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Conventional design of digital circuits is a very complex task which requires much knowledge in domain-specific rules. But, combinational digital circuits can be evolved automatically using evolutionary techniques. This work proposes new approaches for the automated design of combinational digital circuits using Genetic Algorithm (GA) and Reed Muller Universal Logic module (RM ULM). Here 2-1 RM-ULM...
This paper presents a new approach to the design of combinational digital circuits with multiplexers using Evolutionary techniques. Genetic Algorithm (GA) is used as the optimization tool. Several circuits are synthesized with this method and compared with two design techniques such as standard implementation of logic functions using multiplexers and implementation using Shannon's decomposition technique...
This paper presents a high performance Direct Torque Control (DTC) scheme for Permanent Magnet Synchronous Motor (PMSM). This improved method can reduce the torque ripple keeping the simplicity of conventional DTC. Torque ripple is reduced by supplying adjustable switching vector in each sampling period. This method uses a duty ratio calculation technique to reduce the torque ripple. Here the duty...
Combinational digital circuits can be evolved automatically using Genetic Algorithms (GA). Until recently this technique used linear chromosomes and and one dimensional crossover and mutation operators. In this paper, a new method for representing combinational digital circuits as 2 Dimensional (2D) chromosomes and suitable 2D crossover and mutation techniques has been proposed. By using this method,...
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