Abstract
Modern MOSFETs operated at high frequencies are designed and fabricated using a multi-fingered structure to enhance performance, especially to reduce gate resistance. However, even though the layout-dependent effect of other parasitics, such as that related to the source and drain resistances, is becoming more important, it has not been extensively investigated at high frequencies. In this paper, source and drain resistances are experimentally determined and analyzed for several microwave MOSFETs to characterize their corresponding dependence on the layout. This allows for the quantification and modeling of the impact of the device's geometry on its parasitic extrinsic parameters. Physically based closed-form equations are proposed here to accurately represent S-parameters of MOSFETs operating at microwave frequencies with layouts considering different numbers of gate fingers, and grouping devices in cells with multiple source and drain junctions. The proposed models are compatible with SPICE-like circuit simulators, and an excellent model-experiment correlation is obtained when using the proposed scalable equations to represent different geometry MOSFETs up to 60 GHz.
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