@InProceedings{DiekhoffKirstenKraemer2020,
author = {Karsten Diekhoff and
Michael Kirsten and
Jonas Kr{\"{a}}mer},
title = {Verified Construction of Fair Voting Rules},
booktitle = {29th International Symposium on Logic-Based Program
Synthesis and Transformation ({LOPSTR} 2019),
Revised Selected Papers},
venue = {Porto, Portugal},
eventdate = {2020-10-08/2020-10-10},
series = {Lecture Notes in Computer Science},
editor = {Maurizio Gabbrielli},
year = {2020},
month = apr,
abstract = {Voting rules aggregate multiple individual preferences in order to
make collective decisions. Commonly, these mechanisms are expected
to respect a multitude of different fairness and reliability
properties, e.g., to ensure that each voter's ballot accounts for
the same proportion of the elected alternatives, or that a voter
cannot change the election outcome in her favor by insincerely
filling out her ballot. However, no voting rule is fair in all
respects, and trade-off attempts between such properties often
bring out inconsistencies, which makes the construction of arguably
practical and fair voting rules non-trivial and error-prone.
\newline
In this paper, we present a formal and systematic approach for the
flexible and verified construction of voting rules from composable
core modules to respect such properties by construction. Formal
composition rules guarantee resulting properties from properties of
the individual components, which are of generic nature to be reused
for various voting rules. We provide a prototypical logic-based
implementation with proofs for a selected set of structures and
composition rules within the theorem prover Isabelle/HOL. The
approach can be readily extended in order to support many voting
rules from the literature by extending the set of basic modules and
composition rules. We exemplarily construct the well-known voting
rule sequential majority comparison (SMC) from simple generic
modules, and automatically produce a formal proof that SMC
satisfies the fairness property monotonicity. Monotonicity is a
well-known social-choice property that is easily violated by voting
rules in practice.},
publisher = {Springer},
doi = {10.1007/978-3-030-45260-5_6},
volume = {12042},
pages = {90--104}
}
Verified Construction of Fair Voting Rules
| Author(s): | Karsten Diekhoff, Michael Kirsten, and Jonas Krämer |
|---|---|
| In: | 29th International Symposium on Logic-Based Program Synthesis and Transformation (LOPSTR 2019), Revised Selected Papers |
| Publisher: | Springer |
| Series: | Lecture Notes in Computer Science |
| Volume: | 12042 |
| Year: | 2020 |
| Pages: | 90-104 |
| DOI: | 10.1007/978-3-030-45260-5_6 |
Abstract
Voting rules aggregate multiple individual preferences in order to
make collective decisions. Commonly, these mechanisms are expected
to respect a multitude of different fairness and reliability
properties, e.g., to ensure that each voter's ballot accounts for
the same proportion of the elected alternatives, or that a voter
cannot change the election outcome in her favor by insincerely
filling out her ballot. However, no voting rule is fair in all
respects, and trade-off attempts between such properties often
bring out inconsistencies, which makes the construction of arguably
practical and fair voting rules non-trivial and error-prone.
In this paper, we present a formal and systematic approach for the
flexible and verified construction of voting rules from composable
core modules to respect such properties by construction. Formal
composition rules guarantee resulting properties from properties of
the individual components, which are of generic nature to be reused
for various voting rules. We provide a prototypical logic-based
implementation with proofs for a selected set of structures and
composition rules within the theorem prover Isabelle/HOL. The
approach can be readily extended in order to support many voting
rules from the literature by extending the set of basic modules and
composition rules. We exemplarily construct the well-known voting
rule sequential majority comparison (SMC) from simple generic
modules, and automatically produce a formal proof that SMC
satisfies the fairness property monotonicity. Monotonicity is a
well-known social-choice property that is easily violated by voting
rules in practice.