Title :
Equivalent circuit model of a stacked inductor for high-Q on-chip RF applications
Author :
Lim, C.C. ; Yeo, K.S. ; Chew, K.W. ; Tan, C.Y. ; Do, M.A. ; Ma, J.-G. ; Chan, L.
Author_Institution :
Sch. of Electr. & Electron. Eng., Nanyang Technol. Univ., Singapore
Abstract :
A novel design for a stacked inductor using RLC elements is presented. The proposed model used to predict the stacked inductor is based on a 4-port circuit design with semi-empirical derivation. The modified RS formulas are implemented accurately to predict the series resistance of the stacked inductor. The verification has been carried out using a mature 0.18 mum process to fabricate stacked inductor with various sizes and types. All the measured data are extracted from a silicon device based on a physical layered test system (PLTS). The predicted and measured S-parameter results show excellent correlation in terms of performance for frequencies up to 15 GHz. A high-Q on-chip active inductor is demonstrated using a multiple turns stacked inductor
Keywords :
Q-factor; RLC circuits; S-parameters; equivalent circuits; inductors; multiport networks; 0.18 micron; 4-port circuit design; RLC elements; S-parameter; equivalent circuit model; high-Q on-chip RF applications; high-Q on-chip active inductor; physical layered test system; stacked inductor;
Journal_Title :
Circuits, Devices and Systems, IEE Proceedings -
