Title :
Reliable modulo systolic arrays for DSP algorithms
Author :
Bayoumi, Magdy A.
Author_Institution :
Southwestern Louisiana Univ., Lafayette, LA, USA
Abstract :
The algebraic and structural properties of a residue number system (RNS) to optimize the design of DSP (digital signal processing) systolic arrays is discussed. RNS establishes parallelism on the algorithmic level by decomposing the original computational field into a set of finite fields, in which arithmetic operations are performed independently for each field. The impact of the moduli size on the structural choices is analyzed. Three different structures, namely, word-parallel, bit-parallel, and bit-serial, are presented. Redundant RNS has fault tolerance capabilities. An efficient fault-detection technique is developed as an alternative to the standard procedure based on a mixed radix algorithm. A finite-impulse-response (FIR) filter algorithm is used as a case study
Keywords :
cellular arrays; computerised signal processing; digital filters; filtering and prediction theory; microprocessor chips; DSP algorithms; FIR filter; RNS; arithmetic operations; bit-parallel; bit-serial; computational field; digital filter; digital signal processing; fault tolerance; fault-detection technique; finite fields; finite-impulse response filter algorithm; mixed radix algorithm; moduli size; reliable modulo systolic arrays; residue number system; word-parallel; Arithmetic; Concurrent computing; Design optimization; Digital signal processing; Finite impulse response filter; Galois fields; Parallel processing; Signal design; Signal processing algorithms; Systolic arrays;
Conference_Titel :
Acoustics, Speech, and Signal Processing, 1988. ICASSP-88., 1988 International Conference on
Conference_Location :
New York, NY
DOI :
10.1109/ICASSP.1988.197038
