The geometry of manipulation - A quantitative proof of the Gibbard-Satterthwaite theorem

Marcus Isaksson; Guy Kindler; Elchanan Mossel

doi:10.1007/s00493-012-2704-1

The geometry of manipulation - A quantitative proof of the Gibbard-Satterthwaite theorem

Marcus Isaksson, Guy Kindler, Elchanan Mossel

The Hebrew University of Jerusalem, Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

We prove a quantitative version of the Gibbard-Satterthwaite theorem. We show that a uniformly chosen voter profile for a neutral social choice function f of q ≥ 4 alternatives and n voters will be manipulable with probability at least 10 ^-4∈ ²n ^-3q ^-30, where ∈ is the minimal statistical distance between f and the family of dictator functions. Our results extend those of [11], which were obtained for the case of 3 alternatives, and imply that the approach of masking manipulations behind computational hardness (as considered in [4,6,9,15,7]) cannot hide manipulations completely. Our proof is geometric. More specifically it extends the method of canonical paths to show that the measure of the profiles that lie on the interface of 3 or more outcomes is large. To the best of our knowledge our result is the first isoperimetric result to establish interface of more than two bodies.

Original language	English
Pages (from-to)	221-250
Number of pages	30
Journal	Combinatorica
Volume	32
Issue number	2
DOIs	https://doi.org/10.1007/s00493-012-2704-1
State	Published - Mar 2012

All Science Journal Classification (ASJC) codes

Discrete Mathematics and Combinatorics
Computational Mathematics

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title = "The geometry of manipulation - A quantitative proof of the Gibbard-Satterthwaite theorem",

abstract = "We prove a quantitative version of the Gibbard-Satterthwaite theorem. We show that a uniformly chosen voter profile for a neutral social choice function f of q ≥ 4 alternatives and n voters will be manipulable with probability at least 10 -4∈ 2n -3q -30, where ∈ is the minimal statistical distance between f and the family of dictator functions. Our results extend those of [11], which were obtained for the case of 3 alternatives, and imply that the approach of masking manipulations behind computational hardness (as considered in [4,6,9,15,7]) cannot hide manipulations completely. Our proof is geometric. More specifically it extends the method of canonical paths to show that the measure of the profiles that lie on the interface of 3 or more outcomes is large. To the best of our knowledge our result is the first isoperimetric result to establish interface of more than two bodies.",

author = "Marcus Isaksson and Guy Kindler and Elchanan Mossel",

note = "Funding Information: ∗ Supported by the Israel Science Foundation and by the Binational Science Foundation. † Supported by DMS 0548249 (CAREER) award, by ISF grant 1300/08, by a Minerva Foundation grant and by an ERC Marie Curie Grant 2008 239317.",

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doi = "10.1007/s00493-012-2704-1",

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AU - Kindler, Guy

AU - Mossel, Elchanan

N1 - Funding Information: ∗ Supported by the Israel Science Foundation and by the Binational Science Foundation. † Supported by DMS 0548249 (CAREER) award, by ISF grant 1300/08, by a Minerva Foundation grant and by an ERC Marie Curie Grant 2008 239317.

PY - 2012/3

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N2 - We prove a quantitative version of the Gibbard-Satterthwaite theorem. We show that a uniformly chosen voter profile for a neutral social choice function f of q ≥ 4 alternatives and n voters will be manipulable with probability at least 10 -4∈ 2n -3q -30, where ∈ is the minimal statistical distance between f and the family of dictator functions. Our results extend those of [11], which were obtained for the case of 3 alternatives, and imply that the approach of masking manipulations behind computational hardness (as considered in [4,6,9,15,7]) cannot hide manipulations completely. Our proof is geometric. More specifically it extends the method of canonical paths to show that the measure of the profiles that lie on the interface of 3 or more outcomes is large. To the best of our knowledge our result is the first isoperimetric result to establish interface of more than two bodies.

AB - We prove a quantitative version of the Gibbard-Satterthwaite theorem. We show that a uniformly chosen voter profile for a neutral social choice function f of q ≥ 4 alternatives and n voters will be manipulable with probability at least 10 -4∈ 2n -3q -30, where ∈ is the minimal statistical distance between f and the family of dictator functions. Our results extend those of [11], which were obtained for the case of 3 alternatives, and imply that the approach of masking manipulations behind computational hardness (as considered in [4,6,9,15,7]) cannot hide manipulations completely. Our proof is geometric. More specifically it extends the method of canonical paths to show that the measure of the profiles that lie on the interface of 3 or more outcomes is large. To the best of our knowledge our result is the first isoperimetric result to establish interface of more than two bodies.

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DO - 10.1007/s00493-012-2704-1

M3 - مقالة

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SP - 221

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JO - Combinatorica

JF - Combinatorica

IS - 2

ER -

The geometry of manipulation - A quantitative proof of the Gibbard-Satterthwaite theorem

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