针对浅海水声通信的极化码构造与应用研究

doi:10.19665/j.issn1001-2400.20230505

Abstract

Abstract:

To realize high speed and high-reliability communication in shallow water environments,the performance of polar code encoding and decoding technology in shallow water acoustic communication is studied.The Monte Carlo algorithm construction is used to complete the construction of polar codes on the time-invariant,quasi-stationary,and time-variant channel models established based on the ray acoustic theory,and the complexity and performance are compared with those of the channel polarization and channel degradation construction algorithms and the base-symmetric extended polarization weight construction algorithm.The constructed polar code is adopted as the channel coding scheme for the underwater acoustic communication system based on Orthogonal Frequency Division Multiplexing and the decoding scheme uses a Cyclic Redundancy Check-Aided Successive Cancellation List decoding algorithm.The performance of polar codes on these three channels is determined by simulation in comparison with the performance of Low-Density Parity Check codes with the same code length and code rate.Experimental results show that in these three channels and the range of the signal-to-noise ratio of interest,polar codes have a gain of about 0.5 dB ~ 1.2 dB relative to Low-Density Parity Check codes.Simulation comparison results of the three channels show that polar codes based on channel construction coding have better gain effects in harsh channel environments compared to Low-Density Parity Check codes,and that polar codes have a lower encoding and decoding complexity,which proves the competitiveness and broad application prospect of the polar code in energy and resource-limited shallow sea acoustic communication.

Key words: underwater acoustic communication, OFDM, polar codes, Monte Carlo construction

CLC Number:

TN911.22

XING Lijuan, LI Zhuo, HUANG Yanbiao. Research on the construction and application of polar codes for shallow water acoustic communication[J].Journal of Xidian University, 2024, 51(2): 116-125.

Figures/Tables 12

References 20

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声线序号	1	2	3	4	5
相对幅度	1	0.705 8	0.350 8	0.173 5	0.085 0
归一化幅度	0.780 0	0.548 0	0.272 4	0.134 7	0.066 3
相对时延/ms	0	2.5	10.0	22.4	39.6
符号周期	0	1	4	9	16

		R=0.375	R=0.5	R=0.625
时不变水声信道	极化码	3.5	4.0	5.2
	LDPC码	2.8	3.4	4.7
时变水声信道	极化码	7.0	7.6	8.8
	LDPC码	6.2	7.1	8.3
准静止水声信道	极化码	25.0	25.2	26.2
	LDPC码	24.0	24.2	25.0

Research on the construction and application of polar codes for shallow water acoustic communication

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