Title :
Interconnection modelling using distributed RLC models
Author :
Kucar, Dorothy ; Vannelli, Anthony
Author_Institution :
Dept. of Electr. & Comput. Eng., Waterloo Univ., Ont., Canada
Abstract :
In physical design software, it is often necessary to estimate net, i.e. interconnection delays. Interconnections are typically modelled as lumped RC circuits. This approximation is reasonable in technologies where overall delay is dominated by gate delays. With present sub 130 nm technologies, characteristic signal propagation lengths are comparable to signal wavelengths. Interconnections no longer allow currents to flow through efficiently, resulting in a conspiracy of capacitative, resistive and inductive effects. In recent years, more accurate interconnections models, that approximate an interconnection as n distributed RLC segments, have been devised. In this work, we let the number of segments go to infinity and obtain exact expressions for voltages. In particular, we present a mathematically rigorous time-domain analysis of the Lossy Transmission Line Model.
Keywords :
RLC circuits; interconnections; time-domain analysis; transmission lines; capacitative effect; distributed RLC model; gate delay; inductive effect; interconnection delay; interconnection modelling; lossy transmission line model; lumped RC circuits; mathematically rigorous time-domain analysis; physical design software; resistive effect; signal propagation length; signal wavelength; Delay estimation; H infinity control; Integrated circuit interconnections; Mathematical model; Propagation losses; RLC circuits; Software design; Time domain analysis; Transmission lines; Voltage;
Conference_Titel :
System-on-Chip for Real-Time Applications, 2003. Proceedings. The 3rd IEEE International Workshop on
Print_ISBN :
0-7695-1944-X
DOI :
10.1109/IWSOC.2003.1213001
