Design of a systolic coprocessor for rational addition

Author

Jebelean, Tudor

Author_Institution

RISC-Linz, Austria

fYear

1995

fDate

24-26 Jul 1995

Firstpage

282

Lastpage

289

Abstract

We design a systolic coprocessor for the addition of signed normalized rational numbers. This is the most complicated rational operation: it involves GCD, exact division, multiplication and addition/subtraction. In particular the implementation of GCD and exact division improve significantly (2 to 4 times) previously known solutions. In contrast to the traditional approach, all operations are performed least-significant digits first. This allows bit-pipelining between partial operations at reduced area-cost. An Atmel FPGA design for 8-bit operands consumes 730 cells (3,500 equivalent gates) and runs at 25 MHz (5 MHz after layout). For 32-bit operands this would be in the same timing range as the software solutions, however a significant speed-up can be expected for longer operands because the linear time-complexity of the hardware algorithms

Keywords

digital arithmetic; field programmable gate arrays; parallel architectures; systolic arrays; GCD; addition; exact division; multiplication; rational addition; rational numbers; subtraction; systolic coprocessor; Coprocessors; Digital arithmetic; Equations; Europe; Field programmable gate arrays; Hardware; Mathematics; Polynomials; Reduced instruction set computing; Timing;

fLanguage

English

Publisher

ieee

Conference_Titel

Application Specific Array Processors, 1995. Proceedings. International Conference on

Conference_Location

Strasbourg

ISSN

1063-6862

Print_ISBN

0-8186-7109-2

Type

conf

DOI

10.1109/ASAP.1995.522932

Filename

522932