Paper detail

Ultra-High Density, High-Performance and Energy-Efficient All Spin Logic

All Spin Logic gates employ multiple nano-magnets interacting through spin-torque using non-magnetic channels. Compactness, non-volatility and ultra-low voltage operation are some of the attractive features of ASL, while, low switching-speed (of nano-magnets as compared to CMOS gates) and static-power dissipation can be identified as the major bottlenecks. In this work we explore design techniques that leverage the specific device characteristics of ASL to overcome the inefficiencies and to enhance the merits of this technology, for a given set of device parameters. We exploit the non-volatility of nano-magnets to model fully-pipelined ASL that can achieve higher performance. Clocking of power supply in pipelined ASL would require CMOS transistors that may consume significantly large voltage headroom and area, as compared to the nano-magnets. We show that the use of leaky transistors can significantly mitigate such bottlenecks, without sacrificing energy-efficiency and robustness. Exploiting the inherent isolation between the biasing charge current and spin-current paths in ASL, we propose to stack multiple ASL metal layers, leading to ultra-high-density and energy-efficient 3-D computation blocks. Results for the design of an FIR filter show that ASL can achieve performance and power consumption comparable to CMOS while the ultra-high-density of ASL can be projected as its main advantage over CMOS.