QAM Signal Demodulation Algorithm with Minimum Sample Per Symbol Rate

The article discusses a new QAM signal demodulation algorithm based on an adaptive equalizer. The research refers to receiving devices development for communication systems, using PSK/QAM signal for channel modulation. Results can be used in the development of demodulation schemes for satellite, rad...

Full description

Saved in:
Bibliographic Details
Main Authors: Zhuravlev, A. P., Chadov, T. A.
Format: Conference Proceeding
Language:English
Subjects:
adaptive equalization
Adaptive equalizers
communication systems receiving device
Optical fiber communication
QAM signal processing
Quadrature amplitude modulation
quadrature demodulation
Receivers
Signal processing algorithms
Symbols
Synchronization
Online Access:Request full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The article discusses a new QAM signal demodulation algorithm based on an adaptive equalizer. The research refers to receiving devices development for communication systems, using PSK/QAM signal for channel modulation. Results can be used in the development of demodulation schemes for satellite, radio relay and optical communication systems. Adaptive clock recovery algorithm as a modification of the adaptive equalizer is presented for the "blind" equalization variant in the continuous signal processing scheme. This algorithm can also be effectively used in demodulation schemes for block-continuous signals with the equalizer coefficients adjustment using unique words and pilot symbols. The presented clock recovery algorithm has a low computational complexity corresponding to the clock rate detuning. QAM signal demodulation algorithm effectively operates at an input sampling rate of 2 samples per modulation symbol without penalty and reducing noise immunity. It is possible to develop demodulation schemes operating at an input sampling rate of 1.5 and 1 sample per modulation symbol with quality penalty.
ISSN:2832-0514
DOI:10.1109/SYNCHROINFO55067.2022.9840921