Timing-driven Approximate Logic Synthesis Based on Double-chase Grey Wolf Optimizer
Abstract
With the shrinking technology nodes, timing optimization becomes increasingly challenging. Approximate logic synthesis (ALS) can perform local approximate changes (LACs) on circuits to optimize timing with the cost of slight inaccuracy. However, existing ALS methods that focus solely on critical path depth reduction (depth-driven methods) or area minimization (area-driven methods) are inefficient in achieving optimal timing improvement. %based on double-chase grey wolf optimizer (DCGWO). where we employ a double-chase grey wolf optimizer to explore and apply LACs, simultaneously bringing excellent critical path shortening and area reduction under error constraints. According to experiments on open-source circuits with TSMC 28nm technology, compared to the SOTA method, our framework can generate approximate circuits with greater critical path delay reduction under different error and area constraints.
Keywords
Cite
@article{arxiv.2411.10990,
title = {Timing-driven Approximate Logic Synthesis Based on Double-chase Grey Wolf Optimizer},
author = {Xiangfei Hu and Yuyang Ye and Tinghuan Chen and Hao Yan and Bei Yu},
journal= {arXiv preprint arXiv:2411.10990},
year = {2024}
}