论文信息 - Hole filling: a novel delay reduction technique using selector logic

Hole filling: a novel delay reduction technique using selector logic

The proposed hole filling, contrary to the conventional method, makes use of paths with delay margins and provides a high-speed circuit by equalizing the delay margin of all paths. To achieve this delay reduction technique, we introduce a new concept named for the hole, which gives readily-usable information about the delay margins of a path. We also develop a new logic transformation method based on selector logic, which enables very flexible control of the path depth of a circuit. The benchmark test for a 32/64 bit adder and subtractor shows that hole filling reduces delay by about 50% without any area increase, compared to a conventional synthesis tool. Moreover, it is also confirmed that it is possible to reduce delay by about 10% for the logic (/spl sim/10 K gates) of an actual microprocessor.

[1] Inseok S. Hwang,et al. A 3.1ns 32b Cmos Adder In Multiple Output Domino Logic , 1988, 1988 IEEE International Solid-State Circuits Conference, 1988 ISSCC. Digest of Technical Papers.

[2] Makoto Suzuki,et al. A 1.5-ns 32-b CMOS ALU in double pass-transistor logic , 1993 .

[3] A. Bellaouar,et al. 3.3-V BiCMOS current-mode logic circuits for high-speed adders , 1993 .

[4] Graham A. Jullien,et al. Fast adders using enhanced multiple-output domino logic , 1997 .

[5] A. L. Fisher,et al. Ultrafast compact 32-bit CMOS adders in multiple-output domino logic , 1989 .

[6] Fumio Murabayashi,et al. 2.5 V CMOS circuit techniques for a 200 MHz superscalar RISC processor , 1996 .

[7] John P. Fishburn. A depth-decreasing heuristic for combinational logic: or how to convert a ripple-carry adder into a carry-lookahead adder or anything in-between , 1991, DAC '90.

[8] Takashi Nishida,et al. 3.3-V BiCMOS circuit techniques for 250-MHz RISC arithmetic modules , 1992 .

[9] Robert K. Brayton,et al. MIS: A Multiple-Level Logic Optimization System , 1987, IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems.