High-tuning-range CMOS band-pass IF filter based on a low-Q cascaded biquad optimization technique

A design procedure for high-order continuous-time intermediate-frequency band-pass filters based on the cascade of low-Q biquadratic cells is presented. The approach is well suited for integrated-circuit fabrication, as it takes into account the maximum capacitance spread dictated by the available technology and maximum acceptable sensitivity to component variations. A trade-off between noise and maximum linear range is also met. A novel, wide-tuning-range transconductor topology is also described. Based on these results, a 10-pole band-pass filter for a code division multiple-access satellite receiver has been designed and tested. The filter provides tunable center frequency f0 from 10 to 70MHz and exhibits a 28-MHz bandwidth around f0=70MHz with more than 39-dB attenuation at f0/2 and 2f0. Third-order harmonic rejection is higher than 60dB for a 1-Vpp 70-MHz input, and equivalent output noise is lower than 1mVrms. The circuit is fabricated in a 0.25-µm complementary metal oxide semiconductor process, and the core consumes 12mA from a 2.5-V supply, offering the best current/pole ratio figure. The die area resulted to be 0.9×1.1mm2. Copyright © 2014 John Wiley & Sons, Ltd.

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