Abstract
Timing acquisition is critical to enabling the potential of ultra-wideband (UWB) radios in high-speed, short-range indoor wireless networking. An effective timing acquisition method should not only operate at a low sampling rate to reduce implementation complexity and synchronization time, but also be able to collect sufficient signal energy in order to operate in a reasonable transmit SNR regime. Energy capture for time-hopping impulse-radio transmissions in dense multipath is particularly challenging during the synchronization phase, in the absence of reliable channel and timing information. In this paper, we develop an efficient sampling strategy for correlation-based receivers to accomplish adequate energy capture at a low cost, using a noisy correlation template constructed directly from the received waveform. Merging our sampling operation based on noisy template with low-complexity timing acquisition schemes, we derive enhanced cyclostationarity-based blind synchronizers, as well as data-aided maximum likelihood timing offset estimators, all operating at a low frame rate. Both analysis and simulations confirm evident improvement in timing performance when using our noisy template, which makes our low-complexity timing acquisition algorithms attractive for practical UWB systems operating in dense multipath.
Highlights
Ultra-wideband (UWB) communications have raised increasing interest in commercial use, with the release of the UWB spectral masks by the US Federal Communications Commission (FCC) in 2002 [1]
The frame-rate blind estimators in Propositions 1 and 2 resemble the conventional CS in [12, 13], the use of noisy templates leads to quite distinct properties for timing acquisition under dense multipath
Capitalizing on judiciously designed noisy templates, we present in this paper several low-complexity, highperformance timing acquisition algorithms for UWB TH transmissions in dense-multipath environments
Summary
Ultra-wideband (UWB) communications have raised increasing interest in commercial use, with the release of the UWB spectral masks by the US Federal Communications Commission (FCC) in 2002 [1]. In a carrierless UWB impulse radio [2], every symbol is repeatedly transmitted at a low duty cycle over a large number of frames with one pulse per frame, in order to gather adequate symbol energy while maintaining low power density. Such a transmission structure entails a twofold TOE task [4]: one is the coarse frame-level acquisition to identify when the first frame in each symbol starts, and the other is the fine pulse-level tracking to find where a pulse is located within a frame. Conventional synchronization based on peak-picking the correlation output between the received signal and the transmit waveform template has prohibitive complexity due to the exhaustive search over
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