An Ultra-Low Power Always-On Keyword Spotting Accelerator Using Quantized Convolutional Neural Network and Voltage-Domain Analog Switching Network-Based Approximate Computing

An Ultra-Low Power Always-On Keyword Spotting Accelerator Using Quantized Convolutional Neural Network and Voltage-Domain Analog Switching Network-Based Approximate Computing

An ultra-low power always-on keyword spotting (KWS) accelerator is implemented in 22nm CMOS technology, which is based on an optimized convolutional neural network (CNN). To reduce the power consumption while maintaining the system recognition accuracy, we first perform a bit-width quantization meth...

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Veröffentlicht in:IEEE access 2019, Vol.7, p.186456-186469
Hauptverfasser: Liu, Bo, Wang, Zhen, Zhu, Wentao, Sun, Yuhao, Shen, Zeyu, Huang, Lepeng, Li, Yan, Gong, Yu, Ge, Wei
Format: Artikel
Sprache:eng
Schlagworte:
approximate computing
Artificial neural networks
bit-width quantization
CMOS
Computation
Computer architecture
Computer networks
Convolution
Domains
Electric potential
Feature extraction
Keyword spotting
Low-power electronics
Mel frequency cepstral coefficient
Multiplication
Neural networks
Power consumption
Power demand
Recognition
Speech recognition
Switching
Voltage
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Zusammenfassung:An ultra-low power always-on keyword spotting (KWS) accelerator is implemented in 22nm CMOS technology, which is based on an optimized convolutional neural network (CNN). To reduce the power consumption while maintaining the system recognition accuracy, we first perform a bit-width quantization method on the proposed CNN to reduce the data/weight bit width required by the hardware computing unit without reducing the recognition accuracy. Then, we propose an approximate computing architecture for the quantized CNN using voltage-domain analog switching network based multiplication and addition unit. Implementation results show that this accelerator can support 10 keywords real time recognition under different noise types and SNRs, while the power consumption can be significantly reduced to 52 μW.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2019.2960948