On the Hardware Reduction of z-Datapath of Vectoring CORDIC

Author

Stapenhurst, R. ; Maharatna, K. ; Mathew, J. ; Nunez-Yanez, J.L. ; Pradhan, D.K.

Author_Institution

Bristol Univ.

fYear

2007

fDate

27-30 May 2007

Firstpage

3002

Lastpage

3005

Abstract

In this article we present a novel design of a hardware optimal vectoring CORDIC processor. We present a mathematical theory to show that using bipolar binary notation it is possible to eliminate all the arithmetic computations required along the z-datapath. Using this technique it is possible to achieve three and 1.5 times reduction in the number of registers and adder respectively compared to classical CORDIC. Following this, a 16-bit vectoring CORDIC is designed for the application in Synchronizer for IEEE 802.11a standard. The total area and dynamic power consumption of the processor is 0.14 mm² and 700muW respectively when synthesized in 0.18mum CMOS library which shows its effectiveness as a low-area low-power processor.

Keywords

CMOS logic circuits; adders; digital arithmetic; logic design; low-power electronics; microprocessor chips; 0.18 micron; 16 bit; 700 muW; CMOS library; IEEE 802.11a standard; adder; arithmetic computations; bipolar binary notation; mathematical theory; registers; vectoring CORDIC processor; z-datapath; Arithmetic; CMOS process; Computer architecture; Digital signal processing; Energy consumption; Hardware; Iterative algorithms; Libraries; Power generation economics; Registers;

fLanguage

English

Publisher

ieee

Conference_Titel

Circuits and Systems, 2007. ISCAS 2007. IEEE International Symposium on

Conference_Location

New Orleans, LA

Print_ISBN

1-4244-0920-9

Electronic_ISBN

1-4244-0921-7

Type

conf

DOI

10.1109/ISCAS.2007.377978

Filename

4253310