A Novel Framework of Genetic Algorithm and Spectre to Optimize Delay and Power Consumption in Designing Dynamic Comparators

In integrated circuit (IC) design, analog circuits contribute significantly as the interface between real and digital world signals. Although they make up a relatively small portion of the overall circuit, their design process is often most time-consuming, mostly from the phase of manual iteration of circuit parameters to meet design specifications. Therefore, the design automation of analog circuits with the help of efficient optimization techniques arises as a promising candidate to address the issue. Among optimization algorithms, while the genetic algorithm (GA) has been shown to be effective in finding near-optimal solutions, it has not been extensively applied to the field of analog circuit design. Hence, this paper proposes a method to utilize GA in the optimization of a widely used circuit topology, namely the comparator. The comparator is considered the fundamental block in the design of most analog-to-digital converters (ADCs). For high-speed ADCs, dynamic comparators are usually chosen for the purpose of high speed and power efficiency. In summary, this paper introduces an innovative GA-Spectre architecture to optimize the dynamic comparator with respect to delay and power consumption. The post-optimized results are optimistic with a 72.61 ps delay and 3.11 µW power dissipation.