Seis: subspace-based equivariance and invariance scores for neural representations
Seis: subspace-based equivariance and invariance scores for neural representations
Understanding how neural representations respond to geometric transformations is essential for evaluating whether learned features preserve meaningful spatial structure. Existing approaches primarily assess robustness by comparing model outputs under transformed inputs, offering limited insight into how geometric information is organized within internal representations and failing to distinguish between information loss and re-encoding. In this work, we introduce SEIS (Subspace-based Equivariance and Invariance Scores), a subspace metric for analyzing layer-wise feature representations under geometric transformations, disentangling equivariance from invariance without requiring labels or explicit knowledge of the transformation. Synthetic validation confirms that SEIS correctly recovers known transformations. Applied to trained classification networks, SEIS reveals a transition from equivariance in early layers to invariance in deeper layers, and that data augmentation increases invariance while preserving equivariance. We further show that multi-task learning induces synergistic gains in both properties at the shared encoder, and skip connections restore equivariance lost during decoding.
cs.LG, cs.CV
Lin, Huahua
afee4716-d506-458d-8813-a9fb37a115ec
Farrahi, Katayoun
bc848b9c-fc32-475c-b241-f6ade8babacb
Cai, Xiaohao
de483445-45e9-4b21-a4e8-b0427fc72cee
3 February 2026
Lin, Huahua
afee4716-d506-458d-8813-a9fb37a115ec
Farrahi, Katayoun
bc848b9c-fc32-475c-b241-f6ade8babacb
Cai, Xiaohao
de483445-45e9-4b21-a4e8-b0427fc72cee
[Unknown type: UNSPECIFIED]
Abstract
Understanding how neural representations respond to geometric transformations is essential for evaluating whether learned features preserve meaningful spatial structure. Existing approaches primarily assess robustness by comparing model outputs under transformed inputs, offering limited insight into how geometric information is organized within internal representations and failing to distinguish between information loss and re-encoding. In this work, we introduce SEIS (Subspace-based Equivariance and Invariance Scores), a subspace metric for analyzing layer-wise feature representations under geometric transformations, disentangling equivariance from invariance without requiring labels or explicit knowledge of the transformation. Synthetic validation confirms that SEIS correctly recovers known transformations. Applied to trained classification networks, SEIS reveals a transition from equivariance in early layers to invariance in deeper layers, and that data augmentation increases invariance while preserving equivariance. We further show that multi-task learning induces synergistic gains in both properties at the shared encoder, and skip connections restore equivariance lost during decoding.
Text
2602.04054v1
- Author's Original
Available under License Other.
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Published date: 3 February 2026
Keywords:
cs.LG, cs.CV
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Local EPrints ID: 511796
URI: http://eprints.soton.ac.uk/id/eprint/511796
PURE UUID: 122cce5f-5d46-4719-a617-dfb9987e01b2
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Date deposited: 02 Jun 2026 16:52
Last modified: 03 Jun 2026 02:06
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Author:
Huahua Lin
Author:
Katayoun Farrahi
Author:
Xiaohao Cai
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