Approximation Methods in Multidimensional Filter Design.

Abstract

First, new stability tests were developed for multidimensional recursive digital filters and any double-ended n-dimensional noncausal linear processor which is said to be stable if its impulse response decreases exponentially in all 2-n directions. It was than shown that the impulse response operator for a 2-D discrete Hilbert transformer, though not by itself sum-separable, becomes so after appropriate classification. Subsequently it was proved that the multiplicative complexity of computation of a 2-D DHT is not greater than twice the sum of multiplicative complexities of two 1-D DHT's. Subsequently, the 1-D matrix Pade approximation problem via a three-term recursive computation scheme was tackled as a prelude to the solution of 2-D and n-D cases. Specifically, given a 1-D matrix power series, it was shown that a recurrence relation relates the ((L+1)/(M+1)), (L/M), ((L-1)/(M-1)) order Pade approximants, which are guaranteed to exist provided a certain rank condition is satisfied by characterizing matrices possessing block-Hankel structure. Attention to stability, algebraic computational complexity and approximation were necessary because efficient implementation of stable recursion is desired. (Author)

Document Details

Document Type

Technical Report

Publication Date

Feb 28, 1979

Accession Number

ADA067917

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