Energy Efficient 0.5V 4.8pJ/SOP 0.93μW Leakage/Core Neuromorphic Processor Design

Energy Efficient 0.5V 4.8pJ/SOP 0.93μW Leakage/Core Neuromorphic Processor Design

This brief presents a neuromorphic processor with asynchronous routers and configurable LIF neuron models. The neurocore microarchitecture revolves around a high- V_{th} SRAM to reduce leakage, alongside reconfigurable neuron compute logic circuits and async routers to maximize energy efficiency. T...

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Veröffentlicht in:IEEE transactions on circuits and systems. II, Express briefs Express briefs, 2021-09, Vol.68 (9), p.3148-3152
Hauptverfasser: Nambiar, Vishnu P., Pu, Junran, Lee, Yun Kwan, Mani, Aarthy, Koh, Eng Kiat, Wong, Ming Ming, Li, Fei, Goh, Wang Ling, Do, Anh Tuan
Format: Artikel
Sprache:eng
Schlagworte:
Circuit design
CMOS
Computational modeling
Computer architecture
Energy efficiency
Hardware
hardware design
Integrated circuit modeling
Leakage
Logic circuits
low power
Microprocessors
Neuromorphic
Neuromorphics
Neurons
Routers
Routing
Routing protocols
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Zusammenfassung:This brief presents a neuromorphic processor with asynchronous routers and configurable LIF neuron models. The neurocore microarchitecture revolves around a high- V_{th} SRAM to reduce leakage, alongside reconfigurable neuron compute logic circuits and async routers to maximize energy efficiency. The neuron compute module achieves low power via an area efficient ALU implementation by using only adder and bitshifter circuits. We describe this LIF neuron model ALU design, and also include key neurocore verification scenarios (i.e., router deadlocks and functional coverage), CPU-neurocore control flow, and asynchronous router performance analysis. Our 16-core fabricated chip in 40 nm CMOS process works down to 0.5V. The measured leakage and average energy efficiency are 0.93~\mu \text{W} /core and 4.8 pJ/SOP respectively (at 0.5V), which is 20% better than state of the art.
ISSN:1549-7747
1558-3791
DOI:10.1109/TCSII.2021.3096883