Abstract
A classic second-order coupled-capacitor Chebyshev bandpass filter using resonator of tunable active capacitor and inductor is presented. The low cost and small size of CMOS active components make the bandpass filter (BPF) attractive in fully integrated CMOS applications. The tunable active capacitor is designed to compensate active inductor’s resistance for resistive match in the resonator. In many design cases, more than 95% resistive loss is cancelled. Meanwhile, adjusting design parameter of the active component provides BPF tunability in center frequency, pass band, and pass band gain. Designed in 1.8 V 180 nanometer CMOS process, the BPF has a tuning frequency range of 758–864 MHz, a controllable pass band of 7.1–65.9 MHz, a quality factor Q of 12–107, a pass band gain of 6.5–18.1 dB, and a stopband rejection of 38–50 dB.
Highlights
The rapid development of complementary metal-of-semiconductor (CMOS) endues the integrated circuit with small size and low cost in both digital and analog applications
A wireless communication system mainly consists of three components: mixer, bandpass filter, and low noise amplifier
Reducing resistive loss in the Chebyshev bandpass filter has been presented in improvement on pass band gain, bandwidth, and center frequency [1, 2, 5,6,7,8]
Summary
The rapid development of complementary metal-of-semiconductor (CMOS) endues the integrated circuit with small size and low cost in both digital and analog applications. Using AC and AI to produce a small size and low cost BPF with tunable gain, tunable center frequency, and tunable bandwidth is a feasible and cost-effective solution For this reason, eliminating resistive loss in AI will improve BPF quality factor. Reducing resistive loss in the Chebyshev bandpass filter has been presented in improvement on pass band gain, bandwidth, and center frequency [1, 2, 5,6,7,8]. The transformer-based passive inductor produces a frequency-dependent negative resistance for resistive loss compensation [8] It operates at a center frequency of 2,368 MHz and a bandwidth of 60 MHz. But passive inductors make area much larger than active BPFs [5,6,7]. Summary of this work and comparison with previous work are presented
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