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Local learning for stable backpropagation-free neural network training towards physical learning

1 Pith paper cite this work. Polarity classification is still indexing.

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abstract

While backpropagation and automatic differentiation have driven deep learning's success, the physical limits of chip manufacturing and rising environmental costs of deep learning motivate alternative learning paradigms such as physical neural networks. However, most existing physical neural networks still rely on digital computing for training, largely because backpropagation and automatic differentiation are difficult to realize in physical systems. We introduce FFzero, a forward-only learning framework enabling stable neural network training without backpropagation or automatic differentiation. FFzero combines layer-wise local learning, prototype-based representations, and directional-derivative-based optimization through forward evaluations only. We show that local learning is effective under forward-only optimization, where backpropagation fails. FFzero generalizes to multilayer perceptron and convolutional neural networks across classification and regression. Using a simulated photonic neural network as an example, we demonstrate that FFzero provides a viable path toward backpropagation-free in-situ physical learning.

fields

cs.LG 1

years

2026 1

verdicts

UNVERDICTED 1

representative citing papers

FFR: Forward-Forward Learning for Regression

cs.LG · 2026-06-02 · unverdicted · novelty 7.0

FFR adapts Forward-Forward learning to regression via ordinal competitive goodness, stratified ladder layers, and hierarchical uncertainty-aware prediction, recovering 98.6% of backpropagation accuracy with substantially lower peak memory.

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Showing 1 of 1 citing paper.

  • FFR: Forward-Forward Learning for Regression cs.LG · 2026-06-02 · unverdicted · none · ref 10 · internal anchor

    FFR adapts Forward-Forward learning to regression via ordinal competitive goodness, stratified ladder layers, and hierarchical uncertainty-aware prediction, recovering 98.6% of backpropagation accuracy with substantially lower peak memory.