Development and Study of Demodulation Techniques for Frequency Manipulated Signals
Abstract
The goal of our research is development and study of different demodulation techniques for a frequency shift keyed signals. The signal under study is a frequency-shift keyed (FSK) signal when the information signal regulates the carrier frequency. We consider a model imitating data transmission channels and allowing us to perform error counting. The data transmission channels have ideal synchronization. Several techniques of demodulator design are introduced for demodulating frequency-shift keyed (FSK) signal and we compare the techniques using the criterion of error number of a demodulated signal relative to a signal prior to modulation for different signal-to-noise ratio. Signal-to-noise ratio is calculated as a ratio of the energy of the information symbol to the noise power spectral density. We have tested different demodulation techniques with different signal-to-noise ratio and produced a table containing information on demodulation accuracy for different techniques. Overall, we have simulated 100 sec. of continuous bit packages. We indicate that the best results for signal-to-noise ratio exceeding 5 dB are provided with the technique based on double correlation, and for signal-to-noise ratio less than 5 dB - with the technique based on the fast Fourier transform.
About the Authors
D. I. Kaplun
Saint Petersburg Electrotechnical University "LETI"
Russian Federation
Ph.D. on Engineering (2009), Associate Professor of the Department of Automation and Control Processes
Russian Federation
Ph.D. on Engineering (2009), Associate Professor of the Department of Automation and Control Processes
V. V. Gulvanskiy
Saint Petersburg Electrotechnical University "LETI"
Russian Federation
Master's Degree in Engineering and Technology in Engineering System Management (2015), postgraduate student of the Department of Automation and Control Processes
Russian Federation
Master's Degree in Engineering and Technology in Engineering System Management (2015), postgraduate student of the Department of Automation and Control Processes
I. I. Kanatov
Saint Petersburg Electrotechnical University "LETI"
Russian Federation
Ph.D. in Engineering (1974), Associate Professor (1980) of the Department of Automation and Control Processes
Russian Federation
Ph.D. in Engineering (1974), Associate Professor (1980) of the Department of Automation and Control Processes
D. M. Klionskiy
Saint Petersburg Electrotechnical University "LETI"
Russian Federation
Ph.D. in Engineering (2013), Associate Professor of the Department of Software and Computer Application
Russian Federation
Ph.D. in Engineering (2013), Associate Professor of the Department of Software and Computer Application
V. F. Lapizkiy
PJSC "Inteltech"
Russian Federation
Ph.D. in Engineering (2000), Associate Professor (2001). Head of the Department
Russian Federation
Ph.D. in Engineering (2000), Associate Professor (2001). Head of the Department
V. I. Bobrovskiy
PJSC "Inteltech"
Russian Federation
D.Sc. in Engineering (2009), Associate Professor (2010), Head of Department
Russian Federation
D.Sc. in Engineering (2009), Associate Professor (2010), Head of Department
K. V. Frolov
PJSC "Inteltech"
Russian Federation
ster’s Degree in Digital, Microwave and Optical Communication Systems (2016), 2nd Class Engineer
Russian Federation
ster’s Degree in Digital, Microwave and Optical Communication Systems (2016), 2nd Class Engineer
A. K. Skvortzov
PJSC "Inteltech"
Russian Federation
Engineer in Multichannel Telecommunication Systems (2010, Military Academy of Communications (Saint-Petersburg)), 2nd Class Engineer
Russian Federation
Engineer in Multichannel Telecommunication Systems (2010, Military Academy of Communications (Saint-Petersburg)), 2nd Class Engineer
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Review
For citations:
Kaplun D.I., Gulvanskiy V.V., Kanatov I.I., Klionskiy D.M., Lapizkiy V.F., Bobrovskiy V.I., Frolov K.V., Skvortzov A.K. Development and Study of Demodulation Techniques for Frequency Manipulated Signals. Journal of the Russian Universities. Radioelectronics. 2017;(2):11-16. (In Russ.)
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