Augmented Hammerstein model for six-port-based wireless receiver calibration

Augmented Hammerstein model for six-port-based wireless receiver calibration

An augmented Hammerstein model (AHM) is proposed for the first time to calibrate a six-port-based receiver (SPR) and to recover the in-phase I and the quadrature Q components of a modulated wideband RF signal. The proposed model is intended to provide a good compromise between complexity and accurac...

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Bibliographic Details
Published in:IET communications 2017-04, Vol.11 (6), p.951-960
Main Authors: Chagtmi, Nadia, Boulejfen, Noureddine, Ghannouchi, Fadhel M
Format: Article
Language:eng
Subjects:
64‐QAM signals
AHM based single‐step calibration technique
augmented Hammerstein model
bandwidth 2 MHz
bandwidth 4 MHz
error vector magnitude
memory polynomial model
modulated wideband RF signal
polynomials
quadrature amplitude modulation
radio receivers
Research Article
six‐port‐based wireless receiver calibration
SPR
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Summary:An augmented Hammerstein model (AHM) is proposed for the first time to calibrate a six-port-based receiver (SPR) and to recover the in-phase I and the quadrature Q components of a modulated wideband RF signal. The proposed model is intended to provide a good compromise between complexity and accuracy. To verify the performance of the resulting calibration approach, an experimental validation has been performed with an SPR driven by wideband modulated signals with different bandwidths. An error vector magnitude between the transmitted and received signals of 2.17 and 1.33% has been reported for 64-QAM signals with 4 and 2 MHz bandwidths, respectively. The obtained measurement results have revealed the robustness and the superiority of the AHM-based single-step calibration technique compared with the two-step conventional procedure. Moreover, the AHM achieved the same performance as the published memory polynomial model while requiring ∼60% less coefficients leading to a less complexity calibration procedure with a lower number of calibration parameters and flops.
ISSN:1751-8628
1751-8636
1751-8636