A Low-Complexity Self-Calibrating Adaptive Quadrature Receiver

In this paper digital part of a self-calibrating quadrature-receiver is described, containing a digital calibration-engine. The blind source-separation-based calibration-engine eliminates the RF-impairments in real-time hence improving the receiver's performance without the need for test/pilot...

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Hauptverfasser:	Cetin, E., Demirsoy, S.S., Kale, I., Morling, R.C.S.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Constellation diagram Degradation Digital signal processing Energy consumption Field programmable gate arrays Hardware Radio frequency Signal processing Transceivers Very large scale integration
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creator	Cetin, E. Demirsoy, S.S. Kale, I. Morling, R.C.S.
description	In this paper digital part of a self-calibrating quadrature-receiver is described, containing a digital calibration-engine. The blind source-separation-based calibration-engine eliminates the RF-impairments in real-time hence improving the receiver's performance without the need for test/pilot tones, trimming or use of power-hungry discrete components. Furthermore, an efficient time-multiplexed calibration-engine architecture is proposed and implemented on an FPGA utilising a reduced-range multiplier structure. The use of reduced-range multipliers results in substantial reduction of area as well as power consumption without a compromise in performance when compared with an efficiently designed general purpose multiplier. The performance of the calibration-engine does not depend on the modulation format or the constellation size of the received signal; hence it can be easily integrated into the digital signal processing paths of any receiver
doi_str_mv	10.1109/AHS.2006.7
format	Conference Proceeding
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subjects	Constellation diagram Degradation Digital signal processing Energy consumption Field programmable gate arrays Hardware Radio frequency Signal processing Transceivers Very large scale integration
title	A Low-Complexity Self-Calibrating Adaptive Quadrature Receiver
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