Gibbard's theorem

Last updated November 13, 2024

In the fields of mechanism design and social choice theory, Gibbard's theorem is a result proven by philosopher Allan Gibbard in 1973.^[1] It states that for any deterministic process of collective decision, at least one of the following three properties must hold:

The process is dictatorial, i.e. there is a single voter whose vote chooses the outcome.
The process limits the possible outcomes to two options only.
The process is not straightforward; the optimal ballot for a voter "requires strategic voting", i.e. it depends on their beliefs about other voters' ballots.

A corollary of this theorem is the Gibbard–Satterthwaite theorem about voting rules. The key difference between the two theorems is that Gibbard–Satterthwaite applies only to ranked voting. Because of its broader scope, Gibbard's theorem makes no claim about whether voters need to reverse their ranking of candidates, only that their optimal ballots depend on the other voters' ballots.^{[note 1]}

Gibbard's theorem is more general, and considers processes of collective decision that may not be ordinal: for example, voting systems where voters assign grades to or otherwise rate candidates (cardinal voting). Gibbard's theorem can be proven using Arrow's impossibility theorem.^{[ citation needed ]}

Gibbard's theorem is itself generalized by Gibbard's 1978 theorem ^[3] and Hylland's theorem,^[4] which extend these results to non-deterministic processes, i.e. where the outcome may not only depend on the agents' actions but may also involve an element of chance.

Gibbard's theorem assumes the collective decision results in exactly one winner and does not apply to multi-winner voting. A similar result for multi-winner voting is the Duggan–Schwartz theorem.

Overview

Consider some voters $1$ , $2$ and $3$ who wish to select an option among three alternatives: $a$ , $b$ and $c$ . Assume they use approval voting: each voter assigns to each candidate the grade 1 (approval) or 0 (withhold approval). For example, $(1,1,0)$ is an authorized ballot: it means that the voter approves of candidates $a$ and $b$ but does not approve of candidate $c$ . Once the ballots are collected, the candidate with highest total grade is declared the winner. Ties between candidates are broken by alphabetical order: for example, if there is a tie between candidates $a$ and $b$ , then $a$ wins.

Assume that voter $1$ prefers alternative $a$ , then $b$ and then $c$ . Which ballot will best defend her opinions? For example, consider the two following situations.

If the two other voters respectively cast ballots $(0,1,1)$ and $(1,1,1)$ , then voter $1$ has only one ballot that leads to the election of her favorite alternative $a$ : $(1,0,0)$ .
However, if we assume instead that the two other voters respectively cast ballots $(0,0,1)$ and $(0,1,1)$ , then voter $1$ should not vote $(1,0,0)$ because it makes $c$ win; she should rather vote $(1,1,0)$ , which makes $b$ win.

To sum up, voter $1$ faces a strategic voting dilemma: depending on the ballots that the other voters will cast, $(1,0,0)$ or $(1,1,0)$ can be a ballot that best defends her opinions. We then say that approval voting is not strategyproof: once the voter has identified her own preferences, she does not have a ballot at her disposal that best defends her opinions in all situations; she needs to act strategically, possibly by spying over the other voters to determine how they intend to vote.

Gibbard's theorem states that a deterministic process of collective decision cannot be strategyproof, except possibly in two cases: if there is a distinguished agent who has a dictatorial power (unilateral), or if the process limits the outcome to two possible options only (duple).

Formal statement

Let ${\mathcal {A}}$ be the set of alternatives, which can also be called candidates in a context of voting. Let ${\mathcal {N}}=\{1,\ldots ,n\}$ be the set of agents, which can also be called players or voters, depending on the context of application. For each agent $i$ , let ${\mathcal {S}}_{i}$ be a set that represents the available strategies for agent $i$ ; assume that ${\mathcal {S}}_{i}$ is finite. Let $g$ be a function that, to each $n$ -tuple of strategies $(s_{1},\ldots ,s_{n})\in {\mathcal {S}}_{1}\times \cdots \times {\mathcal {S}}_{n}$ , maps an alternative. The function $g$ is called a game form. In other words, a game form is essentially defined like an n-player game, but with no utilities associated to the possible outcomes: it describes the procedure only, without specifying a priori the gain that each agent would get from each outcome.

We say that $g$ is strategyproof (originally called: straightforward) if for any agent $i$ and for any strict weak order $P_{i}$ over the alternatives, there exists a strategy $s_{i}^{*}(P_{i})$ that is dominant for agent $i$ when she has preferences $P_{i}$ : there is no profile of strategies for the other agents such that another strategy $s_{i}$ , different from $s_{i}^{*}(P_{i})$ , would lead to a strictly better outcome (in the sense of $P_{i}$ ). This property is desirable for a democratic decision process: it means that once the agent $i$ has identified her own preferences $P_{i}$ , she can choose a strategy $s_{i}^{*}(P_{i})$ that best defends her preferences, with no need to know or guess the strategies chosen by the other agents.

We let ${\mathcal {S}}={\mathcal {S}}_{1}\times \cdots \times {\mathcal {S}}_{n}$ and denote by $g({\mathcal {S}})$ the range of $g$ , i.e. the set of the possible outcomes of the game form. For example, we say that $g$ has at least 3 possible outcomes if and only if the cardinality of $g({\mathcal {S}})$ is 3 or more. Since the strategy sets are finite, $g({\mathcal {S}})$ is finite also; thus, even if the set of alternatives ${\mathcal {A}}$ is not assumed to be finite, the subset of possible outcomes $g({\mathcal {S}})$ is necessarily so.

We say that $g$ is dictatorial if there exists an agent $i$ who is a dictator, in the sense that for any possible outcome $a\in g({\mathcal {S}})$ , agent $i$ has a strategy at her disposal that ensures that the result is $a$ , whatever the strategies chosen by the other agents.

Gibbard's theorem — If a game form is not dictatorial and has at least 3 possible outcomes, then it is not strategyproof.

Examples

Serial dictatorship

We assume that each voter communicates a strict weak order over the candidates. The serial dictatorship is defined as follows. If voter 1 has a unique most-liked candidate, then this candidate is elected. Otherwise, possible outcomes are restricted to his equally most-liked candidates and the other candidates are eliminated. Then voter 2's ballot is examined: if he has a unique best-liked candidate among the non-eliminated ones, then this candidate is elected. Otherwise, the list of possible outcomes is reduced again, etc. If there is still several non-eliminated candidates after all ballots have been examined, then an arbitrary tie-breaking rule is used.

This game form is strategyproof: whatever the preferences of a voter, he has a dominant strategy that consists in declaring his sincere preference order. It is also dictatorial, and its dictator is voter 1: if he wishes to see candidate $a$ elected, then he just has to communicate a preference order where $a$ is the unique most-liked candidate.

Simple majority vote

If there are only 2 possible outcomes, a game form may be strategyproof and not dictatorial. For example, it is the case of the simple majority vote: each voter casts a ballot for her most-liked alternative (among the two possible outcomes), and the alternative with most votes is declared the winner. This game form is strategyproof because it is always optimal to vote for one's most-liked alternative (unless one is indifferent between them). However, it is clearly not dictatorial. Many other game forms are strategyproof and not dictatorial: for example, assume that the alternative $a$ wins if it gets two thirds of the votes, and $b$ wins otherwise.

A game form showing that the converse does not hold

Consider the following game form. Voter 1 can vote for a candidate of her choice, or she can abstain. In the first case, the specified candidate is automatically elected. Otherwise, the other voters use a classic voting rule, for example the Borda count. This game form is clearly dictatorial, because voter 1 can impose the result. However, it is not strategyproof: the other voters face the same issue of strategic voting as in the usual Borda count. Thus, Gibbard's theorem is an implication and not an equivalence.

Extensions

Gibbard's 1978 theorem states that a nondeterministic voting method is only strategyproof if it's a mixture of unilateral and duple rules. For instance, the rule that flips a coin and chooses a random dictator if the coin lands on heads, or chooses the pairwise winner between two random candidates if the coin lands on tails, is strategyproof. Nondeterministic methods have been devised that approximate the results of deterministic methods while being strategyproof. ^[5]^[6]

Notes and references

↑ The terminology for this varies. Gibbard states that 'an individual "manipulates" the voting scheme if, by misrepresenting his preferences, he secures an outcome he prefers to the "honest" outcome', while Brams and Fishburn call every ballot with an honest ordering "sincere."^[2]

↑ Gibbard, Allan (1973). "Manipulation of voting schemes: A general result" (PDF). Econometrica. 41 (4): 587–601. doi:10.2307/1914083. JSTOR 1914083.
↑ Brams, Steven J.; Fishburn, Peter C. (1978). "Approval Voting". American Political Science Review. 72 (3): 831–847. doi:10.2307/1955105. ISSN 0003-0554. JSTOR 1955105.
↑ Gibbard, Allan (1978). "Straightforwardness of Game Forms with Lotteries as Outcomes" (PDF). Econometrica. 46 (3): 595–614. doi:10.2307/1914235. hdl:10419/220562. JSTOR 1914235.^{[ permanent dead link ]}
↑ Hylland, Aanund. Strategy proofness of voting procedures with lotteries as outcomes and infinite sets of strategies, 1980.
↑ Procaccia, Ariel (2010-07-04). "Can Approximation Circumvent Gibbard-Satterthwaite?". Proceedings of the AAAI Conference on Artificial Intelligence. 24 (1). Association for the Advancement of Artificial Intelligence (AAAI): 836–841. doi: 10.1609/aaai.v24i1.7619 . ISSN 2374-3468.
↑ Filos-Ratsikas, Aris; Miltersen, Peter Bro (2014). "Truthful Approximations to Range Voting". Web and Internet Economics. Vol. 8877. Cham: Springer International Publishing. p. 175–188. doi:10.1007/978-3-319-13129-0_13. ISBN 978-3-319-13128-3.

Related Research Articles

<span class="mw-page-title-main">Arrow's impossibility theorem</span> Proof all ranked voting rules have spoilers

Arrow's impossibility theorem is a key result in social choice theory, showing that no ranking-based decision rule can satisfy the requirements of rational choice theory. Most notably, Arrow showed that no such rule can satisfy independence of irrelevant alternatives, the principle that a choice between two alternatives $A$ and $B$ should not depend on the quality of some third, unrelated option $C$ .

The Gibbard–Satterthwaite theorem is a theorem in voting theory. It was first conjectured by the philosopher Michael Dummett and the mathematician Robin Farquharson in 1961 and then proved independently by the philosopher Allan Gibbard in 1973 and economist Mark Satterthwaite in 1975. It deals with deterministic ordinal electoral systems that choose a single winner, and shows that for every voting rule of this form, at least one of the following three things must hold:

The rule is dictatorial, i.e. there exists a distinguished voter who can choose the winner; or
The rule limits the possible outcomes to two alternatives only; or
The rule is not straightforward, i.e. there is no single always-best strategy.

<span class="mw-page-title-main">Random ballot</span> Electoral system with lottery among ballots

A random ballot or random dictatorship is a randomized electoral system where the election is decided on the basis of a single randomly-selected ballot. A closely-related variant is called random serialdictatorship, which repeats the procedure and draws another ballot if multiple candidates are tied on the first ballot.

<span class="mw-page-title-main">May's theorem</span> Social choice theorem on superiority of majority voting

In social choice theory, May's theorem, also called the general possibility theorem, says that majority vote is the unique ranked social choice function between two candidates that satisfies the following criteria:

In mechanism design, a strategyproof (SP) mechanism is a game form in which each player has a weakly-dominant strategy, so that no player can gain by "spying" over the other players to know what they are going to play. When the players have private information, and the strategy space of each player consists of the possible information values, a truthful mechanism is a game in which revealing the true information is a weakly-dominant strategy for each player. An SP mechanism is also called dominant-strategy-incentive-compatible (DSIC), to distinguish it from other kinds of incentive compatibility.

<span class="mw-page-title-main">Social choice theory</span> Academic discipline

Social choice theory is a branch of welfare economics that analyzes methods of combining individual opinions, beliefs, or preferences to reach a collective decision or create measures of social well-being. It contrasts with political science in that it is a normative field that studies how societies should make decisions, whereas political science is descriptive. Social choice incorporates insights from economics, mathematics, philosophy, political science, and game theory to find the best ways to combine individual preferences into a coherent whole, called a social welfare function.

Allan Fletcher Gibbard is the Richard B. Brandt Distinguished University Professor of Philosophy Emeritus at the University of Michigan, Ann Arbor. Gibbard has made major contributions to contemporary ethical theory, in particular metaethics, where he has developed a contemporary version of non-cognitivism. He has also published articles in the philosophy of language, metaphysics, and social choice theory: in social choice, he first proved the result known today as Gibbard-Satterthwaite theorem, which had been previously conjectured by Michael Dummett and Robin Farquharson.

In game theory and economics, a mechanism is called incentive-compatible (IC) if every participant can achieve their own best outcome by reporting their true preferences. For example, there is incentive compatibility if high-risk clients are better off in identifying themselves as high-risk to insurance firms, who only sell discounted insurance to high-risk clients. Likewise, they would be worse off if they pretend to be low-risk. Low-risk clients who pretend to be high-risk would also be worse off. The concept is attributed to the Russian-born American economist Leonid Hurwicz.

The Duggan–Schwartz theorem is a result about voting systems designed to choose a nonempty set of winners from the preferences of certain individuals, where each individual ranks all candidates in order of preference. It states that for three or more candidates, at least one of the following must hold:

The system is not anonymous.
The system is imposed.
Every voter's top preference is in the set of winners.
The system can be manipulated by either an optimistic voter, one who can cast a ballot that would elect some candidate to a higher rank than all of those candidates who would have been elected if that voter had voted honestly; or by a pessimistic voter, one who can cast a ballot that would exclude some candidate to a lower rank than all of those candidates who were elected due that voter voting strategically.

The revelation principle is a fundamental result in mechanism design, social choice theory, and game theory which shows it is always possible to design a strategy-resistant implementation of a social decision-making mechanism. It can be seen as a kind of mirror image to Gibbard's theorem. The revelation principle says that if a social choice function can be implemented with some non-honest mechanism—one where players have an incentive to lie—the same function can be implemented by an incentive-compatible (honesty-promoting) mechanism with the same equilibrium outcome (payoffs).

<span class="mw-page-title-main">Dictatorship mechanism</span> Theoretical rule in social choice theory

In social choice theory, a dictatorship mechanism is a degenerate voting rule or mechanism where the result depends on only one person's preferences, without considering any other voters. A serial dictatorship is similar, but also designates a series of "backup dictators", who break ties in the original dictator's choices when the dictator is indifferent.

In cooperative game theory and social choice theory, the Nakamura number measures the degree of rationality of preference aggregation rules, such as voting rules. It is an indicator of the extent to which an aggregation rule can yield well-defined choices.

<span class="mw-page-title-main">Rated voting</span> Electoral systems with independent candidate ratings

Rated, evaluative, graded, or cardinalvotingrules are a class of voting methods that allow voters to state how strongly they support a candidate, by giving each one a grade on a separate scale.

Arunava Sen is a professor of economics at the Indian Statistical Institute. He works on Game Theory, Social Choice Theory, Mechanism Design, Voting and Auctions.

<span class="mw-page-title-main">Maximal lotteries</span> Probabilistic Condorcet method

Maximal lotteries refers to a probabilistic voting rule. The method uses preferential ballots and returns a probability distribution of candidates that a majority of voters would weakly prefer to any other.

In economics, dichotomous preferences (DP) are preference relations that divide the set of alternatives to two subsets, "Good" and "Bad".

<span class="mw-page-title-main">Fractional social choice</span>

Fractional, stochastic, or weighted social choice is a branch of social choice theory in which the collective decision is not a single alternative, but rather a weighted sum of two or more alternatives. For example, if society has to choose between three candidates, then in standard social choice exactly one of these candidates is chosen. By contrast, in fractional social choice it is possible to choose any linear combination of these, e.g. "2/3 of A and 1/3 of B".

Budget-proposal aggregation (BPA) is a problem in social choice theory. A group has to decide on how to distribute its budget among several issues. Each group-member has a different idea about what the ideal budget-distribution should be. The problem is how to aggregate the different opinions into a single budget-distribution program.

The median voting rule or median mechanism is a rule for group decision-making along a one-dimensional domain. Each person votes by writing down his/her ideal value, and the rule selects a single value which is the median of all votes.

In mechanism design, a regret-free truth-telling mechanism is a mechanism in which each player who reveals his true private information does not feel regret after seeing the mechanism outcome. A regret-free mechanism incentivizes agents who want to avoid regret to report their preferences truthfully.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[3] The terminology for this varies. Gibbard states that 'an individual "manipulates" the voting scheme if, by misrepresenting his preferences, he secures an outcome he prefers to the "honest" outcome', while Brams and Fishburn call every ballot with an honest ordering "sincere."^[2]

[1] Gibbard, Allan (1973). "Manipulation of voting schemes: A general result" (PDF). Econometrica. 41 (4): 587–601. doi:10.2307/1914083. JSTOR 1914083.

[BramsApproval-2] Brams, Steven J.; Fishburn, Peter C. (1978). "Approval Voting". American Political Science Review. 72 (3): 831–847. doi:10.2307/1955105. ISSN 0003-0554. JSTOR 1955105.

[4] Gibbard, Allan (1978). "Straightforwardness of Game Forms with Lotteries as Outcomes" (PDF). Econometrica. 46 (3): 595–614. doi:10.2307/1914235. hdl:10419/220562. JSTOR 1914235.^{[ permanent dead link ]}

[5] Hylland, Aanund. Strategy proofness of voting procedures with lotteries as outcomes and infinite sets of strategies, 1980.

[e363-6] Procaccia, Ariel (2010-07-04). "Can Approximation Circumvent Gibbard-Satterthwaite?". Proceedings of the AAAI Conference on Artificial Intelligence. 24 (1). Association for the Advancement of Artificial Intelligence (AAAI): 836–841. doi: 10.1609/aaai.v24i1.7619 . ISSN 2374-3468.

[k419-7] Filos-Ratsikas, Aris; Miltersen, Peter Bro (2014). "Truthful Approximations to Range Voting". Web and Internet Economics. Vol. 8877. Cham: Springer International Publishing. p. 175–188. doi:10.1007/978-3-319-13129-0_13. ISBN 978-3-319-13128-3.

[1]

[note 1]

[3]

[4]

[5]

[6]

[2]