Efficient Modeling of Distributed Dynamic Self-Heating and Thermal Coupling in Multifinger SiGe HBTs

In this paper, we propose an efficient model for dynamic self-heating and thermal coupling in a multifinger transistor system. Essentially, the proposed model is an improvement over a state-of-the-art existing model from the viewpoint of simulation time. Verilog-A implementation of the proposed model does not require to use any voltage controlled voltage source. In a multifinger transistor system, with $n$ emitter fingers, our model uses $3n$ extra nodes in Verilog-A implementation whereas it is $2n^{2}-n$ for the state-of-the-art model. Note that our model requires no extra nodes for implementing the thermal coupling effects. We present that the transient simulation results of our model are identical with those of the state-of-the-art model. Electrothermal simulation using the proposed thermal model shows good agreement with the measured data. It is found that the proposed model simulates more than 40% faster compared with the existing model for a ring oscillator circuit.