Non-Volatile Approximate Arithmetic Circuits Using Scalable Hybrid Spin-CMOS Majority Gates

In the nanoscale era, leakage/static power dissipation has become an inevitable and important issue for CMOS devices. To alleviate this issue, we propose to use spintronic devices with near-zero leakage power and non-volatility as key components in arithmetic circuits for error-resilient applications. To this end, spintronic threshold devices are first utilized to construct highly-scalable majority gates (MGs) based on spin-CMOS technology. These MGs are then used in the design of compressors for constructing multipliers and accumulators. For an MG-based compressor, the truth table of a conventional compressor is transformed to ensure that the outputs depend only on the number of input "1"s. To synthesize and optimize the MG-based circuits, a heuristic majority-inverter graph (HMIG) is further proposed for the design of an accurate and two approximate non-volatile 4-2 compressors (denoted as MG-EC, MG-AC1 and MG-AC2). Due to the high scalability of the MGs, approximate compressors with a larger number of inputs can be devised using the same method. Compared to previous designs, the proposed 4-2 compressors show shorter critical path delays and lower energy consumption; MG-AC1 and MG-AC2 also achieve a higher accuracy than state-of-the-art approximate designs. For achieving a similar image quality in image compression, the multiplier implementations using MG-AC1 and MG-AC2 result in more significant reductions in delay and energy than those using other approximate designs.