S. Antony
University of Cincinnati
5 Papers
29 Citations
S. Antony is an academic researcher from University of Cincinnati. The author has contributed to research in topics: Adder & Optical filter. The author has an hindex of 2, co-authored 5 publications.
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Papers
Optical Modified Signed Digit Adder Using Polarization-Coded Symbolic Substitution
P.A. Ramamoorthy,S. Antony +1 more
TL;DR: This paper shows the design of a parallel optical adder based on MSD number representation using the method of symbolic substitution originally proposed by Karl-Heinz Brenner and Alan Huang and discusses the use of this adder along with barrel shifters to efficiently implement multiplication.
23
Symbolic-Substitution-Based Median Filters
TL;DR: The proposed optical implementation of a median filter for optical digital signal and image processing offers an increased throughput compared with the conventional electronic implementation by taking full advantage of the parallelism offered by SSL and the inherent massive parallelism of optics.
4
Optical Implementation Of Systolic Finite Impulse Response Filters
TL;DR: An optical systolic finite impulse response (FIR) filter implementation using barrel shifters and a modified signed digit (MSD) adder is discussed and it is shown that an FIR filter of order eight can be implemented by using one liquid crystal light valve (LCLV) and one optical MSD adder.
2
Median Filters - Optical Implementation Using Symbolic Substitution
S. Antony,P.A. Ramamoorthy,Timothy A. Grogan +2 more
- 18 Jan 1988
TL;DR: An optical implementation of median filters for optical digital signal and image processing offers an increased throughput by taking full advantage of the parallelism offered by SSL and the inherent massive parallelism of optics.
Optical Implementation Of Systolic FIR Filters
P.A. Ramamoorthy,G. Govind,S. Antony +2 more
- 25 Nov 1987
TL;DR: In this article, an optical systolic finite impulse response (FIR) filter implementation using barrel shifters and a Modified Signed-Digit (MSD) adder is proposed, which offers reconfigurability and massive parallelism of optics.