Energy-Efficient Time-Domain Vector-by-Matrix Multiplier for Neurocomputing and Beyond
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We propose an extremely energy-efficient mixed-signal approach for performing vector-by-matrix multiplication in a time domain. In such implementation, multi-bit values of the input and output vector elements are represented with time-encoded digital signals, while multi-bit matrix weights are realized with current sources, e.g. transistors biased in subthreshold regime. With our approach, multipliers can be chained together to implement large-scale circuits completely in a time domain. Multiplier operation does not rely on energy-taxing static currents, which are typical for peripheral and input/output conversion circuits of the conventional mixed-signal implementations. As a case study, we have designed a multilayer perceptron, based on two layers of 10x10 four-quadrant vector-by-matrix multipliers, in 55-nm process with embedded NOR flash memory technology, which allows for compact implementation of adjustable current sources. Our analysis, based on memory cell measurements, shows that at high computing speed the drain-induced barrier lowering is a major factor limiting multiplier precision to 6 bit. Post-layout estimates for a conservative 6-bit digital input/output NxN multiplier designed in 55 nm process, including I/O circuitry for converting between digital and time domain representations, show 7 fJ/Op for N>200, which can be further lowered well below 1 fJ/Op for more optimal and aggressive design.
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