Quadratic optimization models for balancing preferential access and fairness: formulations and optimality conditions
Quadratic optimization models for balancing preferential access and fairness: formulations and optimality conditions
Typically, within facility location problems, fairness is defined in terms of accessibility of users. However, for facilities perceived as undesirable by communities hosting them, fairness between the usage of facilities becomes especially important. Limited research exists on this notion of fairness. To close this gap, we develop a series of optimization models for the allocation of populations of users to facilities such that access for users is balanced with a fair utilization of facilities. The optimality conditions of the underlying nonconvex quadratic models state the precise balance between accessibility and fairness. We define new classes of fairness and a metric to quantify the extent to which fairness is achieved in both optimal and suboptimal allocations. We show that a continuous relaxation of our central model is sufficient to achieve a perfect extent of fairness, while a special case reduces to the classical notion of proportional fairness. Our work is motivated by pervasive ecological challenges faced by the waste management community as policymakers seek to reduce the number of recycling centers in the last few years. As a computational case study, applying our models on data for the state of Bavaria in Germany, we find that even after the closure of a moderate number of recycling centers, large degrees of access can be ensured, provided that the closures are conducted optimally. Fairness, however, is impacted more, with facilities in rural regions shouldering larger loads of visiting populations than those in urban regions.
Schmitt, Christian
bfcc8f5c-f77d-428c-8890-22a530a59526
Singh, Bismark
9d3fc6cb-f55e-4562-9d5f-42f9a3ddd9a1
19 February 2024
Schmitt, Christian
bfcc8f5c-f77d-428c-8890-22a530a59526
Singh, Bismark
9d3fc6cb-f55e-4562-9d5f-42f9a3ddd9a1
Schmitt, Christian and Singh, Bismark
(2024)
Quadratic optimization models for balancing preferential access and fairness: formulations and optimality conditions.
INFORMS Journal on Computing.
(doi:10.1287/ijoc.2022.0308).
Abstract
Typically, within facility location problems, fairness is defined in terms of accessibility of users. However, for facilities perceived as undesirable by communities hosting them, fairness between the usage of facilities becomes especially important. Limited research exists on this notion of fairness. To close this gap, we develop a series of optimization models for the allocation of populations of users to facilities such that access for users is balanced with a fair utilization of facilities. The optimality conditions of the underlying nonconvex quadratic models state the precise balance between accessibility and fairness. We define new classes of fairness and a metric to quantify the extent to which fairness is achieved in both optimal and suboptimal allocations. We show that a continuous relaxation of our central model is sufficient to achieve a perfect extent of fairness, while a special case reduces to the classical notion of proportional fairness. Our work is motivated by pervasive ecological challenges faced by the waste management community as policymakers seek to reduce the number of recycling centers in the last few years. As a computational case study, applying our models on data for the state of Bavaria in Germany, we find that even after the closure of a moderate number of recycling centers, large degrees of access can be ensured, provided that the closures are conducted optimally. Fairness, however, is impacted more, with facilities in rural regions shouldering larger loads of visiting populations than those in urban regions.
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Accepted/In Press date: 28 January 2024
Published date: 19 February 2024
Identifiers
Local EPrints ID: 487442
URI: http://eprints.soton.ac.uk/id/eprint/487442
ISSN: 1091-9856
PURE UUID: e17ffa66-c37d-470c-abbf-7bfce74b6cbd
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Date deposited: 20 Feb 2024 13:09
Last modified: 18 Mar 2024 04:08
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Author:
Christian Schmitt
Author:
Bismark Singh
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