Title :
Linear prediction of bandlimited processes with flat spectral densities
Author :
Lyman, Raphael J. ; Edmonson, William W.
Author_Institution :
Dept. of Electr. & Comput. Eng., New Mexico State Univ., Las Cruces, NM, USA
fDate :
7/1/2001 12:00:00 AM
Abstract :
Lyman et al. (2000) developed some important properties of a continuous-time linear predictor applied to a bandlimited random process, and discussed how such a prediction could be applied to the problem of mobile radio fading. In this paper, we solve explicitly for the optimal predictor, in the mean-square sense, when the process spectral density is not within the band limits and the predictor impulse response is energy constrained. As basis functions, we use time-shifted versions of the prolate spheroidal wave functions, leading to a simple algebraic optimization problem that is solved using a Lagrange multiplier. We show how to use the solution to compute the minimum mean squared prediction error under the energy constraint. Then, we discuss the case of a bandlimited process embedded in white noise, showing how to determine if a certain mean squared prediction error can be attained
Keywords :
bandlimited communication; fading channels; land mobile radio; least mean squares methods; optimisation; prediction theory; transient response; white noise; Lagrange multiplier; algebraic optimization problem; bandlimited process; bandlimited processes; bandlimited random process; basis functions; continuous-time linear predictor; energy constraint; flat spectral densities; linear prediction; mean squared prediction error; minimum mean squared prediction error; mobile radio fading; optimal predictor; predictor impulse response; process spectral density; prolate spheroidal wave functions; white noise; Concrete; Equations; Fading; Lagrangian functions; Land mobile radio; Predictive models; Random processes; Spectral shape; Wave functions; White noise;
Journal_Title :
Signal Processing, IEEE Transactions on
