Optimal Incoherent Reception Noise Immunity of Binary Signals with Differential Phase Manipulation in the Presence of Several Harmonic Interferences

This article proposes the calculation of the probabilities of incoherent reception of signals with binary relative phase manipulation (OFM–2) in the presence of several harmonic interference. Examples of calculating the error probability per bit of receiving signals from OFM – 2 according to the presented method in the presence of several harmonic interference are shown. The obtained graphs depend on the magnitude of the signal at different values of interference and the same magnitude of the frequency shift, as well as on the frequency shift of interference at different levels of signals and interference. The results of the study using this technique allow us to calculate with high accuracy and reliable forecasting the reliability of transmitted information in radio communication channels under the influence of several harmonic interference during processing on two clock cycles. And also to predict the maximum damage to the process of transmitting information in a radio communication channel under various conditions: the coincidence of interference frequencies with the signal frequency, the offset of interference frequencies relative to the signal frequency and the spread of interference frequencies with the signal frequency.

1. Pitrin A.V., Popov A.S., Vorona M.S., Kovalsky A.A. The Method of Calculating the Noise Immunity of Incoherent Reception of Signals with Binary Relative Phase Manipulation (OFM−2) with Harmonic Interference. Nonlinear World. 2023;21(1):5−13. EDN:ATBNHF

2. Borisov V.I., Zinchuk V.M. Ecm-Resistance of Radio Communications Systems. Probabilistic-Temporal Approach. Mosсow: RadioSoft Publ.; 2008. 260 p. EDN:CATZHM

3. Kulikov G.V., Zung N.V., Tien D.C. Noise immunity of an autocorrelation signal demodulator with differential phase manipulation in the presence of Rayleigh fading and harmonic interference. Russian Technological Journal. 2020;8(3):48−58. DOI:10.32362/2500-316X-2020-8-3-48-58. EDN:NVQDYZ

4. Okunev Yu.B. Digital transmission of information by phase-manipulated signals. Mosсow: Sovetskoe radio Publ.; 1991. 296 p.

5. Fink L.M. Theory of transmission of discrete messages. Mosсow: Sovetskoe radio Publ.; 1970. 728 p.

6. Zvonarev V.V., Popov A.S., Pitrin A.V. Methodology for calculating the probabilities of bit errors of receiving radio signals with QPSK modulation with several harmonic interference. Radioengineering. 2022;86(8):84−95. DOI:10.18127/j00338486-202208-09. EDN:ETXHBQ

7. Zvonarev V.V., Pimenov V.F., Popov A.S. Methodology for calculating probabilities of symbolic and bit errors for QPSK signals in the presence of harmonic interference with frequency shift. Proceedings of the Mozhaisky Military Space Academy. 2021;677:50−61. EDN:GDAOEP

8. Zvonarev V.V., Popov A.S. Potential noise immunity of coherent reception of a four–position phase-manipulated radio signal in the presence of coherent harmonic interference. Information and Control Systems. 2021;1:45−54. DOI:10.31799/1684-8853-2021-1-45-54. EDN:IQCUMU

9. Prokis J. Digital communication. Translated from English. Mosсow: Radio i sviaz Publ.; 2000. 800 p.

10. Hvorostenko N.P. Statistical theory of demodulation of discrete signals. Mosсow: Sviaz Publ.; 1968. 336 p.

11. Brodsky M.S., Zvonarev V.V., Popov A.S. A method for constructing a probabilistic space on a set of joint events for calculating the probabilities of bit errors of receiving radio signals with QPSK modulation in the presence of interference. Proceedings of the Mozhaisky Military Space Academy. 2021;678:43−50. EDN:GNPKQZ

12. Zvonarev V.V., Karabelnikov I.F., Popov A.S. Method of Calculating Influence of Frequency Scanning Interference on Reliability of Signal Reception with QPSK Modulation. Trudy MAI. 2022;124:13. DOI:10.34759/trd-2022-124-13. EDN:AHUDUS