Frequency-Domain Partial-Response Signals for Parallel Data Transmission

Linearly independent (rather than orthogonal) superpositions of harmonically related sine and cosine pulses of duration T form the basis of partial-response signals for parallel data transmission through K overlapping channels. The channels are equally spaced by b=1/T , each one carrying a signaling...

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Bibliographic Details
Published in:I.R.E. transactions on communications systems 1969-10, Vol.17 (5), p.536-543
Main Authors: Schmid, P., Dudley, H., Skinner, S.
Format: Article
Language:English
Subjects:
Communications technology
Data communication
Decoding
Delay effects
Frequency
Interchannel interference
Intersymbol interference
Noise level
Time domain analysis
Transmitters
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Summary:Linearly independent (rather than orthogonal) superpositions of harmonically related sine and cosine pulses of duration T form the basis of partial-response signals for parallel data transmission through K overlapping channels. The channels are equally spaced by b=1/T , each one carrying a signaling rate 2b . With a large number of channels, such systems very closely approach the Nyquist rate. Duality relations are shown to exist between the frequencydomain partial-response (FDPR) signals which will be described and the time-domain partial-response (TDPR)-signals which were defined by Kretzmer. FDPR signals are characterized by: 1) a specific coherent envelope with a gradual roll-off, 2) precisely prescribed amounts of interchannel interference between adjacent channels, and 3) more than two received levels with binary input data, which requires transmitter precoding or receiver decoding. Three FDPR signal classes are defined, and system implementation and performance are discussed with respect to a system utilizing time-limited orthogonal signals. Band occupancies and Gaussian noise performance are given, and sensitivities to various receiver impairments are investigated by computer simulation.
ISSN:0018-9332
0096-2244
2162-2175
DOI:10.1109/TCOM.1969.1090134