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Main Authors: Brenner, Manuel, Koppe, Georgia
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.07919
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author Brenner, Manuel
Koppe, Georgia
author_facet Brenner, Manuel
Koppe, Georgia
contents Sequence modeling tasks across domains such as natural language processing, time series forecasting, and control require learning complex input-output mappings. Nonlinear recurrence is theoretically required for universal approximation of sequence-to-sequence functions, yet linear recurrent models often prove surprisingly effective. This raises the question of when nonlinearity is truly required. We present a framework to systematically dissect the functional role of nonlinearity in recurrent networks, identifying when it is computationally necessary and what mechanisms it enables. We address this using Almost Linear Recurrent Neural Networks (AL-RNNs), which allow recurrence nonlinearity to be gradually attenuated and decompose network dynamics into analyzable linear regimes, making computational mechanisms explicit. We illustrate the framework across diverse synthetic and real-world tasks, including classic sequence modeling benchmarks, a neuroscientific stimulus-selection task, and a multi-task suite. We demonstrate how the AL-RNN's piecewise linear structure enables identification of computational primitives such as gating, rule-based integration, and memory-dependent transients, revealing that these operations emerge within predominantly linear backbones. Across tasks, sparse nonlinearity improves interpretability by reducing and localizing nonlinear computations, promotes shared representations in multi-task settings, and reduces computational cost. Moreover, sparse nonlinearity acts as a useful inductive bias: in low-data regimes or when tasks require discrete switching between linear regimes, sparsely nonlinear models often match or exceed fully nonlinear architectures. Our findings provide a principled approach for identifying where nonlinearity is functionally necessary, guiding the design of recurrent architectures that balance performance, efficiency, and interpretability.
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publishDate 2025
record_format arxiv
spellingShingle Uncovering the Computational Roles of Nonlinearity in Sequence Modeling Using Almost-Linear RNNs
Brenner, Manuel
Koppe, Georgia
Machine Learning
Artificial Intelligence
Computation and Language
Chaotic Dynamics
Computational Physics
Sequence modeling tasks across domains such as natural language processing, time series forecasting, and control require learning complex input-output mappings. Nonlinear recurrence is theoretically required for universal approximation of sequence-to-sequence functions, yet linear recurrent models often prove surprisingly effective. This raises the question of when nonlinearity is truly required. We present a framework to systematically dissect the functional role of nonlinearity in recurrent networks, identifying when it is computationally necessary and what mechanisms it enables. We address this using Almost Linear Recurrent Neural Networks (AL-RNNs), which allow recurrence nonlinearity to be gradually attenuated and decompose network dynamics into analyzable linear regimes, making computational mechanisms explicit. We illustrate the framework across diverse synthetic and real-world tasks, including classic sequence modeling benchmarks, a neuroscientific stimulus-selection task, and a multi-task suite. We demonstrate how the AL-RNN's piecewise linear structure enables identification of computational primitives such as gating, rule-based integration, and memory-dependent transients, revealing that these operations emerge within predominantly linear backbones. Across tasks, sparse nonlinearity improves interpretability by reducing and localizing nonlinear computations, promotes shared representations in multi-task settings, and reduces computational cost. Moreover, sparse nonlinearity acts as a useful inductive bias: in low-data regimes or when tasks require discrete switching between linear regimes, sparsely nonlinear models often match or exceed fully nonlinear architectures. Our findings provide a principled approach for identifying where nonlinearity is functionally necessary, guiding the design of recurrent architectures that balance performance, efficiency, and interpretability.
title Uncovering the Computational Roles of Nonlinearity in Sequence Modeling Using Almost-Linear RNNs
topic Machine Learning
Artificial Intelligence
Computation and Language
Chaotic Dynamics
Computational Physics
url https://arxiv.org/abs/2506.07919