Saved in:
Bibliographic Details
Main Authors: Son, Jungyong, Jung, Jinwook, Park, Minhee, Baik, Sungyong
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.28444
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910266759839744
author Son, Jungyong
Jung, Jinwook
Park, Minhee
Baik, Sungyong
author_facet Son, Jungyong
Jung, Jinwook
Park, Minhee
Baik, Sungyong
contents Fine-tuning large-scale pre-trained models is a recent prevalent paradigm for adapting general representations to specialized tasks. However, when a new version of a pre-trained model becomes available, expertise acquired through fine-tuning cannot be directly reused because it is tied to the parameterization of the original model, requiring another costly fine-tuning. To address this inefficiency, recent work uses task vectors, defined as the parameter difference between a fine-tuned model and its base model, to transfer expertise across models. While existing methods bridge disparate models by matching activations or gradients, a significant performance gap remains relative to direct fine-tuning, suggesting that these partial correspondences are insufficient. In this work, instead of viewing a task vector merely as a parameter offset, we revisit the formation of task vectors and show that they can be derived as accumulated bilinear interactions between input-side activations and output-side gradients. Motivated by this observation, we formulate task-vector transfer as a dual-space alignment problem and propose BiCo, a training-free framework for transferring task vectors through Bilinear Coordinate alignment. BiCo estimates orthogonal Procrustes mappings in both spaces using a single forward-backward pass on a small calibration set, without any parameter update. Across extensive computer vision and natural language processing benchmarks, BiCo consistently outperforms existing transfer methods across models that differ in width, depth, and pre-training configuration.
format Preprint
id arxiv_https___arxiv_org_abs_2605_28444
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Bilinear Coordinate Alignment for Training-Free Task-Vector Transfer
Son, Jungyong
Jung, Jinwook
Park, Minhee
Baik, Sungyong
Machine Learning
Fine-tuning large-scale pre-trained models is a recent prevalent paradigm for adapting general representations to specialized tasks. However, when a new version of a pre-trained model becomes available, expertise acquired through fine-tuning cannot be directly reused because it is tied to the parameterization of the original model, requiring another costly fine-tuning. To address this inefficiency, recent work uses task vectors, defined as the parameter difference between a fine-tuned model and its base model, to transfer expertise across models. While existing methods bridge disparate models by matching activations or gradients, a significant performance gap remains relative to direct fine-tuning, suggesting that these partial correspondences are insufficient. In this work, instead of viewing a task vector merely as a parameter offset, we revisit the formation of task vectors and show that they can be derived as accumulated bilinear interactions between input-side activations and output-side gradients. Motivated by this observation, we formulate task-vector transfer as a dual-space alignment problem and propose BiCo, a training-free framework for transferring task vectors through Bilinear Coordinate alignment. BiCo estimates orthogonal Procrustes mappings in both spaces using a single forward-backward pass on a small calibration set, without any parameter update. Across extensive computer vision and natural language processing benchmarks, BiCo consistently outperforms existing transfer methods across models that differ in width, depth, and pre-training configuration.
title Bilinear Coordinate Alignment for Training-Free Task-Vector Transfer
topic Machine Learning
url https://arxiv.org/abs/2605.28444