Random ballot
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 serial 'dictatorship', which repeats the procedure and draws another ballot if multiple candidates are tied on the first ballot.
Random dictatorship was first described in 1977 by Allan Gibbard, who showed it to be the unique social choice rule that treats all voters equally while still being strategyproof in all situations. Its application to elections was first described in 1984 by Akhil Reed Amar.
The rule is rarely, if ever, proposed as a genuine electoral system, as such a method "leaves too much to chance". However, the rule is often used as a tiebreaker to encourage voters to cast honest ballots, and is sometimes discussed as a thought experiment.
Random dictatorship and random serial dictatorship
The dictatorship rule is obviously unfair, but it has a variant that is fair in expectation. In the random dictatorship rule, one of the voters is selected uniformly at random, and the alternative most preferred by that voter is selected. This is one of the common rules for random social choice. When used in multi-constituency bodies, it is sometimes called random ballot.Similarly to dictatorship, random dictatorship too should handle the possibility of indifferences; the common solution is to extend it to random serial dictatorship, also called random priority. In this mechanism, a random permutation of the voters is selected, and each voter in turn narrows the existing alternatives to the ones they most prefer, from the ones still available. It is a common mechanism in allocating indivisible objects among agents; see random priority item allocation.
Properties
proved the random dictatorship theorem. It says that RD is the only rule that satisfies the following three properties:- Anonymity: the lottery does not discriminate in advance between different voters.
- Strategyproofness: any false report by an agent results in an outcome that is weakly stochastically dominated.
- Ex post Pareto-efficiency: the outcome is Pareto-efficient.
- * In fact, with strict preferences, RD satisfies a stronger efficiency property called SD-efficiency: the resulting lottery is not stochastically dominated. With weak preferences, RSD satisfies ex-post efficiency, but violates SD-efficiency.
- * Even with strict preferences, RD violates the stronger property called PC-efficiency: the resulting lottery might be dominated in the sense of pairwise-comparisons.
- Strong contraction consistency : probabilities cannot decrease when removing arbitrary alternatives.
- Ex-post efficiency.
- A probabilistic version of independence of irrelevant alternatives.
RD satisfies an axiom called population consistency, and an axiom called cloning-consistency, but violates composition consistency.
Computation
It is easy to implement both the RD and the RSD mechanisms in practice: just pick a random voter, or a random permutation, and let each dictator in turn pick the best option. However, sometimes one wants to compute in advance, what is the probability that a certain alternative would be chosen. With RD, this is easy too: the probability that alternative x is chosen equals the number of voters who rank x first, divided by the total number of voters. But the situation is different with RSD :- Computing the probabilities is #P-hard;
- There is an efficient algorithm for computing the support ;
- There are algorithms with tractable parameterized complexity, where the parameters are: number of objects, number of alternatives, and number of voter types.
- There is an exponential-time algorithm for computing the probabilities in the context of fractional approval voting.
For multimember bodies
For example, say a minority party has 1% of the vote. This party would, in a 50-person assembly, have a vanishingly small chance of winning a majority. Using the binomial distribution, the probability is given by: