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stochastic-physical-neural-networks

Stochastic Physical Neural Networks (PNNs) methodology using single-electron and single-photon stochastic neurons. Training via empirical backward pass with few trials achieves >97% MNIST accuracy. Use when: physical neural networks, stochastic neurons, single-electron tunneling, quantum dot neurons, single-photon neurons, PNN training strategies, MNIST classification, noise-resilient deep learning, arXiv:2604.10861, stochastic physical computing, quantum neurons.

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UpdatedJune 4, 2026 at 02:00

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stochastic-physical-neural-networks

description

Stochastic Physical Neural Networks

Train physical neural networks where neurons are realized by stochastic activation switches — single-electron tunneling or single-photon processes.

Electronic Stochastic Neuron

Implementation: Single-electron tunneling through a quantum dot
Basis: Charge state of the quantum dot
Stochasticity: Inherent tunneling statistics

Photonic Stochastic Neuron

Implementation: Single-photon source driving one of two modes via controllable beam-splitter interaction
Basis: Occupation of the undriven mode
Stochasticity: Photon detection statistics

Training Strategies

Strategy	Forward Pass	Backward Pass	Key Finding
True probability	Expected values	True gradients	Lower accuracy
Empirical outputs	Sampled values	Empirical gradients	>97% MNIST accuracy

Key Insight

Using empirical outputs in the backward pass (not true probabilities) achieves significantly higher accuracy with fewer trials per layer.

Noise Robustness

Maintains >97% test accuracy under high noise and model uncertainty
Works with single-hidden-layer architecture
Simplicity enables practical implementation

Training Protocol

Build single-hidden-layer stochastic PNN with electronic or photonic neurons
Vary number of trials per layer to control forward-pass stochasticity
Use empirical outputs (sampled values) for gradient estimation in backward pass
Train on target task — monitor convergence under noise conditions

Architectural Simplicity

Unlike DNNs requiring backpropagation through time, stochastic PNNs:

No BPTT needed
Only simple readout training
Natural noise resilience
Compatible with quantum hardware constraints

Activation Keywords

stochastic PNN, physical neural network, single-electron neuron, single-photon neuron, quantum dot neuron, stochastic neuron training, empirical backward pass, MNIST stochastic, Dou Kumara Burns

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Source

hiyenwong

hiyenwong/ai_collection

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name

stochastic-physical-neural-networks

description

Stochastic Physical Neural Networks

Train physical neural networks where neurons are realized by stochastic activation switches — single-electron tunneling or single-photon processes.

Electronic Stochastic Neuron

Implementation: Single-electron tunneling through a quantum dot
Basis: Charge state of the quantum dot
Stochasticity: Inherent tunneling statistics

Photonic Stochastic Neuron

Implementation: Single-photon source driving one of two modes via controllable beam-splitter interaction
Basis: Occupation of the undriven mode
Stochasticity: Photon detection statistics

Training Strategies

Strategy	Forward Pass	Backward Pass	Key Finding
True probability	Expected values	True gradients	Lower accuracy
Empirical outputs	Sampled values	Empirical gradients	>97% MNIST accuracy

Key Insight

Using empirical outputs in the backward pass (not true probabilities) achieves significantly higher accuracy with fewer trials per layer.

Noise Robustness

Maintains >97% test accuracy under high noise and model uncertainty
Works with single-hidden-layer architecture
Simplicity enables practical implementation

Training Protocol

Build single-hidden-layer stochastic PNN with electronic or photonic neurons
Vary number of trials per layer to control forward-pass stochasticity
Use empirical outputs (sampled values) for gradient estimation in backward pass
Train on target task — monitor convergence under noise conditions

Architectural Simplicity

Unlike DNNs requiring backpropagation through time, stochastic PNNs:

No BPTT needed
Only simple readout training
Natural noise resilience
Compatible with quantum hardware constraints

Activation Keywords

stochastic PNN, physical neural network, single-electron neuron, single-photon neuron, quantum dot neuron, stochastic neuron training, empirical backward pass, MNIST stochastic, Dou Kumara Burns