Functionally weighted lagrange interpolation of band-limited signals from nonuniform samples
IEEE Transactions on Signal Processing
Design of barycentric interpolators for uniform and nonuniform sampling grids
IEEE Transactions on Signal Processing
X2random fields in space and time
IEEE Transactions on Signal Processing
Joint estimation of time delay and Doppler shift for band-limited signals
IEEE Transactions on Signal Processing
Low-complexity all-digital sample clock dither for OFDM timing recovery
IEEE Transactions on Very Large Scale Integration (VLSI) Systems
Regularized sampling of multiband signals
IEEE Transactions on Signal Processing
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A method to interpolate a bounded bandlimited signal from its own samples with minimum complexity is presented that guarantees an a priori specified accuracy. The method is the result of combining a fast-converging sampling expansion with the Farrow interpolator technique. It provides important complexity reductions in various signal processing applications, from which three cases are studied. For the Farrow interpolator, it assures that the interpolation error will be smaller than a known bound, both in the time and frequency domains. For delay estimation, the method allows one to decouple a given estimation/detection algorithm in two steps. In the first one, a few finite convolutions are carried out in order to compute a set of interpolation coefficients. In the second, the algorithm is executed but with a complexity independent of the length of the temporal observation interval. Besides, it is shown how to introduce this decoupling in the matched filter, MUSIC, and conditional maximum-likelihood delay estimators. Finally, the method is employed to give a simple solution to an important efficiency problem in the simulation of communications systems: the generation of Rayleigh processes