Dynamically-programmable gate arrays (DPGAs) promise lower-cost implementations than conventional field-programmable gate arrays (FPGAs) since they efficiently reuse limited hardware resources in time. One of the typical DPGA architectures is a multi-context FPGA (MC-FPGA) that requires multiple memory bits per configuration bit to realize fast context switching. However, this additional memory bits cause significant overhead in area and power consumption. This paper presents novel architecture of a switch element to overcome the required capacity of configuration memory. Our main idea is to exploit redundancy between different contexts by using a fine-grained switch element. The proposed MC-FPGA is designed in a 0.18 µm CMOS technology. Its maximum clock frequency and the context switching frequency are measured to be 310 MHz and 272 MHz, respectively. Moreover, novel CAD process that exploits the redundancy in configuration data, is proposed to support the MC-FPGA architecture.

This paper presents a novel architecture to solve two problems of existing FPGAs : the large delay and area due to complex programmable switch blocks, and the large area due to coarse-grain logic blocks that are underutilized to a great degree. A mesh-connected cellular array based on a bit-serial pipeline architecture is introduced to minimize complexity of switch blocks. A fine-grain logic block architecture with a functionality of a bit-serial adder is presented to minimize the number of inputs and outputs of the logic block since increase in the number of inputs and outputs directly increases the complexity of a switch block. For an area-efficient design, the logic block is implemented based on a hybrid of a programmable logic gate and a dedicated carry logic. The hybrid architecture allows us to use a small lookup table to implement the logic gate. Moreover, the carry logic uses a functional pass-gate that merges both logic and storage functions compactly. The performance of the fine-grain field-programmable VLSI (FPVLSI) is evaluated to be more than 2 times higher than that of a coarse-grain FPVLSI.

A low-power field-programmable VLSI (FPVLSI) is presented to overcome the problem of large power consumption in field-programmable gate arrays (FPGAs). To reduce power consumption in routing networks, the FPVLSI consists of cells that are based on a bit-serial pipeline architecture which reduces routing block complexity. Moreover, a level-converter-less multiple-supply-voltage scheme using dynamic circuits is proposed, where the cells in non-critical paths use a low supply voltage for low power under a speed constraint. The FPVLSI is evaluated based on a 0.18-µm CMOS design rule. The power consumption of the FPVLSI using multiple supply voltages is reduced to 17% or less compared to that of the static-circuit-based FPVLSI using multiple supply voltages.