Title :
Post-placement lithographic hotspot detection and removal in one-dimensional gridded designs
Author :
Wuu, Jen-Yi ; Simmons, Mark ; Marek-Sadowska, Malgorzata
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of California, Santa Barbara, CA, USA
Abstract :
As double patterning techniques mature, they become the primary approaches enabling feature size scaling beyond 32nm. Although it is possible to print dense patterns by splitting the design into two masks, printability problems and pattern distortion remains a major concern. In this paper, we study the potential lithographic hotspots that may occur between the line ends in one-dimensional gridded designs obtained with Line-End Cut (LEC) method [2]. We propose a post-placement hotspot detection and removal algorithm that perturbs the cell locations to eliminate all hotspots. Hotspot detection is performed using a pattern classifier based on machine learning techniques. Experimental results show that we can successfully eliminate all hotspots with excellent runtime efficiency and insignificant overhead on estimated wire lengths.
Keywords :
learning (artificial intelligence); masks; pattern classification; photolithography; LEC method; double patterning techniques; line-end cut method; machine learning techniques; masks; one-dimensional gridded designs; pattern classifier; pattern distortion; post-placement lithographic hotspot detection; printability problems; removal algorithm; Classification algorithms; Context; Labeling; Layout; Machine learning algorithms; Robustness; Training; DFM; Design for manufacturability; gridded design; hotspot detection; hotspot removal; machine learning; placement; printability;
Conference_Titel :
Quality Electronic Design (ISQED), 2012 13th International Symposium on
Conference_Location :
Santa Clara, CA
Print_ISBN :
978-1-4673-1034-5
DOI :
10.1109/ISQED.2012.6187494
