论文信息 - Design and VLSI architecture of wave digital filters with short signed digit coefficients

Design and VLSI architecture of wave digital filters with short signed digit coefficients

The low-roundoff-noise properties of wave digital filters have known and desirable properties with respect to their realization with short coefficient wordlengths. The authors seek realizations with coefficients that are restricted to a particular form; the aim is to minimize the number of levels of addition required in the implementation of the two-port adaptor equations. Various types of short-word length signed-digit coefficients are investigated. A pole-zero analysis method gives an indication of the range of specifications that can be met for each type. A useful four-digit form is identified, and a four-level architecture for the associated two-port adaptor is developed. Direct and bit-level pipelined techniques are examined for its implementation. It is concluded that low-latency, high-clock-rate adaptors that can be employed in filters for high-performance applications can be designed with this method.<<ETX>>

[1] Sun-Yuan Kung,et al. The use of data dependence graphs in the design of bit-level systolic arrays , 1990, IEEE Trans. Acoust. Speech Signal Process..

[2] J. Pandel,et al. Design of Bireciprocal Wave Digital Filters for High Sampling Rate Applications , 1986 .

[3] A. Jones,et al. Design of cascaded allpass structures with magnitude and delay constraints using simulated annealing and quasi-Newton methods , 1991, 1991., IEEE International Sympoisum on Circuits and Systems.

[4] C. K. Yuen,et al. Digital Filters , 1979, IEEE Transactions on Systems, Man, and Cybernetics.

[5] Lajos Gazsi,et al. Explicit formulas for lattice wave digital filters , 1985 .

[6] Stuart Lawson,et al. The design of wave digital filters using fully pipelined bit-level systolic arrays , 1990, J. VLSI Signal Process..

[7] S. Summerfield. Prototype chip set for systolic wave digital filters employing optimal two phase clocking , 1991, 1991., IEEE International Sympoisum on Circuits and Systems.