An Augmented Lagrangian Optimization Method for VLSI Global Placement

Author

Weiguo Li ; Jianli Chen ; Wenxing Zhu

Author_Institution

Center for Discrete Math. & Theor. Comput. Sci., Fuzhou Univ., Fuzhou, China

fYear

2012

fDate

14-16 Dec. 2012

Firstpage

569

Lastpage

573

Abstract

Ignoring some cell overlaps, global placement computes the best position for each cell to minimize some cost metric (e.g., total wire length, density overflow). It is a crucial step in very large scale integration (VLSI) physical design, because it affects rout ability, performance, and power consumption of a circuit. In this paper, we propose an Augmented Lagrangian method to solve the VLSI global placement. In this method, a cautious dynamic density weight increasing strategy is used to balance the wire length and density constraint. We incorporated our method into NTUplace3´s global placement framework, and tested it on the IBM mixed-size benchmark circuits. Experimental results show that it obtains high-quality results in a reasonable running time.

Keywords

Lagrangian field theory; VLSI; integrated circuit design; optimisation; IBM mixed-size benchmark circuits; NTUplace3 global placement framework; VLSI global placement; augmented Lagrangian optimization method; cautious dynamic density weight increasing strategy; density constraint; very large scale integration physical design; Benchmark testing; Density functional theory; Minimization; Optimization methods; Runtime; Very large scale integration; Augmented Lagrangian Multiplier; Global placement; VLSI; nonlinear optimization;

fLanguage

English

Publisher

ieee

Conference_Titel

Parallel and Distributed Computing, Applications and Technologies (PDCAT), 2012 13th International Conference on

Conference_Location

Beijing

Print_ISBN

978-0-7695-4879-1

Type

conf

DOI

10.1109/PDCAT.2012.41

Filename

6589339