Three-Dimensional Physical Design Flow for Monolithic 3D-FPGAs to Improve Timing Closure and Chip Area

Abstract

By scaling the semiconductor industry to nano-scale era, design and prototyping cost of cell-based Application-Specific Integrated Circuits (ASICs) becomes more expensive and it makes Field Programmable Gate Arrays (FPGAs) more popular among designers. However, there is a gap between FPGAs and ASICs in terms of timing, dynamic power consumption and logic density. Three-dimensional integration, particularly in the full monolithic process, has been considered as a promising solution to reduce the performance gap of ASICs and FPGAs. In this paper, two new architectures for the monolithically integrated 3D-FPGAs are introduced. In order to exploit the great potentials of the suggested architectures, a new three-dimensional FPGA placement algorithm is proposed thereafter. The proposed placement algorithm, named JABE, is the first of its kind that enables designers to take advantages of the large number of vertical interconnections in the monolithically stacked 3D-FPGAs. Our experiments show a 24% timing improvement for the new architectures and CAD algorithms compared with the conventional TSV-based 3D-FPGAs and design flows. In addition, improvements in terms of the total wirelength and area footprint are reported for the proposed placement algorithms and new architectures.