Abstract
Discrete orthogonal transforms (DOTs) are important in many applications, including image and signal processing. Novel 1D and 2D bit-level systolic architectures are presented for the efficient implementation of DOTs for image and signal processing. The authors describe the design methodology of the techniques based on the Baugh-Wooley (1973) algorithm, and the associated design, including a case study of an FPGA implementation. They also discuss the efficiency of implementations which have O(N/sup 2/) and O(2nN) as the area and time complexities for 2D structures, respectively, and O(N) and O(2nN) as the area and time complexities for 1D structures, respectively (where N is the transform length and n is the word length). Furthermore, it is shown that the architectures are parameterisable and that the area required by the designs can be predicted for different values of N and n. A comparison with existing and similar structures has shown that the proposed architectures perform better.
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