Title :
Application of convolutionally coded DPSK in meteor-burst communication systems
Author :
Xiong, Fuqin ; Saoud, Maissah
Author_Institution :
Dept. of Electr. Eng., Cleveland State Univ., OH, USA
Abstract :
Convolutionally coded DPSK MBC system is analyzed based on the time-varying SNR model and the statistical nature of the burst duration and the decaying time constant. The performance is evaluated in terms of the average bit error rate, the throughput, the average waiting time, and the system complexity. The average bit error rate is stressed in this paper, whereas only maximum acceptable BER is used as a parameter in earlier literature. The results obtained by this method are more accurate than that by the classical methods. The new results are about 1 dB more optimistic in terms of minimum SNR. The performance of the CC-DPSK is compared with that of a Reed-Solomon coded-DPSK. It shows that for similar performance the CC-DPSK has a much smaller system complexity and for similar complexity the soft-decision decoded CC-DPSK has a much better performance
Keywords :
coding errors; convolutional codes; decoding; differential phase shift keying; error statistics; meteor burst communication; modulation coding; DPSK MBC system; Reed-Solomon coded-DPSK; average bit error rate; average waiting time; burst duration statistics; convolutionally coded DPSK; decaying time constant; meteor-burst communication systems; minimum SNR; performance; soft-decision decoded CC-DPSK; system complexity; throughput; time-varying SNR model; Binary phase shift keying; Bit error rate; Block codes; Circuits; Convolutional codes; Decoding; Differential quadrature phase shift keying; Error probability; Reed-Solomon codes; Throughput;
Conference_Titel :
Military Communications Conference, 1994. MILCOM '94. Conference Record, 1994 IEEE
Conference_Location :
Fort Monmouth, NJ
Print_ISBN :
0-7803-1828-5
DOI :
10.1109/MILCOM.1994.473859
