Abstract
In this paper, we present a novel cooperative scheme of joint optimal resource allocation, such that the overall performance of the coexisting radar-communications (CRC) system can be improved. In our proposed scheme, target detection and multiuser communication are performed by radar and communication subsystems at the same time, as well as a control center, which is responsible for joint resource management. We aim to minimize the ISLR for target detection and maximize the sum-rate for communications simultaneously by jointly optimizing the band assignment and transmit power allocation. Since the resulting optimization problem involving two performance metrics and a binary constraint is a multiobjective nonconvex problem, a two-tier iterative decomposition (TT-ID) approach is devised to obtain the globally optimal solution. However, compared with the conventional radar signals, the autocorrelation function of the devised radar signal may still have relatively high sidelobes. In particular, when the data transmission becomes the primary purpose of the CRC system, the sidelobe performance gets worse. As a consequence, some weak targets are most likely overshadowed by the adjacent strong targets through the matched filtering at the radar receiver. To address this, a spectral estimation algorithm based on the Bayes Cauchy–Gaussian (Bayes–CG) model is employed to further reduce the range sidelobes of the matched filter output at the radar receiver according to the prior distribution of the desired autocorrelation. Finally, several numerical results are provided to show the merits of the proposed method.
Highlights
Owing to the rapid growth of electronic devices, the electromagnetic frequency spectrum is increasingly congested
The design of a coexisting radarcommunications (CRC) system is becoming a key mechanism to cope with this challenge, which has been widely used in several scenarios, such as the spectral coexistence of airborne early warning radar systems and time division duplexing long term evolution (TDD-LTE)
The resulting radar waveform is synthesized by power spectrum density (PSD) fitting in [12], and quadrature amplitude modulation (QAM) signals are used for data delivery
Summary
Owing to the rapid growth of electronic devices, the electromagnetic frequency spectrum is increasingly congested. It is shown that RFI significantly deteriorates the performance for radar and communication applications. The design of a coexisting radarcommunications (CRC) system is becoming a key mechanism to cope with this challenge, which has been widely used in several scenarios, such as the spectral coexistence of airborne early warning radar systems and time division duplexing long term evolution (TDD-LTE). It is shown that the CRC techniques can enable radar and communication systems to share the same bandwidth by mitigating mutual interference through some common protocols and strategies. A straightforward time-division method uses a switch to allocate different time slots to the radar and communication functions, which can be found in autonomous vehicle applications [5]. The study in [9] investigates the frequency division-based technique in radar-communication spectral coexistence for the first time, where a spectral null is added to the ultra-wide band (UWD)
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