Title :
High performance, integrated 1T1R oxide-based oscillator: Stack engineering for low-power operation in neural network applications
Author :
Sharma, A.A. ; Jackson, T.C. ; Schulaker, M. ; Kuo, C. ; Augustine, C. ; Bain, J.A. ; Wong, H.-S.P. ; Mitra, S. ; Pileggi, L.T. ; Weldon, J.A.
Author_Institution :
Carnegie Mellon Univ., Pittsburgh, PA, USA
Abstract :
Brain-inspired non-Boolean computing paradigms are gaining wide interest due to their error resilient nature and massive parallelism. This work explores oxide-based compact oscillators for oscillatory neural networks (ONN). We demonstrate for the first time, best in class high-frequency performance at 500 MHz and low power (<; 200 μW). The superior figures of merit are achieved due to device engineering to give maximum swing at low power and integration as a 1T1R structure. We show frequency control over 2 orders of magnitude by varying the gate voltage and show its applicability to an ONN-based associative memory.
Keywords :
content-addressable storage; frequency control; low-power electronics; neural nets; oscillators; voltage control; 1T1R structure; ONN-based associative memory; brain-inspired non-Boolean computing paradigms; error resilient nature; frequency 500 MHz; frequency control; gate voltage; massive parallelism; oscillatory neural networks; oxide-based compact oscillators; Associative memory; Biological neural networks; CMOS integrated circuits; Frequency control; Neurons; Oscillators; Threshold voltage;
Conference_Titel :
VLSI Technology (VLSI Technology), 2015 Symposium on
DOI :
10.1109/VLSIT.2015.7223672
