A new systolic array algorithm for inverse discrete cosine transform with high throughput rate

Author

Chiper, Doru Florin

Author_Institution

Dept. of Appl. Electron., Iasi Univ., Romania

Volume

1

fYear

1996

fDate

17-20 Jun 1996

Firstpage

201

Abstract

In this paper a new approach for the realization of the inverse 1D discrete cosine transform (IDCT) is presented. This approach is based on a new formulation of an odd prime-length IDCT which uses two half-length cyclic convolutions with the same form which can be concurrently computed. Using this approach, a new efficient systolic array with a higher throughput rate, a reduced average computation time, and a very regular structure can be obtained as compared with other systolic arrays for IDCT based on using cyclic convolution forms. A simpler control structure and hardware structure of the PE´s, and hence a reduced cycle time, can be obtained. It owns all the outstanding features of the other systolic arrays implementations based on using cyclic convolution forms, being very well suited for a VLSI realization

Keywords

VLSI; computational complexity; discrete cosine transforms; parallel algorithms; systolic arrays; VLSI realization; average computation time; concurrent computing; control structure; cyclic convolution forms; half-length cyclic convolutions; hardware structure; inverse 1D discrete cosine transform; odd prime-length IDCT; regular structure; systolic array algorithm; throughput rate; Algorithm design and analysis; Computational complexity; Concurrent computing; Convolution; Costs; Discrete cosine transforms; Hardware; Parallel processing; Systolic arrays; Throughput;

fLanguage

English

Publisher

ieee

Conference_Titel

Industrial Electronics, 1996. ISIE '96., Proceedings of the IEEE International Symposium on

Conference_Location

Warsaw

Print_ISBN

0-7803-3334-9

Type

conf

DOI

10.1109/ISIE.1996.548419

Filename

548419