1-3hit |
Tsuyoshi SAKATA Takaaki OKUMURA Atsushi KUROKAWA Hidenari NAKASHIMA Hiroo MASUDA Takashi SATO Masanori HASHIMOTO Koutaro HACHIYA Katsuhiro FURUKAWA Masakazu TANAKA Hiroshi TAKAFUJI Toshiki KANAMOTO
Leakage current is an important qualitative metric of LSI (Large Scale Integrated circuit). In this paper, we focus on reduction of leakage current variation under the process variation. Firstly, we derive a set of quadratic equations to evaluate delay and leakage current under the process variation. Using these equations, we discuss the cases of varying leakage current without degrading delay distribution and propose a procedure to reduce the leakage current variations. From the experiments, we show the proposed method effectively reduces the leakage current variation up to 50% at 90 percentile point of the distribution compared with the conventional design approach.
Takaaki OKUMURA Atsushi KUROKAWA Hiroo MASUDA Toshiki KANAMOTO Masanori HASHIMOTO Hiroshi TAKAFUJI Hidenari NAKASHIMA Nobuto ONO Tsuyoshi SAKATA Takashi SATO
Process variation is becoming a primal concern in timing closure of LSI (Large Scale Integrated Circuit) with the progress of process technology scaling. To overcome this problem, SSTA (Statistical Static Timing Analysis) has been intensively studied since it is expected to be one of the most efficient ways for performance estimation. In this paper, we study variation of output transition-time. We firstly clarify that the transition-time variation can not be expressed accurately by a conventional first-order sensitivity-based approach in the case that the input transition-time is slow and the output load is small. We secondly reveal quadratic dependence of the output transition-time to operating margin in voltage. We finally propose a procedure through which the estimation of output transition-time becomes continuously accurate in wide range of input transition-time and output load combinations.
Masanori HASHIMOTO Junji YAMAGUCHI Hidetoshi ONODERA
Spatial power/ground level variation causes power/ground level mismatch between driver and receiver, and the mismatch affects gate propagation delay. This paper proposes a timing analysis method based on a concept called "PG level equalization" which is compatible with conventional STA frameworks. We equalize the power/ground levels of driver and receiver. The charging/discharging current variation due to equalization is compensated by replacing output load. We present an implementation method of the proposed concept, and demonstrate that the proposed method works well for multiple-input gates and RC load model.