標題: Critical-Trunk-Based Obstacle-Avoiding Rectilinear Steiner Tree Routings and Buffer Insertion for Delay and Slack Optimization
作者: Lin, Yen-Hung
Chang, Shu-Hsin
Li, Yih-Lang
交大名義發表
National Chiao Tung University
關鍵字: Buffer insertion;Elmore delay model;obstacle-avoiding rectilinear Steiner tree;performance-driven routing;timing constraint
公開日期: 1-九月-2011
摘要: For modern designs, delay optimization significantly facilitates success in design closure owing to its more realistic metric than wirelength in routing. Obstacle-avoiding rectilinear Steiner tree (OARST) construction is an essential routing problem. With the trends toward Internet protocol-block-based system-on-chip designs, OARST with buffer insertion has been surveyed to diminish the delay of long wires. Previous works on performance-driven (PD) OARST without and with buffer insertion can only handle small circuits. This paper develops a novel routing algorithm in obstacle-avoiding spanning graph to construct OARST with optimized delay efficiently. The proposed multisource single-target maze routing is first employed to identify the critical trunks, and the critical-trunk-based tree growth mechanism connects the unconnected pins to critical trunks under delay constraints of every sink. We apply the proposed critical-trunk-based tree growth mechanism to solve PD and slack-driven (SD) OARST problems. The proposed algorithms are extended to consider buffer insertion during PD and SD OARST constructions. Experimental results demonstrate that the proposed algorithms achieve an average 25.84% improvement in the maximum delay over obstacle-avoiding rectilinear Steiner minimal tree in the PD OARST problem and successfully solve 66.67% worst negative slack violations in the SD OARST problem. Compared to the simultaneous routing and buffer insertion approach, the proposed buffer-aware (BA) algorithm generates satisfactory timing results with almost identical wire length (WL). Moreover, the proposed BA SD OARST algorithm utilizes less WL than the BA rectilinear Steiner tree construction does by 17.99% on average. The runtime comparison with previous works shows the efficiency and scalability of this paper.
URI: http://dx.doi.org/10.1109/TCAD.2011.2150222
http://hdl.handle.net/11536/19748
ISSN: 0278-0070
DOI: 10.1109/TCAD.2011.2150222
期刊: IEEE TRANSACTIONS ON COMPUTER-AIDED DESIGN OF INTEGRATED CIRCUITS AND SYSTEMS
Volume: 30
Issue: 9
起始頁: 1335
結束頁: 1348
顯示於類別:期刊論文


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