Wire-Length and Run-Time Optimization in FPGA Placement Using Hybrid Iterative Algorithms

Abstract

This paper introduces hybrid iterative algorithms that combine Particle Swarm Optimization (PSO) and Simulated Annealing (SA) algorithms for Field Programmable Gate Array (FPGA) placement by considering adaptive inertia weight and local minima avoidance. The algorithms target to optimize the wire-length of the nets, run time and critical path delay in the placement of logic blocks. Using the adaptive inertia weight parameter and local minima avoidance, the hybrid PSO-SA algorithm is modified to Time-varying PSO-SA (TPSO-SA) and Modified PSO-SA (MPSO-SA) algorithm, respectively. These different hybrid PSO-SA algorithms are checked for efficiency by comparing with the Versatile Place and Route (VPR) algorithm of the Verilog to Routing (VTR) tool using Microelectronics Centre of North Carolina (MCNC) benchmark circuits. The hybrid PSO-SA algorithms give 5–37% better results for wire-length cost and 20–58% reduction in runtime compared to the VPR placement algorithm on different benchmark circuits. Critical path delay is also taken into consideration.