j = 1}^N \tilde y_j $, where N = 3N _R. A real-world example is a purchase involving a nominal price, fees, taxes, discounts, bonuses, rewards and so forth that partly offset each other. In both examples, seeing one component is not informative about the others.

Even if the total expected payoff remains unchanged, the payoff composition matters for communication. As before, suppose the DM cannot deliberate on more than a certain number of topics (in keeping with the previous framework, say, two). A proliferation of components then causes more relevant information to slip her attention. Furthermore, disaggregating the payoff can make each component, in and of itself, less important. To see this point, let $\tilde x_{ih} = \displaystyle{{\tilde x_i} / m}$ for all i in the first (landlord) example above. Increasing m leaves the total payoff $\tilde y$ unchanged, but shrinks every component $\displaystyle{{\tilde x_i} / m}$. Crucially, this reduces how much the DM can learn from a given number of components.

Payoff-equivalent variation is thus a means of manipulating the DM's learning process. How the expert uses such means hinges, as before, on the DM's decision rule. If she uses an opt-in rule, the expert wants to help her learn more about A. He would set N ≤ 2 – such that no relevant aspect escapes deliberation – and exert communication effort on all the components; that is, he would simplify the payoff structure and strive to explain.

By contrast, if the DM follows an opt-out rule, the expert wants to do the exact opposite. He would increase the number of components, even if it were costly to do so, only to thwart learning. Suppose he must pay v > 0  to raise N by one.

As v → 0, the expert increases N such that more relevant information escapes the DM's attention, given that she can deliberate on only a limited number of components. At the same time, he disaggregates the payoff to reduce the amount of information she can possibly wrest from any given component. In the limit, even what she can learn from the components she is capable of studying becomes so trivial that it no longer affects her decision: she chooses what she would have chosen without the information. Intuitively, the expert makes the action unnecessarily complex and thereby successfully prevents the DM from getting the full picture.

Complexification thus has the same welfare consequences as inducing information overload – it can eradicate all intended welfare gains from mandated information provision, even if the mandate prohibits unclear communication.

Complexification in practice According to Edward L. Yingling, president and chief executive of the American Bankers Association (ABA), during his first term, President Obama urged credit card companies “to issue a simple credit card product” (emphasis added). A year earlier, after similar comments by Federal Reserve Chairman Ben S. Bernanke “that improved disclosures alone cannot solve all of the problems consumers face in trying to manage their credit card accounts,” the ABA and other industry representatives had signaled strong opposition to such interventions.Footnote ²⁴

The UK financial regulator, the Financial Services Authority, is also quoted as saying:

Other examples of complexification come from the food industry, where legislation mandates that all ingredients be listed in a food declaration; however, ‘incidental additives’ need not be listed. This has provided food producers with incentives for complexification, most prominently by removing an ingredient that consumers may want to avoid and replacing it with one or several incidental additives that accomplish the same effect in food but that remain invisible (provided each of them is included in small enough a quantity). A recent example is Starbuck's use of a color additive derived from the animal world classified as an incidental additive instead of an ingredient, which effectively caused a non-vegan product to be labeled vegan, leading to a stir among vegan consumers.Footnote ²⁵ Similarly, widespread consumer awareness of the dangers of bisphenol-A (BPA) has spurred the development of a new range of plastic products labeled ‘BPA free’; however, these products contain BPA replacement substances that allegedly have produced health problems similar to those associated with BPA itself.Footnote ²⁶ Clearly, in the absence of mandated disclosure of the ingredients in food, none of these complexifications was necessary; in the presence of this disclosure rule, however, they represented strategic responses on the part of food producers.Footnote ²⁷

As opposed to the examples presented in the previous subsection, which showed manipulation of the complexity of information, the examples provided here refer to manipulation of the complexity of the product itself. Whether the complexity of information or the complexity of the product itself is involved, the danger is that misguided decisions affect consumers’ risk of getting into debt or of buying food products that they wish to avoid.

However, while complexity of information has a simple legislative recipe mandating that firms provide easy-to-understand information, complexification is much harder to address from a legislative perspective. In fact, Proposition 4, along with the real-world examples of complexification presented in this subsection, underscore that even the most elaborate disclosure rule – which specifies exactly how easy-to- understand information should be provided – may be completely ineffective for the consumer. This is because any regulation at the communication level proves futile if the seller can modify the object of communication in a way that makes it intellectually challenging to grasp, even with all details correctly disclosed. While the communication is correct, the matter to be decided becomes too complicated. In such a case, to be effective, regulation may have to target the object of communication per se; that is, product design. This, as the examples illustrate, is a much thornier issue.