Spiking Neural Network Equalizer With Fast and Low Power Decoding for IM/DD Optical Communication

Spiking Neural Network Equalizer With Fast and Low Power Decoding for IM/DD Optical Communication

Neuromorphic computing based on spiking neural networks (SNN) realized in CMOS mixed-signal circuits promises lower power consumption than conventional digital computing. This makes SNNs an interesting technology for low-footprint optical transceiver ASICs. Arnold et al. proposed a non-linear SNN eq...

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Veröffentlicht in:IEEE photonics technology letters 2024-09, Vol.36 (17), p.1061-1064
Hauptverfasser: Li, Shuangxu, Bocherer, Georg, Calabro, Stefano, Schadler, Maximilian
Format: Artikel
Sprache:eng
Schlagworte:
Data centers
Decoding
Digital computers
equalization
Equalizers
intensity-modulation/direct-detection (IM/DD)
Membrane potentials
Membranes
Neural networks
Neurons
optical communication
Power consumption
spiking neural network (SNN)
Synapses
Throughput
Voltage
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Zusammenfassung:Neuromorphic computing based on spiking neural networks (SNN) realized in CMOS mixed-signal circuits promises lower power consumption than conventional digital computing. This makes SNNs an interesting technology for low-footprint optical transceiver ASICs. Arnold et al. proposed a non-linear SNN equalizer and demapper architecture outperforming a linear digital equalizer for a simulated IM/DD link. In this work, the spike decoding layer providing the demapper decision is optimized with respect to throughput and power. Four decoding methods are compared, namely max-over-time membrane (MOTM), end-of-time membrane (EOTM), time-to-first-spike (TTFS), and spike rate decoding. Optimized EOTM decoding is found to provide the fastest decision and the lowest spike rate, improving throughput and power consumption by factors 4 and 10, respectively, compared to previously used MOTM decoding.
ISSN:1041-1135
1941-0174
DOI:10.1109/LPT.2024.3424495