Abstract :
Few ultrawide-band (UWB) models directly fit original baseband UWB data to simultaneously account for their correlation structure, non-Gaussianity, and nonstationarity. The difficulty arises from the fact that no relevant result is available, even in multivariate statistical analysis. It also arises from the attempt to pursue the details of the mechanism that is imagined to be responsible for the generation of UWB data. The consequence is the modeling complexity, which makes it difficult to handle the received signal correlation on the basis of a single realization. Accordingly, various partial characterization is used in the literature instead by virtue of second-order statistics (such as power delay profile), nonparametric characteristics (such as zero-crossing rate), or their combination. In this paper, we take a different philosophy, which believes that the information in the received UWB data itself, as long as fully exploited, plus some simple physical intuition should suffice for the model identification and its parameter estimation. A received UWB signal is decomposed into three factor processes and each is parsimoniously parameterized. The application of the new model to data regeneration and receiver design is illustrated by using the real UWB data acquired by Intel and the TimeDomain Corporation.
Keywords :
computational complexity; correlation methods; parameter estimation; statistical analysis; ultra wideband communication; baseband UWB data; multivariate statistical analysis; parameter estimation; parsimonious correlated nonstationary model; partial characterization; received signal correlation; second-order statistics; ultrawide-band model; Baseband; Delay; Electromagnetic scattering; Fluctuations; Indoor environments; Parameter estimation; Random variables; Statistical analysis; Statistical distributions; Statistics; Correlated baseband ultrawide-band (UWB)-signal models; generation of correlated non-Gaussian UWB data; modeling UWB signals;
