Title :
Bandwidth expansion for robust, low-complexity communication over fading dispersive channels
Author :
Baas, Nicholas J. ; Taylor, Desmond P.
Author_Institution :
Dept. of Electr. & Electron. Eng., Canterbury Univ., Christchurch, New Zealand
fDate :
10/1/2001 12:00:00 AM
Abstract :
In this paper, we derive pulses that yield Nyquist or near Nyquist properties when convolved with the initial terms of the series model of a slow fading dispersive channel. For the f-power series these are the so called powers of Nyquist pulses. For a Karhunen-Loeve series, model pulses are found that maximize the ratio of the mean peak-sample energy to mean residual intersymbol interference energy for a given bandwidth expansion factor. Under certain conditions, the approach significantly lessens the need for, or complexity of, equalization. Other benefits attributable to the use of the derived pulses, including those related to timing recovery, are discussed
Keywords :
Karhunen-Loeve transforms; computational complexity; dispersive channels; fading channels; intersymbol interference; maximum likelihood detection; pulse shaping; radio networks; synchronisation; Karhunen-Loeve series; Nyquist properties; Nyquist pulses; bandwidth expansion; bandwidth expansion factor; f-power series; fading dispersive channels; mean peak-sample energy; mean residual intersymbol interference energy; near Nyquist properties; pulses; robust low-complexity communication; series model; timing recovery; Bandwidth; Bit error rate; Dispersion; Fading; Filters; Frequency; Intersymbol interference; Pulse shaping methods; Robustness; Timing;
Journal_Title :
Communications, IEEE Transactions on
