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Main Authors: Pagan, Nicolò, Baumann, Joachim, Elokda, Ezzat, De Pasquale, Giulia, Bolognani, Saverio, Hannák, Anikó
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2305.06055
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author Pagan, Nicolò
Baumann, Joachim
Elokda, Ezzat
De Pasquale, Giulia
Bolognani, Saverio
Hannák, Anikó
author_facet Pagan, Nicolò
Baumann, Joachim
Elokda, Ezzat
De Pasquale, Giulia
Bolognani, Saverio
Hannák, Anikó
contents Prediction-based decision-making systems are becoming increasingly prevalent in various domains. Previous studies have demonstrated that such systems are vulnerable to runaway feedback loops, e.g., when police are repeatedly sent back to the same neighborhoods regardless of the actual rate of criminal activity, which exacerbate existing biases. In practice, the automated decisions have dynamic feedback effects on the system itself that can perpetuate over time, making it difficult for short-sighted design choices to control the system's evolution. While researchers started proposing longer-term solutions to prevent adverse outcomes (such as bias towards certain groups), these interventions largely depend on ad hoc modeling assumptions and a rigorous theoretical understanding of the feedback dynamics in ML-based decision-making systems is currently missing. In this paper, we use the language of dynamical systems theory, a branch of applied mathematics that deals with the analysis of the interconnection of systems with dynamic behaviors, to rigorously classify the different types of feedback loops in the ML-based decision-making pipeline. By reviewing existing scholarly work, we show that this classification covers many examples discussed in the algorithmic fairness community, thereby providing a unifying and principled framework to study feedback loops. By qualitative analysis, and through a simulation example of recommender systems, we show which specific types of ML biases are affected by each type of feedback loop. We find that the existence of feedback loops in the ML-based decision-making pipeline can perpetuate, reinforce, or even reduce ML biases.
format Preprint
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institution arXiv
publishDate 2023
record_format arxiv
spellingShingle A Classification of Feedback Loops and Their Relation to Biases in Automated Decision-Making Systems
Pagan, Nicolò
Baumann, Joachim
Elokda, Ezzat
De Pasquale, Giulia
Bolognani, Saverio
Hannák, Anikó
Computers and Society
Machine Learning
Prediction-based decision-making systems are becoming increasingly prevalent in various domains. Previous studies have demonstrated that such systems are vulnerable to runaway feedback loops, e.g., when police are repeatedly sent back to the same neighborhoods regardless of the actual rate of criminal activity, which exacerbate existing biases. In practice, the automated decisions have dynamic feedback effects on the system itself that can perpetuate over time, making it difficult for short-sighted design choices to control the system's evolution. While researchers started proposing longer-term solutions to prevent adverse outcomes (such as bias towards certain groups), these interventions largely depend on ad hoc modeling assumptions and a rigorous theoretical understanding of the feedback dynamics in ML-based decision-making systems is currently missing. In this paper, we use the language of dynamical systems theory, a branch of applied mathematics that deals with the analysis of the interconnection of systems with dynamic behaviors, to rigorously classify the different types of feedback loops in the ML-based decision-making pipeline. By reviewing existing scholarly work, we show that this classification covers many examples discussed in the algorithmic fairness community, thereby providing a unifying and principled framework to study feedback loops. By qualitative analysis, and through a simulation example of recommender systems, we show which specific types of ML biases are affected by each type of feedback loop. We find that the existence of feedback loops in the ML-based decision-making pipeline can perpetuate, reinforce, or even reduce ML biases.
title A Classification of Feedback Loops and Their Relation to Biases in Automated Decision-Making Systems
topic Computers and Society
Machine Learning
url https://arxiv.org/abs/2305.06055