Title :
Differential pulse-position modulation for power-efficient optical communication
Author :
Shiu, Da-shan ; Kahn, Joseph M.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., California Univ., Berkeley, CA, USA
fDate :
8/1/1999 12:00:00 AM
Abstract :
We examine the use of differential pulse-position modulation (DPPM) for optical communication systems using intensity modulation with direct detection in the presence of additive white Gaussian noise. We present expressions for the error probability and power spectral density of DPPM. We show that for a given bandwidth, DPPM requires significantly less average power than pulse position modulation (PPM). We also examine the performance of DPPM in the presence of multipath intersymbol interference (ISI). We find that the ISI penalties incurred by PPM and DPPM exhibit very similar dependencies upon the channel RMS delay spread. We discuss the use of chip-rate and multichip-rate equalization to combat ISI. Finally, we describe potential problems caused by the nonuniform bit-rate characteristic of DPPM, and we propose several solutions
Keywords :
AWGN; decision feedback equalisers; delays; error statistics; intensity modulation; intersymbol interference; maximum likelihood detection; multipath channels; optical communication; optical modulation; optical signal detection; pulse position modulation; spectral analysis; AWGN; DFE; DPPM; ISI; PPM; additive white Gaussian noise; bandwidth; channel RMS delay spread; chip-rate equalization; differential pulse-position modulation; direct detection; error probability; intensity modulation; maximum likelihood sequence detection; multichip-rate equalization; multipath intersymbol interference; nonuniform bit-rate characteristic; performance; power spectral density; power-efficient optical communication; pulse position modulation; wireless indoor communication; Additive white noise; Bandwidth; Error probability; Intensity modulation; Intersymbol interference; Optical fiber communication; Optical modulation; Optical noise; Optical pulses; Pulse modulation;
Journal_Title :
Communications, IEEE Transactions on
