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Difference Target Propagation

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abstract

Back-propagation has been the workhorse of recent successes of deep learning but it relies on infinitesimal effects (partial derivatives) in order to perform credit assignment. This could become a serious issue as one considers deeper and more non-linear functions, e.g., consider the extreme case of nonlinearity where the relation between parameters and cost is actually discrete. Inspired by the biological implausibility of back-propagation, a few approaches have been proposed in the past that could play a similar credit assignment role. In this spirit, we explore a novel approach to credit assignment in deep networks that we call target propagation. The main idea is to compute targets rather than gradients, at each layer. Like gradients, they are propagated backwards. In a way that is related but different from previously proposed proxies for back-propagation which rely on a backwards network with symmetric weights, target propagation relies on auto-encoders at each layer. Unlike back-propagation, it can be applied even when units exchange stochastic bits rather than real numbers. We show that a linear correction for the imperfectness of the auto-encoders, called difference target propagation, is very effective to make target propagation actually work, leading to results comparable to back-propagation for deep networks with discrete and continuous units and denoising auto-encoders and achieving state of the art for stochastic networks.

fields

cs.LG 1

years

2026 1

verdicts

UNVERDICTED 1

representative citing papers

Muon as a Residual Connection

cs.LG · 2026-07-01 · unverdicted · novelty 3.0

Muon is interpreted as an implicit residual connection that sacrifices local gradient fidelity to improve downstream layer usability in neural network training.

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  • Muon as a Residual Connection cs.LG · 2026-07-01 · unverdicted · none · ref 3 · internal anchor

    Muon is interpreted as an implicit residual connection that sacrifices local gradient fidelity to improve downstream layer usability in neural network training.