Litcius/Paper detail

A 3-8bit Reconfigurable Hybrid ADC Architecture with Successive-approximation and Single-slope Stages for Computing in Memory

Wuyu Fan, Yuandong Li, Li Du, Likai Li, Yuan Du

20222022 IEEE International Symposium on Circuits and Systems (ISCAS)16 citationsDOI

Abstract

Computing in Memory (CIM) is reported as one of the most promising non-Von-Neumann computing architectures to replace the existing digital AI processor architecture. Compared with digital-based computation, CIM shows advantages in computing density, energy efficiency, and throughput. However, it requires a large analog-to-digital array to quantize the column-parallel analog Multiply-Accumulate (MAC) results with tight area, high speed, and low power requirements. In this paper, we first discuss the design trade-off between different ADC architectures for CIM accelerators. To improve the overall system efficiency, a 3-8bit reconfigurable hybrid ADC architecture with successive-approximation and single-slope stages is proposed, particularly emphasizing the reconfigurability of the conversion speed and bit-resolution for different computation mode. A prototype is designed and simulated in 65-nm CMOS, which occupies an area of l90$\mu$m $\times$ 5$\mu$m and consumes a power of 48$\mu$W at 8-bit conversion mode, achieving 7.87-bit ENOB and 10.2 fJ/conv.

Topics & Concepts

Effective number of bitsReconfigurabilityComputer scienceCMOSComputationSuccessive approximation ADCComputer hardwareThroughputVon Neumann architectureEfficient energy usePower (physics)Analog-to-digital converterComputer architectureComputational scienceEmbedded systemElectronic engineeringEngineeringPhysicsAlgorithmElectrical engineeringVoltageWirelessCapacitorOperating systemQuantum mechanicsTelecommunicationsAdvanced Memory and Neural ComputingCCD and CMOS Imaging SensorsAnalog and Mixed-Signal Circuit Design