Title :
Coding and equalization for PPM on wireless infrared channels
Author :
Lee, David C. ; Kahn, Joseph M.
Author_Institution :
California Univ., Berkeley, CA, USA
Abstract :
We analyze the performance of trellis-coded pulse-position modulation with block decision-feedback equalization (BDFE) and parallel decision-feedback decoding (PDFD) on indoor, wireless infrared channels. We show that the reduced complexities of BDFE and PDFD as compared to maximum-likelihood sequence detection allow for better codes whose increased coding gain more than compensates for the penalty due to suboptimal detection. We quantify these net gains in performance over a range of dispersive channels, indicating where BDFE and PDFD provide the best performance. Finally, we present Monte Carlo simulation results to verify our analysis
Keywords :
Monte Carlo methods; computational complexity; decision feedback equalisers; decoding; dispersive channels; error statistics; maximum likelihood detection; multipath channels; optical communication; optical modulation; pulse position modulation; trellis coded modulation; Monte Carlo simulation results; PPM; block decision-feedback equalization; channel models; codes; coding gain; computational complexity; dispersive channels; equalization; error probability analysis; indoor wireless infrared channels; maximum-likelihood sequence detection; multipath channels; noise models; parallel decision-feedback decoding; performance analysis; suboptimal detection; trellis-coded pulse-position modulation; wireless IR channels; Bandwidth; Decision feedback equalizers; Infrared detectors; Maximum likelihood decoding; Maximum likelihood detection; Optical noise; Optical receivers; Optical transmitters; Performance gain; Pulse modulation;
Conference_Titel :
Global Telecommunications Conference, 1998. GLOBECOM 1998. The Bridge to Global Integration. IEEE
Conference_Location :
Sydney,NSW
Print_ISBN :
0-7803-4984-9
DOI :
10.1109/GLOCOM.1998.775724
