Useful-skew clock routing with gate sizing for low power design

Instead of zero-skew or assuming a fixed skew bound, we seek to produce useful skews in clock routing. This is motivated by the fact that negative skew may allow a larger timing budget for gate sizing. We construct a useful-skew tree (UST) such that the total clock and logic power (measured as a cost function) is minimized. Given a required clock period and feasible gate sizes, a set of negative and positive skew bounds are generated. The allowable skews within these bounds and feasible gate sizes form the feasible solution space of our problem. We use a merging segment perturbation procedure and a simulated annealing approach to explore various tree configurations. This is complemented by a bi-partitioning heuristic to generate appropriate connection topology and take advantage of useful skews. Experimental results have shown 11% to 22% total power reduction over previous methods of clock routing with zero-skew or single fixed skew bound and separately sizing logic gates