Abstract
A unique strategy for optimum multi-objective optimization for VLSI implementation of artificial neural network (ANN) is proposed. This strategy is efficient in terms of area, power, and speed, and it has a good degree of accuracy and dynamic range. The goal of this research is to find the sweet spot where area, speed, and power may all be optimised in a very large-scale integration (VLSI) implementation of a neural network (NN). The design should also allow for the dynamic reconfiguration of weight, and it should be very precise. The authors also use a 65-nm CMOS fabrication method to produce the circuits, and these results show that the suggested integral stochastic design may reduce energy consumption by up to 21% compared to the binary radix implementation, without sacrificing accuracy.
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CITATION STYLE
Nagarajan, A. K., Thandapani, K., Neelima, K., Bharathi, M., Srinivasan, D., & Selvaperumal, S. K. (2023). Vlsi implementation of neural systems. In Neuromorphic Computing Systems for Industry 4.0 (pp. 94–116). IGI Global. https://doi.org/10.4018/978-1-6684-6596-7.ch004
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