Abstract
Impulse radio-based ultra-wideband (UWB) communication systems allow multiple users to access channels simultaneously by assigning unique time-hopping codes to individual users, while each user's information stream is modulated by pulse-position modulation (PPM). However, transmitted signals undergo fading from a number of propagation paths in a dense multipath environment and meanwhile suffer from multiuser interference (MUI). Although RAKE receiver can be employed to maximally exploit path diversity, it is a single-user receiver. Multiuser receiver can significantly improve detection performance. Each of these receivers requires channel parameters. Existing maximum likelihood channel estimators treat MUI as Gaussian noise. In this paper, we derive a blind subspace channel estimator first and then design linear receivers. Following a channel input/output model that transforms a PPM signal into a sum of seemingly pulse-amplitude modulated signals, a structure similar to a code-division multiple-access (CDMA) system is observed. Code matrices for each user are identified. After considering unique statistical properties of new inputs such as mean and covariance, the model is further transformed to ensure that all signature waveforms lie in the signal subspace and are orthogonal to the noise subspace. Consequently, a subspace technique is applicable to estimate each channel. Then minimum mean square error receivers of two different versions are designed, suitable for both uplink and downlink. Asymptotic performance of both the channel estimator and receivers is studied. Closed-form bit error rate is also derived.
Highlights
Research in impulse radio (IR) ultra-wideband (UWB) systems has lasted for several decades whose interest remains growing
Code matrices can be clearly defined for each user from its unique TH sequence, like code matrices constructed from spreading codes in a multirate code-division multiple-access (CDMA) system [14]
We focus on the direct matrix inversion (DMI)-minimum mean square error (MMSE) receiver first
Summary
Research in impulse radio (IR) ultra-wideband (UWB) systems has lasted for several decades whose interest remains growing. We first focus on multiple access (MA) channel estimation based on up to the second-order statistics (SOS) of the received signal in order to construct linear receivers Both first-order statistics and SOS can be estimated from data with low complexity and fast convergence. Code matrices can be clearly defined for each user from its unique TH sequence, like code matrices constructed from spreading codes in a multirate CDMA system [14] They consist of only zeros and ones, indicating existence of path contributions to the received signal from a multipath channel. Signal-to-interference-plusnoise ratio (SINR) of each receiver is studied jointly with channel estimation Those results can be used to predict detection performance for given operational conditions.
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