DocumentCode
507390
Title
Voltage-drop aware analytical placement by global power spreading for mixed-size circuit designs
Author
Chuang, Yi-Lin ; Lee, Po-Wei ; Chang, Yao-Wen
Author_Institution
Grad. Inst. of Electron. Eng., Nat. Taiwan Univ., Taipei, Taiwan
fYear
2009
fDate
2-5 Nov. 2009
Firstpage
666
Lastpage
673
Abstract
Excessive supply voltage drops in a circuit may lead to significant circuit performance degradation and even malfunction. To handle this problem, existing power delivery aware placement algorithms model voltage drops as an optimization objective. We observe that directly minimizing voltage drops in an objective function might not resolve voltage-drop violations and might even cause problems in power-integrity convergence. To remedy this deficiency, in this paper, we propose new techniques to incorporate device power spreading forces into a mixed-size analytical placement framework. Unlike the state-of-the-art previous work that handles the worst voltage-drop spots one by one, our approach simultaneously and globally spreads all the blocks with voltage-drop violations to desired locations directly to minimize the violations. To apply the power force, we model macro current density and power rails for our placement framework to derive desired macro/cell locations. To further improve the solution quality, we propose an efficient mathematical transformation to adjust the power force direction and magnitude. Experimental results show that our approach can substantially improve the voltage drops, wirelength, and runtime over the previous work.
Keywords
circuit optimisation; current density; electric potential; power aware computing; device power spreading forces; global power spreading; macro current density rail; mathematical transformation; mixed-size analytical placement framework; mixed-size circuit designs; optimization objective; power delivery aware placement algorithms; power force direction; power force magnitude; power-integrity convergence; voltage-drop minimisation; Circuit optimization; Circuit synthesis; Convergence; Design engineering; Energy consumption; Performance analysis; Permission; Process design; System-on-a-chip; Voltage;
fLanguage
English
Publisher
ieee
Conference_Titel
Computer-Aided Design - Digest of Technical Papers, 2009. ICCAD 2009. IEEE/ACM International Conference on
Conference_Location
San Jose, CA
ISSN
1092-3152
Print_ISBN
978-1-60558-800-1
Electronic_ISBN
1092-3152
Type
conf
Filename
5361223
Link To Document