In DSM technology and beyond, the performance and correctness of the circuit cannot be assured without taking into consideration the multiple effects of interconnect parasitics. The inter wire parasitics i.e. mutual inductance and coupling capacitance are primary sources of crosstalk noise. In this paper, the optimization of coupling capacitance for delay and peak noise is carried out qualitatively. This optimization process is essential from the fact that propagation delay and peak noise in some cases show opposite behavior with change in coupling capacitance. For our study, two distributed RLC lines coupled inductively and capacitively are considered. A pair of interconnect lines each of 4 mm length and terminated by capacitive load of 30 fF with varying capacitive and inductive couplings are simulated. The SPICE waveforms are generated for simultaneous switching of inputs at far end of lines. The simulation is carried out for 130 nm, 1.5 V technology node. The width of driver PMOS and NMOS are taken as 70 μm and 35 μm respectively.
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机译:在DSM技术及更远的情况下,在不考虑互连寄生菌的多种效果的情况下,不能保证电路的性能和正确性。 Inter Wirce acisitics即互感和耦合电容是串扰噪声的主要源。在本文中,定性地执行延迟和峰值噪声的耦合电容的优化。这种优化过程是因为在某些情况下传播延迟和峰值噪声的事实表明了耦合电容的变化的相反行为。对于我们的研究,考虑两个分布式RLC线路耦合耦合的电感和电容。模拟了一对互连线,每个长度为4 mm长度,并且通过具有不同电容和电感耦合的30FF的电容负载终止。生成SPICE波形以在远端同时切换输入的输入。仿真是为130nm,1.5 V技术节点进行的。驱动器PMOS和NMOS的宽度分别为70μm和35μm。
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