Tensorized Multi-Task Learning for Personalized Modeling of Heterogeneous Individuals with High-Dimensional Data

Computer Vision & MultiModal AI

Published: arXiv: 2508.15676v1

Authors

Elif Konyar Mostafa Reisi Gahrooei Kamran Paynabar

Abstract

Effective modeling of heterogeneous subpopulations presents a significant challenge due to variations in individual characteristics and behaviors. This paper proposes a novel approach to address this issue through multi-task learning (MTL) and low-rank tensor decomposition techniques. Our MTL approach aims to enhance personalized modeling by leveraging shared structures among similar tasks while accounting for distinct subpopulation-specific variations. We introduce a framework where low-rank decomposition decomposes the collection of task model parameters into a low-rank structure that captures commonalities and variations across tasks and subpopulations. This approach allows for efficient learning of personalized models by sharing knowledge between similar tasks while preserving the unique characteristics of each subpopulation. Experimental results in simulation and case study datasets demonstrate the superior performance of the proposed method compared to several benchmarks, particularly in scenarios with high variability among subpopulations. The proposed framework not only improves prediction accuracy but also enhances interpretability by revealing underlying patterns that contribute to the personalization of models.

Paper Summary

Problem

Effective modeling of heterogeneous subpopulations is a significant challenge due to variations in individual characteristics and behaviors. In many real-world applications, such as precision medicine and healthcare, it's difficult to gather a large sample size for each individual, making it hard to create personalized models that account for unique traits and variations between individuals.

Key Innovation

This research proposes a novel approach called Tensorized Multi-Task Learning (TenMTL), which combines low-rank tensor decomposition with multi-task learning to enhance personalized modeling across heterogeneous subpopulations. TenMTL represents the collection of task-specific model parameters as a higher-order tensor, which is then decomposed using Tucker decomposition. This allows for joint modeling of shared structures across tasks and individual-level variations, making it scalable and interpretable.

Practical Impact

TenMTL has the potential to improve predictive performance and interpretability in various fields, including precision medicine, healthcare, and human-robot interaction. By revealing latent components that capture commonalities and heterogeneity across tasks, TenMTL can help researchers and clinicians better understand the underlying patterns that contribute to personalization of models. This can lead to more accurate predictions and better decision-making in real-world applications.

Analogy / Intuitive Explanation

Imagine you're trying to create a personalized fitness plan for a group of people with different fitness levels and goals. A global model that aggregates data from all individuals might not capture the unique characteristics and variations between them. TenMTL is like a special kind of "personal trainer" that uses tensor decomposition to identify shared structures and individual-level variations, allowing it to create personalized plans that account for each person's unique needs and goals.

Paper Information

Categories:

cs.LG stat.ML

Published Date:

arXiv ID:

2508.15676v1

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