Design of an RF low-noise bandpass filter using active capacitance circuit

Design of an RF low-noise bandpass filter using active capacitance circuit

In this paper, a novel RF active bandpass filter (BPF) is proposed and its noise performance is optimized by noise analysis. In the proposed design, a resonator consists of an active capacitance circuit together with a conventional inductor. The active capacitor is made of a field-effect transistor...

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Veröffentlicht in:IEEE transactions on microwave theory and techniques 2005-02, Vol.53 (2), p.687-695
Hauptverfasser: CHUN, Young-Hoon, LEE, Jae-Ryong, YUN, Sang-Won, RHEE, Jin-Koo
Format: Artikel
Sprache:eng
Schlagworte:
Active filters
Active inductors
Active noise reduction
Applied sciences
Band pass filters
Bandpass filters
bandpass filters (BPFs)
Capacitance
Capacitors
Circuit design
Circuit noise
Circuit properties
Design engineering
Electric, optical and optoelectronic circuits
Electronic circuits
Electronics
Exact sciences and technology
filter noise
Frequency filters
Inductors
Microwave circuits, microwave integrated circuits, microwave transmission lines, submillimeter wave circuits
negative resistance circuits
Noise
Noise figure
Performance analysis
Radio frequencies
Radio frequency
Ripples
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Beschreibung
Zusammenfassung:In this paper, a novel RF active bandpass filter (BPF) is proposed and its noise performance is optimized by noise analysis. In the proposed design, a resonator consists of an active capacitance circuit together with a conventional inductor. The active capacitor is made of a field-effect transistor that exhibits negative resistance as well as capacitance. It can, therefore, compensate the loss of an inductor. Whereas the conventional active filters using negative resistance circuits usually have a high noise figure, the proposed active filter shows good noise property achieved by adopting a novel active capacitance circuit, which is proven by noise analysis and the experimental result. The measured second-order active BPF shows bandwidth of 95 MHz, 0.1-dB insertion loss, 0.3-dB ripple, and a noise figure of 2.4 dB at the 1.9-GHz band, which agrees well with the simulated results
ISSN:0018-9480
1557-9670
DOI:10.1109/TMTT.2004.840565