An Effective Timing-Driven Detailed Placement Algorithm for FPGAs.

In this paper, we propose a new timing-driven detailed placement technique for FPGAs based on optimizing critical paths. Our approach extends well beyond the previously known critical path optimization approaches and explores a significantly larger solution space. It is also complementary to single-net based timing optimization approaches. The new algorithm models the detailed placement improvement problem as a shortest path optimization problem, and optimizes the placement of all elements in the entire timing critical path simultaneously, while minimizing the costs of adjusting the placement of adjacent non-critical elements. Experimental results on industrial circuits using a modern FPGA device show an average placement clock frequency improvement of 4.5%.