Computational social choice

Computational social choice[1] is a field at the intersection of social choice theory and (theoretical) computer science (and the study of multi-agent systems). It analyzes problems arising from the aggregation of preferences of a group of agents from a computational perspective. In particular, computational social choice is concerned with the efficient computation of outcomes of voting rules, with the computational complexity of various forms of manipulation, and issues arising from the problem of representing and eliciting preferences in combinatorial settings.

Winner determination

The usefulness of a particular voting system can be severely limited if it takes a very long time to calculate the winner of an election. Therefore it is important to design fast algorithms that can evaluate a voting rule when given ballots as input. As is common in computational complexity, an algorithm is thought to be efficient if it takes polynomial time. Many popular voting systems can be evaluated in polynomial time in a straightforward way (through counting), such as the Borda count, approval voting, or the plurality rule. For rules such as the Schulze method[2] or ranked pairs,[3] more sophisticated algorithms can be used to show polynomial runtime. As first pointed in an influential article in 1989,[4] certain voting systems are computationally difficult to evaluate. In particular, winner determination for the Kemeny-Young method,[4][5] Dodgson's method,[4][6] and Young's method[7] are all NP-hard problems. This has led to the development of approximation algorithms[8][9] and fixed-parameter tractable algorithms.[10]

Hardness of manipulation

By the Gibbard-Satterthwaite theorem, all non-trivial voting rules can be manipulated in the sense that voters can sometimes achieve a better outcome by misrepresenting their preferences, that is, they submit a non-truthful ballot to the voting system. Much effort in social choice theory has been invested in finding ways to circumvent this result. One such possibility was proposed by Bartholdi, Tovey, and Trick in 1989[11] and is based on computational complexity theory. They considered a voting rule called second-order Copeland rule (which can be evaluated in polynomial time), and proved that it is NP-complete for a voter to decide, given knowledge of how everyone else has voted, whether it is possible to manipulate in such a way as to make some favored candidate the winner. The same property holds for single transferable vote.[12]

These results show that (assuming the widely-believed hypothesis that P ≠ NP) there are instances where polynomial time is not enough to establish whether a beneficial manipulation is possible. In this sense, the voting rules that come with an NP-hard manipulation problem are "resistant" to manipulation. One should note that these results only concern the worst-case: it might well be possible that a manipulation problem is usually easy to solve, and only requires superpolynomial time on very unusual inputs.[13]

Other topics

See also

References

  1. 1 2 Brandt, Felix; Conitzer, Vincent; Endriss, Ulle; Lang, Jérôme; Procaccia, Ariel D. (2016-04-25). Handbook of Computational Social Choice. Cambridge University Press. ISBN 9781107060432.
  2. Schulze, Markus (2010-07-11). "A new monotonic, clone-independent, reversal symmetric, and condorcet-consistent single-winner election method". Social Choice and Welfare. 36 (2): 267–303. doi:10.1007/s00355-010-0475-4. ISSN 0176-1714.
  3. Brill, Markus; Fischer, Felix (2012-01-01). "The Price of Neutrality for the Ranked Pairs Method". Proceedings of the Twenty-Sixth AAAI Conference on Artificial Intelligence. AAAI'12. Toronto, Ontario, Canada: AAAI Press: 1299–1305.
  4. 1 2 3 Bartholdi III, J.; Tovey, C. A.; Trick, M. A. (1989-04-01). "Voting schemes for which it can be difficult to tell who won the election". Social Choice and Welfare. 6 (2): 157–165. doi:10.1007/BF00303169. ISSN 0176-1714.
  5. Hemaspaandra, Edith; Spakowski, Holger; Vogel, Jörg (2005-12-16). "The complexity of Kemeny elections". Theoretical Computer Science. 349 (3): 382–391. doi:10.1016/j.tcs.2005.08.031.
  6. Hemaspaandra, Edith; Hemaspaandra, Lane A.; Rothe, Jörg (1997-11-01). "Exact Analysis of Dodgson Elections: Lewis Carroll's 1876 Voting System is Complete for Parallel Access to NP". J. ACM. 44 (6): 806–825. doi:10.1145/268999.269002. ISSN 0004-5411.
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