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Joint Transmit and Receive Filter Optimization for Sub-Nyquist Delay-Doppler Estimation

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arxiv 1704.07612 v2 pith:WE6FADXU submitted 2017-04-25 cs.IT math.IT

Joint Transmit and Receive Filter Optimization for Sub-Nyquist Delay-Doppler Estimation

classification cs.IT math.IT
keywords estimationreceivetransmitdesignfilteroptimizationtransceiveranalog
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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In this article, a framework is presented for the joint optimization of the analog transmit and receive filter with respect to a parameter estimation problem. At the receiver, conventional signal processing systems restrict the two-sided bandwidth of the analog pre-filter $B$ to the rate of the analog-to-digital converter $f_s$ to comply with the well-known Nyquist-Shannon sampling theorem. In contrast, here we consider a transceiver that by design violates the common paradigm $B\leq f_s$. To this end, at the receiver, we allow for a higher pre-filter bandwidth $B>f_s$ and study the achievable parameter estimation accuracy under a fixed sampling rate when the transmit and receive filter are jointly optimized with respect to the Bayesian Cram\'{e}r-Rao lower bound. For the case of delay-Doppler estimation, we propose to approximate the required Fisher information matrix and solve the transceiver design problem by an alternating optimization algorithm. The presented approach allows us to explore the Pareto-optimal region spanned by transmit and receive filters which are favorable under a weighted mean squared error criterion. We also discuss the computational complexity of the obtained transceiver design by visualizing the resulting ambiguity function. Finally, we verify the performance of the optimized designs by Monte-Carlo simulations of a likelihood-based estimator.

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