Area-Delay-Power Efficient VLSI Architecture of FIR Filter for Processing Seismic Signal

Abstract

Low-complexity, high-speed and re-configurability are the primary requirements of the finite impulse response (FIR) filters employed for the processing of acquired seismic signal in real-time seismic-alert-system. The common sub-expression elimination (CSE) technique is employed widely to reduce the hardware complexity by minimizing the logic operators (LOs) and logic depths (LDs) in digital FIR filter. In this brief, a novel matrix grouped CSE (MCSE) algorithm has been proposed which outperforms the existing CSE algorithms in terms of LOs and LDs minimization. Moreover, a new half-unit biased (HUB) based rounding technique is incorporated in the proposed design to reduce the truncation error while maintaining low-complexity and the cut-set retiming technique is employed to reduce the critical-path-delay (CPD). Two hardware efficient FIR filter architectures (I and II) involving the proposed canonical signed digit (CSD) based MCSE algorithm, HUB rounding and cut-set retiming approach have been presented. Further, the architecture II represents a hardware efficient realization of a reconfigurable FIR filter. The hardware implementation of the architectures is performed on both FPGA and ASIC platforms. The hardware implementation of the proposed architecture I yields more than 25%, 49%, 38%, 36% and, 31% reduction in LOs, CPD, effective latency, area-delay-product (ADP) and, power-delay-product (PDP), respectively, over the state-of-the-art CSE based architectures. Whereas the reconfigurable architecture II exhibits nearly 48%, 12% and, 13% reduction in CPD, ADP and, PDP over the counterpart.