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Main Authors: Banerjee, Amartya, Hazard, Christopher J., Beel, Jacob, Mack, Cade, Xia, Jack, Resnick, Michael, Goddin, Will
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2311.10246
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author Banerjee, Amartya
Hazard, Christopher J.
Beel, Jacob
Mack, Cade
Xia, Jack
Resnick, Michael
Goddin, Will
author_facet Banerjee, Amartya
Hazard, Christopher J.
Beel, Jacob
Mack, Cade
Xia, Jack
Resnick, Michael
Goddin, Will
contents Nonparametric learning is a fundamental concept in machine learning that aims to capture complex patterns and relationships in data without making strong assumptions about the underlying data distribution. Owing to simplicity and familiarity, one of the most well-known algorithms under this paradigm is the $k$-nearest neighbors ($k$-NN) algorithm. Driven by the usage of machine learning in safety-critical applications, in this work, we shed new light on the traditional nearest neighbors algorithm from the perspective of information theory and propose a robust and interpretable framework for tasks such as classification, regression, density estimation, and anomaly detection using a single model. We can determine data point weights as well as feature contributions by calculating the conditional entropy for adding a feature without the need for explicit model training. This allows us to compute feature contributions by providing detailed data point influence weights with perfect attribution and can be used to query counterfactuals. Instead of using a traditional distance measure which needs to be scaled and contextualized, we use a novel formulation of $\textit{surprisal}$ (amount of information required to explain the difference between the observed and expected result). Finally, our work showcases the architecture's versatility by achieving state-of-the-art results in classification and anomaly detection, while also attaining competitive results for regression across a statistically significant number of datasets.
format Preprint
id arxiv_https___arxiv_org_abs_2311_10246
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Surprisal Driven $k$-NN for Robust and Interpretable Nonparametric Learning
Banerjee, Amartya
Hazard, Christopher J.
Beel, Jacob
Mack, Cade
Xia, Jack
Resnick, Michael
Goddin, Will
Machine Learning
Artificial Intelligence
Nonparametric learning is a fundamental concept in machine learning that aims to capture complex patterns and relationships in data without making strong assumptions about the underlying data distribution. Owing to simplicity and familiarity, one of the most well-known algorithms under this paradigm is the $k$-nearest neighbors ($k$-NN) algorithm. Driven by the usage of machine learning in safety-critical applications, in this work, we shed new light on the traditional nearest neighbors algorithm from the perspective of information theory and propose a robust and interpretable framework for tasks such as classification, regression, density estimation, and anomaly detection using a single model. We can determine data point weights as well as feature contributions by calculating the conditional entropy for adding a feature without the need for explicit model training. This allows us to compute feature contributions by providing detailed data point influence weights with perfect attribution and can be used to query counterfactuals. Instead of using a traditional distance measure which needs to be scaled and contextualized, we use a novel formulation of $\textit{surprisal}$ (amount of information required to explain the difference between the observed and expected result). Finally, our work showcases the architecture's versatility by achieving state-of-the-art results in classification and anomaly detection, while also attaining competitive results for regression across a statistically significant number of datasets.
title Surprisal Driven $k$-NN for Robust and Interpretable Nonparametric Learning
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2311.10246