Title :
Sequence detection and equalization for pulse-position modulation
Author_Institution :
Sch. of Electr. & Comput. Eng., Georgia Inst. of Technol., Atlanta, GA, USA
Abstract :
We propose several strategies for detecting digital pulse-position modulation (PPM) in the presence of intersymbol interference and additive white Gaussian noise. We develop an equivalent vector channel by viewing PPM as a binary block code, and use this vector channel to derive the maximum likelihood (ML) sequence detector. We also propose three sub-optimal block-by-block detectors, all of which use block decision-feedback equalization (DFE) to mitigate inter-block interference, but differ in how they mitigate intra-block interference: the ML-BDFE accounts for it in an optimal way, the comparator-BDFE uses linear equalization, and the correcting-scalar-DFE uses DFE. We illustrate low-complexity implementations of these equalizers, and compare their performance to the ML detector using Monte-Carlo simulations
Keywords :
Gaussian noise; Viterbi detection; block codes; channel coding; decision feedback equalisers; estimation theory; intersymbol interference; maximum likelihood detection; modulation coding; pulse position modulation; white noise; Monte-Carlo simulations; additive white Gaussian noise; binary block code; block decision-feedback equalization; digital pulse-position modulation; equalization; equivalent vector channel; inter-block interference; intersymbol interference; linear equalization; maximum likelihood sequence detector; sequence detection; sub-optimal block-by-block detectors; Additive white noise; Bandwidth; Block codes; Decision feedback equalizers; Detectors; Digital modulation; Intersymbol interference; MIMO; Optical fiber communication; Pulse modulation;
Conference_Titel :
Communications, 1994. ICC '94, SUPERCOMM/ICC '94, Conference Record, 'Serving Humanity Through Communications.' IEEE International Conference on
Conference_Location :
New Orleans, LA
Print_ISBN :
0-7803-1825-0
DOI :
10.1109/ICC.1994.368768
