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Siji Quan

Bio: Siji Quan is an academic researcher. The author has contributed to research in topics: Bistatic radar & Communications system. The author has an hindex of 1, co-authored 1 publications receiving 36 citations.

Papers
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Proceedings ArticleDOI
01 Nov 2014
TL;DR: Main approaches including time-sharing, sub-beams and signal-sharing are shown, and the most promising signal- Sharing approach is detailed discussed with its three typical realizations.
Abstract: Radar-communication integration combines radar system and communication system together These two systems have similar structures, and communication system can take advantage of radar's excellent hardware features if integrated This technique is still under study and may take decades to achieve practical application The motivation of such integration is presented in the beginning of this paper Main approaches including time-sharing, sub-beams and signal-sharing are shown, and the most promising signal-sharing approach is detailed discussed with its three typical realizations Characteristics, including advantages and disadvantages of these approaches are also analyzed Three typical integration application scenarios are described in the end of this paper

53 citations


Cited by
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Journal ArticleDOI
TL;DR: This paper explores the state-of-the-art of JRC in the levels of coexistence, cooperation, co-design and collaboration, and reviews the entire trends that drive the development of radar sensing and wireless communication using JRC.
Abstract: Joint radar and communication (JRC) technology has become important for civil and military applications for decades. This paper introduces the concepts, characteristics and advantages of JRC technology, presenting the typical applications that have benefited from JRC technology currently and in the future. This paper explores the state-of-the-art of JRC in the levels of coexistence, cooperation, co-design and collaboration. Compared to previous surveys, this paper reviews the entire trends that drive the development of radar sensing and wireless communication using JRC. Specifically, we explore an open research issue on radar and communication operating with mutual benefits based on collaboration, which represents the fourth stage of JRC evolution. This paper provides useful perspectives for future researches of JRC technology.

167 citations

Journal ArticleDOI
01 Jan 2022
TL;DR: In this paper , the authors provide a comprehensive survey on the fundamental limits of integrated sensing and communication (ISAC), and summarize the major performance metrics and bounds used in sensing, communications and ISAC, respectively.
Abstract: The integrated sensing and communication (ISAC), in which the sensing and communication share the same frequency band and hardware, has emerged as a key technology in future wireless systems due to two main reasons. First, many important application scenarios in fifth generation (5G) and beyond, such as autonomous vehicles, Wi-Fi sensing and extended reality, requires both high-performance sensing and wireless communications. Second, with millimeter wave and massive multiple-input multiple-output (MIMO) technologies widely employed in 5G and beyond, the future communication signals tend to have high-resolution in both time and angular domain, opening up the possibility for ISAC. As such, ISAC has attracted tremendous research interest and attentions in both academia and industry. Early works on ISAC have been focused on the design, analysis and optimization of practical ISAC technologies for various ISAC systems. While this line of works are necessary, it is equally important to study the fundamental limits of ISAC in order to understand the gap between the current state-of-the-art technologies and the performance limits, and provide useful insights and guidance for the development of better ISAC technologies that can approach the performance limits. In this paper, we aim to provide a comprehensive survey for the current research progress on the fundamental limits of ISAC. Particularly, we first propose a systematic classification method for both traditional radio sensing (such as radar sensing and wireless localization) and ISAC so that they can be naturally incorporated into a unified framework. Then we summarize the major performance metrics and bounds used in sensing, communications and ISAC, respectively. After that, we present the current research progresses on fundamental limits of each class of the traditional sensing and ISAC systems. Finally, the open problems and future research directions are discussed.

68 citations

Journal ArticleDOI
TL;DR: Results demonstrate that the proposed FrFT waveform presents performance close to a LFM pulse in terms of probability of detection and probability of false alarm, in exchange for slightly worse range and Doppler resolution, to maintain comparable communication performance with respect to the OFDM waveform.

43 citations

Journal ArticleDOI
TL;DR: A system architecture for industrial big data (BD) transmission based on radar-communication integration with arbitrary geometrical array is developed and it is shown that the proposed method can achieve excellent estimation performance for its application in radar- communication integration.
Abstract: Various kinds of data are generated from industrial Internet of Things, and these data can be applied for connecting production equipment, identifying and locating items, etc. These data should be forwarded to the decision center for further analyses, especially in wartime. Thus, the channel status information (CSI) for industrial big data transmission has to be acquired. In this article, we develop a system architecture for industrial big data (BD) transmission based on radar-communication integration with arbitrary geometrical array. The traditional channel estimation method, which usually utilizes the regular antenna array to estimate the CSI, cannot be applied to the arbitrary geometrical array. Here, we use the manifold separation technique to transform the complex array configuration into regular array and the downlink channel covariance matrix is estimated by exploiting the frequency calibration technique when the uplink channel covariance matrix is received. The computational complexity for the proposed method and other state-of-the-art methods are analyzed. The simulation results prove that the proposed method can achieve excellent estimation performance for its application in radar-communication integration.

33 citations

Proceedings ArticleDOI
Yu Zhang1, Qingyu Li1, Ling Huang1, Changyong Pan1, Jian Song1 
04 Jun 2017
TL;DR: Simulation results show that the modified waveform holds good bit error rate (BER) performance even when there is strong interference beside the original bandwidth of the radar system, while the waveform without modification can hardly complete the transmission with high BER.
Abstract: The integration of radar and communication has attracted general interest with its advantage of equipment miniaturizing and high efficiency of spectrum, especially in intelligent transportation systems because of the need for transmitting and detecting simultaneously and the lack of room for various devices. Among various integration schemes, the integrated waveform which realizes transmitting and detection at the same time is a real integration with high efficiency and no interference. In this paper, we proposed a modified three-section integrated waveform based on linear frequency modulation and continuous phase modulation (LFM-CPM). Short Time Fourier Transform (STFT) is used for time-frequency analysis and the modification of the mapping codebook of the communication symbols restrains the spectrum of the integrated waveform within the original bandwidth of the radar system. Simulation results show that the modified waveform holds good bit error rate (BER) performance even when there is strong interference beside the original bandwidth of the radar system, while the waveform without modification can hardly complete the transmission with high BER.

27 citations