Title :
A Physics-Based Equivalent-Circuit Model for On-Chip Symmetric Transformers With Accurate Substrate Modeling
Author :
Wang, Chuan ; Liao, Huailin ; Xiong, Yongzhong ; Li, Chen ; Huang, Ru ; Wang, Yangyuan
Author_Institution :
Inst. of Microelectron., Peking Univ., Beijing
fDate :
4/1/2009 12:00:00 AM
Abstract :
A physics-based equivalent-circuit model for on-chip symmetric transformers is presented with all the model elements driven from fabrication specifications. Two extra coupled transformer loops are used for each coil to model the parameters of skin effect, proximity effect, and reflective effect of the substrate eddy current, respectively. Model accuracy under free space is first demonstrated using an electromagnetic field solver without considering substrate loss. Several sets of transformers were fabricated on a standard 0.18- mum 1P8M RF CMOS technology to further verify the accuracy and scalability of the proposed model. By careful comparison of S -parameters, coil inductance, quality factor,coupling coefficient, and maximum available gain between measured data and simulated data, model accuracy, and scalability are verified over a wide range of geometry configurations.
Keywords :
CMOS integrated circuits; coils; eddy currents; equivalent circuits; geometry; transformers; CMOS technology; S -parameters; coil inductance; coupling coefficient; electromagnetic field solver; fabrication specifications; geometry configurations; maximum available gain; onchip symmetric transformers; physics-based equivalent-circuit model; proximity effect; quality factor; reflective effect; skin effect; substrate eddy current; substrate modeling; Baluns; eddy current; equivalent circuit; physical model; transformers;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2009.2014479
