A Fast Hierarchical Adaptive Analog Routing Algorithm Based on Integer Linear Programming

Abstract

The shrinking design window and high parasitic sensitivity in advanced technologies have imposed special challenges on analog and radio frequency (RF) integrated circuit design. The state-of-the-art analog routing research tends to favor linear programming to achieve various analog constraints, which, although effective, fail to offer high routing efficiency on its own. In this article, we propose a new methodology to address such a deficiency based on integer linear programming (ILP) but without compromising the capability of handling any special constraints for the analog routing problems. Our proposed method supports hierarchical routing, which can divide the entire routing area into multiple small heterogeneous regions where the ILP can efficiently derive routing solutions. Distinct from the conventional methods, our algorithm utilizes adaptive resolutions for various routing regions. For a more congested region, a routing grid with higher resolution is employed, whereas a lower-resolution grid is adopted to a less-crowded routing region. For a large empty space, routing efficiency can be even boosted by creating more routing hierarchy levels. This scheme is especially beneficial to the analog and RF layouts, which are far sparser than their digital counterparts. The experimental results show that our proposed adaptive ILP-based router is much faster than the conventional ones, since it spends much less time in the areas that need no accurate routing anyway. The higher efficiency is demonstrated for large circuits and especially sparse layouts along with promising routing quality in terms of analog constraints.