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Autori principali: Mlodozeniec, Bruno, Reid, Isaac, Power, Sam, Krueger, David, Erdogdu, Murat, Turner, Richard E., Grosse, Roger
Natura: Preprint
Pubblicazione: 2025
Soggetti:
Accesso online:https://arxiv.org/abs/2506.12965
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author Mlodozeniec, Bruno
Reid, Isaac
Power, Sam
Krueger, David
Erdogdu, Murat
Turner, Richard E.
Grosse, Roger
author_facet Mlodozeniec, Bruno
Reid, Isaac
Power, Sam
Krueger, David
Erdogdu, Murat
Turner, Richard E.
Grosse, Roger
contents Randomness is an unavoidable part of training deep learning models, yet something that traditional training data attribution algorithms fail to rigorously account for. They ignore the fact that, due to stochasticity in the initialisation and batching, training on the same dataset can yield different models. In this paper, we address this shortcoming through introducing distributional training data attribution (d-TDA), the goal of which is to predict how the distribution of model outputs (over training runs) depends upon the dataset. Intriguingly, we find that influence functions (IFs), a popular data attribution tool, are 'secretly distributional': they emerge from our framework as the limit to unrolled differentiation, without requiring restrictive convexity assumptions. This provides a new perspective on the effectiveness of IFs in deep learning. We demonstrate the practical utility of d-TDA in experiments, including improving data pruning for vision transformers and identifying influential examples with diffusion models.
format Preprint
id arxiv_https___arxiv_org_abs_2506_12965
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Distributional Training Data Attribution: What do Influence Functions Sample?
Mlodozeniec, Bruno
Reid, Isaac
Power, Sam
Krueger, David
Erdogdu, Murat
Turner, Richard E.
Grosse, Roger
Machine Learning
Artificial Intelligence
Randomness is an unavoidable part of training deep learning models, yet something that traditional training data attribution algorithms fail to rigorously account for. They ignore the fact that, due to stochasticity in the initialisation and batching, training on the same dataset can yield different models. In this paper, we address this shortcoming through introducing distributional training data attribution (d-TDA), the goal of which is to predict how the distribution of model outputs (over training runs) depends upon the dataset. Intriguingly, we find that influence functions (IFs), a popular data attribution tool, are 'secretly distributional': they emerge from our framework as the limit to unrolled differentiation, without requiring restrictive convexity assumptions. This provides a new perspective on the effectiveness of IFs in deep learning. We demonstrate the practical utility of d-TDA in experiments, including improving data pruning for vision transformers and identifying influential examples with diffusion models.
title Distributional Training Data Attribution: What do Influence Functions Sample?
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2506.12965