An efficient method for ECSM characterization of CMOS inverter in nanometer range technologies

B. Kaur, S. Miryala, S. Manhas, B. Anand
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引用次数: 2

Abstract

Accurate estimation of delay is a major challenge in current nanometer regime using Non Linear Delay Model (NLDM) due to issues such as parametric variation, nonlinear capacitance value etc. It demands a large number of simulations to be performed for getting the accurate delay values. To partly solve this issue, people have started using Effective Current Source Model (ECSM), which stores certain predefined Threshold Crossing Point (TCP) of the output voltage waveform with respect to different input transition time (TR) values and load capacitance (Cl). In this work, we propose an analytical timing model relating 10% - 90% TCPs with Cl and TR values. We also derive the relationship between the cell size and the model coefficients. We also derive the region of validity of the model in (TR, Cl) space and determine its relationship with cell size. The proposed model is in good agreement with HSPICE simulations with a maximum relative error of 2.5%. We verified the proposed model with technology scaling. We use this model and the relationships to reduce the number of simulations in ECSM library characterization.
一种纳米范围内CMOS逆变器ECSM表征的有效方法
由于参数变化、电容值非线性等问题,在当前纳米体系中,利用非线性延迟模型(NLDM)准确估计延迟是一个重大挑战。为了得到准确的延迟值,需要进行大量的仿真。为了部分解决这个问题,人们已经开始使用有效电流源模型(ECSM),它存储了相对于不同输入过渡时间(TR)值和负载电容(Cl)的输出电压波形的某些预定义阈值交叉点(TCP)。在这项工作中,我们提出了一个关于10% - 90% tcp与Cl和TR值的分析时序模型。我们还推导了单元格大小与模型系数之间的关系。我们还推导了模型在(TR, Cl)空间中的有效区域,并确定了其与细胞大小的关系。该模型是在良好的协议与HSPICE模拟的最大相对误差为2.5%。我们用技术尺度验证了所提出的模型。我们使用该模型和关系来减少ECSM库表征中的模拟次数。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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