9 research outputs found
High sample-rate Givens rotations for recursive least squares
The design of an application-specific integrated circuit of a parallel array processor is considered
for recursive least squares by QR decomposition using Givens rotations, applicable
in adaptive filtering and beamforming applications. Emphasis is on high sample-rate operation,
which, for this recursive algorithm, means that the time to perform arithmetic operations
is critical. The algorithm, architecture and arithmetic are considered in a single
integrated design procedure to achieve optimum results.
A realisation approach using standard arithmetic operators, add, multiply and divide is
adopted. The design of high-throughput operators with low delay is addressed for fixed- and
floating-point number formats, and the application of redundant arithmetic considered. New
redundant multiplier architectures are presented enabling reductions in area of up to 25%,
whilst maintaining low delay. A technique is presented enabling the use of a conventional
tree multiplier in recursive applications, allowing savings in area and delay. Two new divider
architectures are presented showing benefits compared with the radix-2 modified SRT algorithm.
Givens rotation algorithms are examined to determine their suitability for VLSI implementation.
A novel algorithm, based on the Squared Givens Rotation (SGR) algorithm, is developed
enabling the sample-rate to be increased by a factor of approximately 6 and offering
area reductions up to a factor of 2 over previous approaches. An estimated sample-rate of
136 MHz could be achieved using a standard cell approach and O.35pm CMOS technology.
The enhanced SGR algorithm has been compared with a CORDIC approach and shown to
benefit by a factor of 3 in area and over 11 in sample-rate. When compared with a recent implementation
on a parallel array of general purpose (GP) DSP chips, it is estimated that a single
application specific chip could offer up to 1,500 times the computation obtained from a
single OP DSP chip