Joint Transmit Waveform and Receive Filter Design for Dual-Function Radar-Communication Systems

Symeon Chatzinotas,Aakash Arora,Bjorn Ottersten,Christos G Tsinos

doi:10.1109/jstsp.2021.3112295

Abstract

In this paper, the problem of joint transmit waveform and receive filter design for dual-function radar-communication (DFRC) systems is studied. The considered system model involves a multiple antenna base station (BS) of a cellular system serving multiple single antenna users on the downlink. Furthermore, the BS simultaneously introduces sensing capabilities in the form of point-like target detection from the reflected return signals in a signal-dependent interference environment. A novel framework based on constrained optimization problems is proposed for the joint design of the transmit waveform and the radar receive filter such that different constraints related to the power amplifiers and the radar waveform are satisfied. In contrast to the existing approaches in the DFRC systems’ literature, the proposed approach does not require the knowledge of a predetermined radar beampattern in order to optimize the performance of the radar part through its approximation. Instead, a beampattern is generated by maximizing the radar receive signal-to-interference ratio (SINR) thus, enabling a more flexible design. Moreover, the radar receive filter processing and its optimization is considered for the first time on DFRC systems, enabling the effective exploitation of the available degrees of freedom in the radar receive array. Efficient algorithmic solutions with guaranteed convergence are developed for the defined constrained nonconvex optimization problems. The effectiveness of the proposed solutions is verified via numerical results.

Highlights

T HE rise of the 5th Generation (5G) and beyond wireless technologies brings huge demands for high quality wireless communications services, since numerous different devices are expected to be interconnected
The case of joint communications-radar spectrum sharing has recently concentrated great interest in the literature [7]-[9]. The latter is usually implemented via two different approaches: 1) Coexistence of the radar and the communication systems and 2) Dual-function radar-communication (DFRC) system design
3 interfering sources are assumed to be located at spatial angles θ1 = −50o, θ2 = −10o and θ3 = 40o

Summary

Introduction

T HE rise of the 5th Generation (5G) and beyond wireless technologies brings huge demands for high quality wireless communications services, since numerous different devices are expected to be interconnected. Additional frequency spectrum resources are more than necessary to wireless communication systems in order to meet those demands. The case of joint communications-radar spectrum sharing has recently concentrated great interest in the literature [7]-[9]. The latter is usually implemented via two different approaches: 1) Coexistence of the radar and the communication systems and 2) Dual-function radar-communication (DFRC) system design

Methods

Results

Conclusion