Abstract
This paper provides an extensive analysis of the performance of a six-port based direct conversion receiver (SPR) in terms of signal quality, dynamic range, noise figure, ports matching, isolation, bandwidth, and cost. Calibration technique using multimemory polynomials has been adopted in order to improve the signal quality of the six-port receiver. The performances of the calibrated receiver are then compared with the performances of a commercially availableI-Qdemodulator used as a low-IF receiver. The main advantages and disadvantages of the SPR compared to the low-IF receiver are highlighted. The major advantages of the SPR come in terms of its available input frequency bandwidth and the low power requirement. The SPR system requires no external bias supply but suffers in terms of the available conversion gain. A better port matching of the SPR can be guaranteed over a wide frequency bandwidth, which mixer based receiver systems lack. The main component limiting the performance of a SPR is the diode detector. A faster and a better diode detector will alleviate some of the problems highlighted in this paper. The SPR system is calibratable and its error-vector-magnitude performance can be made better than theI-Qdemodulator used as a low-IF receiver.
Highlights
The Six-Port technique was first introduced in the 1970s for accurate power measurement and reflectometer applications [1, 2]
Because of passive quadrature hybrids and power dividers involvement better port matching over a wide frequency bandwidth can be achieved in case of Six-Port based receiver (SPR) system, while lowIF receiver offers better isolation between the radio frequency (RF) and the local oscillator (LO) ports
Multimemory polynomial calibration technique has been applied to the detected voltage readings from the four power detectors in order to boost the linearity of the receiver
Summary
The Six-Port technique was first introduced in the 1970s for accurate power measurement and reflectometer applications [1, 2]. The six-port concept, as a radio frequency (RF) front-end in communication receivers, is usually implemented using power dividers and quadrature hybrid circuits [6, 7].
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