An Encoding and Decoding Scheme of LDPC Codes Based on Pulse Position Modulation

Che  Shu-Ling; Li  Ping; Wang  Xin-Mei

doi:10.3724/SP.J.1146.2007.00693

Volume 30 Issue 11

Jan. 2011

Turn off MathJax

Article Contents

Article Navigation > Journal of Electronics & Information Technology > 2008 > 30(11): 2630-2633

Che Shu-Ling, Li Ping, Wang Xin-Mei. An Encoding and Decoding Scheme of LDPC Codes Based on Pulse Position Modulation[J]. Journal of Electronics & Information Technology, 2008, 30(11): 2630-2633. doi: 10.3724/SP.J.1146.2007.00693

Citation:

Che Shu-Ling, Li Ping, Wang Xin-Mei. An Encoding and Decoding Scheme of LDPC Codes Based on Pulse Position Modulation[J]. Journal of Electronics & Information Technology, 2008, 30(11): 2630-2633. doi: 10.3724/SP.J.1146.2007.00693

Citation:

PDF( 230 KB)

An Encoding and Decoding Scheme of LDPC Codes Based on Pulse Position Modulation

doi: 10.3724/SP.J.1146.2007.00693

Che Shu-Ling^{① 李坪
,},
Li Ping,
Wang Xin-Mei

Received Date: 2007-05-08
Rev Recd Date: 2007-09-28
Publish Date: 2008-11-19

Abstract

Abstract

In this paper, a low-rate LDPC-PPM scheme is bring forward which can be applied into UWB communication systems. This scheme can provide good performance with low decoding complexity. By changing the mapping style from coded bits to modulated symbols, not only the iterative operations between decoding and demodulation can be avoided, but also Fast Hadamard Transformation (FHT) and the so called A Posteriori Probability FHT (APP-FHT) algorithm can be adopted to further decrease decoding complexity. It can be proved that this scheme is equivalent to low-rate LDPC-Hadamard codes with BPSK modulation. Simulation results show that this scheme can achieve -1.18dB at bit error rate with data length 65536, which is only worse 0.02dB than Turbo-Hadamard codes with BPSK modulation.
- P,
- u

FullText(HTML)

References(1)

References

[1] Komulainen P and Pehkonen K. Performance evaluation ofsuper-orthogonal turbo codes in AWGN and flat Raleighfading channel[J].IEEE J. Select. Areas Commun.1998, 16(2):196-205 [2] Li Ping, Leung W K, and Wu K Y. Low-rateturbo-Hadamard codes[J].IEEE Trans. on Inform. Theory.2003, 49(12):3213-3224 [3] Yue Guosen, Li Ping, and Wang Xiaodong. Low-rategeneralized low-density parity-check codes with Hadamardconstraints. Proc. IEEE Int. Symp. Inform. Theory (ISIT),Australia, 2005: 1377-1381. [4] Yue Guosen, Li Ping, and Wang Xiaodong. Generalizedlow-density parity-check codes based on Hadamardconstraints[J].IEEE Trans. on Inform. Theory.2007, 53(3):1058-1079 [5] Zhang Hao and Gulliver T Aaron. Bi-orthogonal pulseposition modulation for time-hopping multiple access UWBcommunications[J].IEEE Trans. on Wireless Commun.2005,4(3):1154-1162 [6] Wilson Stephen G. Digital Modulation and Coding. Prentice-Hall, Inc., 1996, Section 3.3. [7] Lentmaier L and Ziganggirov K. Iterative decoding ofgeneralized low-density parity-check codes. Proc. IEEE Int.Symp. Inform. Theory (ISIT), Cambridge, 1999: 149. [8] Lentmaier M and Zigangirov K Sh. On generalizedlow-density parity-check codes based on hamming componentcodes[J].IEEE Commun. Lett.1999, 3(8):248-250 [9] Mckay D J C and Neal R M. Near Shannon limit performanceof low-density parity check codes[J].IEE Electron. Lett.1997,33(6):457-458 [10] Li Ping, Leung W K, and Phamdo Nam. Low density paritycheck codes with semi-random parity check matrix[J].IEEElectron. Lett.1999, 35(1):38-39

Relative Articles

Supplements(0)

Cited By

Proportional views