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Design and Analysis of Linear Channel-Selection Filter for Direct Conversion Receiver  

Jin, Sang-Su (Department of Electrical Engineering, MMlC Lab, POSTECH)
Ryu, Seong-Han (Department of Electrical Engineering, MMlC Lab, POSTECH)
Kim, Hui-Jung (Department of Electrical Engineering, MMlC Lab, POSTECH)
Kim, Bum-Man (Department of Electrical Engineering, MMlC Lab, POSTECH)
Lee, Jong-Ryul (Future Communications IC)
Publication Information
JSTS:Journal of Semiconductor Technology and Science / v.4, no.4, 2004 , pp. 293-299 More about this Journal
Abstract
An active RC 2nd order Butterworth filter suitable for a baseband channel-selection filter of a direct conversion receiver is presented. The linearity of the 2nd order Butterworth filter is analyzed. In order to improve the linearity of the filter, the operational amplifiers should have a high linear gain and low 3rd harmonic, and the filter should be designed to have large feedback factor. This second order Butterworth filter achieves-14dBV in-channel (400kHz, 500kHz) IIP3, +29dBV out-channel (10MHz, 20.2MHz) IIP3 and 15.6 $nV/\sqrt{Hz}$ input-referred noise and dissipates 10.8mW from a 2.7-V supply. The analysis and experimental results are in good agreement
Keywords
Analog integrated filter; passive matrix frequency tuning; linearity analysis; operational amplifier (OPAMP); active-RC filter; channel-selection filter;
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