Construction of Latency-Bounded Clock Trees.

Clock trees must be constructed to function even under the influence of on-chip variations (OCV). Bounding the latency of a clock tree, i.e., the maximum delay from the tree root to any sequential element, is important because the latency correlates with the maximum magnitude of the skews caused by OCV. In this paper, a latency constraint graph (LCG) that captures the latencies of a set of subtrees and the skew constraints between the subtrees is introduced. The minimum latency of a clock tree that can be constructed from the corresponding subtrees is equal to the (negative of the) length of a shortest path in the LCG, which can be computed in $O(VE)$. Based on the LCG, we propose a framework that consists of a latency-aware clock tree synthesis (CTS) phase and a clock tree optimization (CTO) phase to construct latency-bounded clock trees. When applied to a set of synthesized circuits, the framework is capable of constructing latency-bounded clock trees that have higher yield compared to clock trees constructed in previous studies.