Your search keyword '"signal-dependent interference"' showing total 4 results

1. MIMO Radar Waveform Optimization in Clutter Under General Power Constraints

Author

Heng Liu, Zhongshan Zhang, Shuai Wang, Yiting Du, and Xin Zhao

Subjects

General Computer Science, Computer science, MIMO, General Engineering, waveform design, Power (physics), Constraint (information theory), Noise, Matrix (mathematics), unitary matrix approximation (UMA), Colors of noise, successive convex approximation (SCA), Clutter, Waveform, MIMO radar system, General Materials Science, lcsh:Electrical engineering. Electronics. Nuclear engineering, signal-dependent interference, general power constraints, lcsh:TK1-9971, Algorithm

Abstract

In this paper, we investigate a novel framework on the waveform optimization for multiple-input multiple-output (MIMO) radar systems under assumptions of statistical information of scattering matrices and colored noise. Different from most of traditional designs under total power constraint, in our framework, a general power constraint named as multiple weighted power constraints is provided, which includes total power constraint, per-antenna power constraints as its special cases. In the framework, the transmit and receive correlations of parameter matrix to estimate and the spatial and time correlations of noise matrix are all taken into account. Moreover, the signal-dependent interference is also taken into account, which can be considered as a self-interference noise. Based on the available statistics of scattering matrices and colored noise, two kinds of estimation schemes are proposed in this paper, which can realize different trade-offs between complexity and performance. Finally, some numerical results are given to demonstrate the performance advantages of the proposed radar waveform designs.

Published

2020

2. Characterizations of PAPR-Constrained Radar Waveforms for Optimal Target Detection.

Author

Sen, Satyabrata

Abstract

We propose to design a peak-to-average power ratio (PAPR) constrained transmit waveform that achieves the optimal performance (following the Neyman-Pearson lemma) in detecting a target in the presence of signal-dependent interference. The direct time-domain approach allows straightforward characterizations of the correlation and PAPR properties of the designed signals, which are critically important to analyze the system performance in the presence of multiple targets and to assess the transmitter power-utilization, respectively. Therefore, instead of designing a transmit signal only for the optimal detection performance, we solve a biobjective Pareto-optimization problem, subjecting to the PAPR and total energy constraints, in order to simultaneously optimize the detection and cross-correlation performances. With extensive numerical examples, we demonstrate that PAPR-constrained signals produce nearly optimum detection performance even with a strict PAPR requirement, and also highlight the conflicting behavior of the detection and correlation performances. [ABSTRACT FROM PUBLISHER]

Published

2014

3. Hidden Convexity in Robust Waveform and Receive Filter Bank Optimization under Range Unambiguous Clutter

Author

Augusto Aubry, Guolong Cui, Xiaolin Du, Antonio De Maio, Du, X., Aubry, A., De Maio, A., and Cui, G.

Subjects

Optimization problem, Computer science, 02 engineering and technology, range unambiguous clutter, Signal, Convexity, law.invention, symbols.namesake, law, Robust design, 0202 electrical engineering, electronic engineering, information engineering, Waveform, Electrical and Electronic Engineering, Radar, signal-dependent interference, Computer Science::Information Theory, Applied Mathematics, 020206 networking & telecommunications, Filter bank, waveform design, Signal Processing, symbols, Clutter, filter bank optimization, Doppler effect, Algorithm, Energy (signal processing)

Abstract

This letter deals with the robust joint design of radar transmit waveform and receive filter bank in a background of range unambiguous signal-dependent clutter. Assuming an unknown Doppler shift for the target, the worst-case Signal-to-Interference-plus-Noise-Ratio (SINR) at the output of the receive filter bank is considered as the figure of merit. The transceiver design is pursued considering a max-min optimization problem with some constraints on the transmit energy, similarity, and signal dynamic range. Hidden convexity is shown and a procedure to derive optimal waveform and filters is given. Simulation results highlight the effectiveness of the devised method.

Published

2020

4. Robust Transmit Code and Receive Filter Design for Extended Targets in Clutter

Author

M. H. Bastani, Seyyed Mohammad Karbasi, Augusto Aubry, Antonio De Maio, Karbasi, Seyyed Mohammad, Aubry, Augusto, DE MAIO, Antonio, and Bastani, Mohammad Hasan

Subjects

Computer science, Transmitter, Sampling (statistics), Interference (wave propagation), law.invention, PAR constraint, Filter design, Signal-to-noise ratio, law, Robustness (computer science), Control theory, robust design, Signal Processing, Clutter, Figure of merit, Radar, signal-dependent interference, Electrical and Electronic Engineering, semi-definite programming, Impulse response, Extended target model

Abstract

We propose a novel robust design method to jointly optimize the radar transmit code and receive filter, exploiting the Signal-to-Interference plus Noise Ratio (SINR) at the receiver end as design figure of merit. We confer robustness to our method against uncertainties on the target impulse response (TIR) using a worst-case optimization approach based on two different uncertainty sets. The former is composed of a finite collection of TIRs, obtained by sampling the actual TIR at some aspect angles; the latter is a spherical uncertainty set. We further enforce a peak-to-average power ratio (PAR) constraint to the transmit code, which is very important for radar applications where the transmitter operates close to saturation. The design problem is tackled using a sequential optimization procedure alternating between two semi-definite programming (SDP) problems, followed by randomization steps. Our numerical results highlight the robustness and applicability of the proposed method in different scenarios.

Published

2015