Coded Pilot Assisted Baseband Receiver for High Data Rate Millimeter-Wave Communications

被引:6
|
作者
An, Sining [1 ]
He, Zhongxia Simon [1 ]
Li, Jianguo [2 ]
Bu, Xiangyuan [2 ]
Zirath, Herbert [1 ]
机构
[1] Chalmers Univ Technol, Dept Microtechnol & Nanosci, Microwave Elect Lab, SE-41296 Gothenburg, Sweden
[2] Beijing Inst Technol, Sch Informat Sci & Elect, Beijing 100081, Peoples R China
来源
IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES | 2020年 / 68卷 / 11期
基金
中国国家自然科学基金;
关键词
Receivers; Baseband; Millimeter wave communication; Millimeter wave technology; Synchronization; Demodulation; Baseband receiver; carrier recovery; communication link; millimeter-wave; synchronization; GHZ;
D O I
10.1109/TMTT.2020.2993789
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
A coded pilot assisted high data rate millimeterwave receiver topology is presented in this article. A low data rate and low power pseudorandom noise (pn) coded pilot signal is superimposed at the transmitter, and the receiver can use such pilot for carrier recovery (CR) and/or channel estimation regardless of modulation scheme or communication data rate. The proposed baseband receiver has an analog-digital hybrid structure where a low-cost digital signal processor is used. This structure requires only a low-cost analog-to-digital converter (ADC) with a sampling rate of 40 MSPS. A proof-of-concept communication link at E-band is demonstrated with 18 Gbps 64-quadrature amplitude modulation (QAM) and 24 Gbps 16-QAM.
引用
收藏
页码:4719 / 4727
页数:9
相关论文
共 50 条
  • [41] Photonic Millimeter-Wave System for High-Capacity Wireless Communications
    McKenna, Timothy P.
    Nanzer, Jeffrey A.
    Clark, Thomas R., Jr.
    JOHNS HOPKINS APL TECHNICAL DIGEST, 2015, 33 (01): : 57 - 67
  • [42] Photonic millimeter-wave system for high-capacity wireless communications
    McKenna, Timothy P.
    Nanzer, Jeffrey A.
    Clark, Thomas R.
    Johns Hopkins APL Technical Digest (Applied Physics Laboratory), 2015, 33 (01): : 57 - 67
  • [43] NEW APPROACH TO MILLIMETER-WAVE COMMUNICATIONS.
    Feldman, N.E.
    Dudzinsky, S.J.Jr
    1600,
  • [44] Photonic Signal Generation for Millimeter-Wave Communications
    Nanzer, Jeffrey A.
    Callahan, Patrick T.
    Dennis, Michael L.
    Clark, Thomas R., Jr.
    JOHNS HOPKINS APL TECHNICAL DIGEST, 2012, 30 (04): : 299 - 308
  • [45] Autonomous Relay for Millimeter-Wave Wireless Communications
    Kong, Linghe
    Ye, Linsheng
    Wu, Fan
    Tao, Meixia
    Chen, Guihai
    Vasilakos, Athanasios V.
    IEEE JOURNAL ON SELECTED AREAS IN COMMUNICATIONS, 2017, 35 (09) : 2127 - 2136
  • [46] Millimeter-wave and Terahertz Photonics for Communications and Sensors
    Nagatsuma, Tadao
    Fujita, Masayuki
    Li Yi
    2021 OPTICAL FIBER COMMUNICATIONS CONFERENCE AND EXPOSITION (OFC), 2021,
  • [47] On Analog QAM Demodulation for Millimeter-Wave Communications
    Etemadi, Farzad
    Heydari, Payam
    Jafarkhani, Hamid
    IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS II-EXPRESS BRIEFS, 2019, 66 (03) : 402 - 406
  • [48] Millimeter-Wave Photonics for Communications and Phased Arrays
    Nanzer, Jeffrey A.
    Wichman, Adam
    Klamkin, Jonathan
    Mckenna, Timothy P.
    Clark, Thomas R., Jr.
    FIBER AND INTEGRATED OPTICS, 2015, 34 (03) : 91 - 106
  • [49] Enhancing data rate and energy efficiency of NOMA systems using reconfigurable intelligent surfaces for millimeter-wave communications
    Pham, Xuan Nghia
    Nguyen, Ba Cao
    Thi, Tam Dinh
    Vinh, Nguyen Van
    Minh, Bui Vu
    Kim, Taejoon
    Nguyen, Tan N.
    Le, Anh Vu
    DIGITAL SIGNAL PROCESSING, 2024, 151
  • [50] QoS Aware Robot Trajectory Optimization With IRS-Assisted Millimeter-Wave Communications
    Tatino, Cristian
    Pappas, Nikolaos
    Yuan, Di
    IEEE OPEN JOURNAL OF THE COMMUNICATIONS SOCIETY, 2022, 3 : 1323 - 1336
12345