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    智能传感网络信息处理

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    袁涛

    来源: 日期:2024-03-27点击:

    简介:

    袁涛,博士,深圳大学电子与信息工程学院特聘教授,博士生导师,国家级专家(入选第十一批国家级重大人才工程A类),广东省珠江人才计划青年拔尖人才A类,深圳市海外高层次人才A类(“孔雀计划”A类)。目前主要研究方向包括5G射频前端关键技术及产业化、物联网(IOT)射频技术、5G毫米波大规模天线阵列研究、射频/微波/毫米波电路及系统集成、新型微波器件与制造技术。

    袁涛博士2016年3月起加入深圳大学电子与信息工程学院(原信息工程学院)任教,担任特聘教授及博士生导师。在校期间,袁涛博士组建了深圳大学电子与信息工程学院微波与天线技术研究团队,牵头搭建了深圳市首家毫米波天线测试系统、深圳市首家Sub-6 GHz有源射频多天线测试系统。现实验室微波天线和无源器件测量能力已实现1–40 GHz全覆盖,测量能力正在升级至覆盖110 GHz。目前团队成员共50余人,包括特聘教授1名、助理教授3名,专职研究人员5名,博士及硕士研究生40余名。袁涛教授至今累计培养研究生20余人,其中已毕业7人,在读18人,引进和指导青年教师4名,招收博士后5名。所指导研究生获国家奖学金、鹏城奖学金、学业奖学金、优秀毕业研究生、“优博计划”等荣誉奖项累计50余人次。

    团队于2016年、2017年分别获批“广东省移动智能终端工程技术(联合)研究中心”和“广东省移动终端微波毫米波天线工程技术研究中心”,于2020年参与申请并获批广东省科技厅粤港澳联合实验室——“粤港大数据图像和通信应用联合实验室”(为广东省粤港澳大湾区最具影响力的实验室之一),于2020年承担深大-鹏鼎-康佳“大数据图像和通信应用”产教融合育人平台项目,成立“大数据图像和通信应用产教联合创新中心”。

    袁涛教授作为团队负责人和学术带头人承担多项国家级、省市级科技项目。团队科研经费累计超过2200万元,累计发表SCI/EI收录高水平学术期刊和会议论文百余篇,申请(含授权)中国发明专利20余项,参与制定国家、行业、团体标准10余项。袁涛教授团队与复旦大学、东南大学、新加坡国立大学、香港城市大学、中国信息通信研究院等众多知名企事业单位紧密展开产学研合作,取得了丰硕的学术成果。

    联系方式:

    邮箱:yuantao@szu.edu.cn

    电话: 13524963864/0755-26925473

    地址: 广东省深圳市南山区南海大道3688号深圳大学沧海校区致信楼N305

    研究兴趣:

    5G射频前端关键技术及产业化、物联网射频技术、5G毫米波大规模天线阵列、射频/微波/毫米波电路及系统集成、新型微波器件与制造技术

    主讲课程:

    本科生课程 电磁场与电磁波(1300310001)

    获奖与荣誉:

    • 国家级特聘专家

    • 广东省珠江人才计划青年拔尖人才A类

    • 广东省移动终端微波毫米波天线工程技术研究中心主任

    • 深圳市海外高层次人才A类(“孔雀计划”A类)

    • 深圳市海外高层次人才团队“孔雀团队”(三名核心成员之一)

    • 深圳大学优秀个人

    • 中国通信学会科学技术奖二等奖

    • 第五届全国大学生集成电路创新创业大赛(华南赛区)优秀指导教师

    • 第五届全国大学生集成电路创新创业大赛(全国总决赛)优秀指导教师

    主要学术兼职:

    • 复旦大学访问教授

    • 重庆大学访问教授

    • IEEE会员,IEEE MTT-S、AP-S会员

    • 中国通信学会高级会员

    • 中华人民共和国教育部学位论文评审专家

    • 《IEEE Transactions on Components, Packaging and Manufacturing Technology》审稿人

    • 《Frontiers of Information Technology & Electronic Engineering》审稿人

    • 《电子与信息学报》审稿人

    • 2020年亚太微波会议(APMC2020)技术委员会委员、审稿人

    • 2021年海峡两岸无线科学与技术会议(CSRSWTC2021)大会主席

    • 中国信息通信研究院外聘专家

    • 北京智芯微电子科技有限公司外聘专家

    • 深圳市微波通信技术应用行业协会专家

    • 智能图像处理北京市工程研究中心专家顾问

    科研项目:

    • 国家重点研发计划“国家质量基础的共性技术研究与应用”重点专项项目子课题负责人:多载波射频多天线链路切换技术在Sub-6 GHz频段的研究,2019.12–2021.11,39.75万,在研,所属课题:5G移动终端天线接口阻抗标定与多载波射频多天线链路切换技术(2019YFF0216602),169万

    • 广东省科技厅粤港澳联合实验室——“粤港大数据图像和通信应用联合实验室”,500万,第二合作单位,团队负责人之一,在研

    • 深圳市海外高层次人才创新创业计划团队(孔雀团队)项目,团队三名核心成员之一:城市地下空间结构安全智慧感知关键技术与成套装备研发(KQTD20180412181337494),2019.10–2024.10,3000万(负责课题150万),在研

    • 深圳市科技创新委员会基础研究自由探索项目,新一代高速移动通信多进多出天线关键技术研究(JCYJ20180305124721920),50万,在研

    • 深圳市高层次人才科研启动经费,500万,结题

    • 高水平大学二期建设项目“广东省移动终端微波毫米波天线工程技术研究中心”,担任工程中心主任,150万,在研

    • 深圳大学校长基金,20万,结题

    • 校企产学研横向项目,移动终端射频天线与传输线关键技术研发与创新合作平台建设,项目负责人,300万元,在研

    • 校企产学研横向项目,物联网智能终端天线技术研究,项目负责人,30万元,结题

    • 校企产学研横向项目,基于极小净空及未来5G移动通信射频天线关键技术研究,项目负责人,60万元,结题

    • 校企产学研横向项目,5G终端射频天线关键技术研究,项目负责人,120万元,结题

    • 校企产学研横向项目,极致净空环境下全面屏5G天线方案研究,项目负责人,10万元,结题

    • 校企产学研横向项目,基于多层印制电路的毫米波封装天线研究,项目负责人,10万元,在研

    • 校企产学研横向项目,轻小型GNSS天线合作项目,项目负责人,35万元,在研

    部分代表性论文:

    • T. Yuan, Y. Zheng, L.-W. Li, and M.-S. Leong, “A fully integrated ultra-low power CMOS transmitter module for UWB systems,” Microwave and Optical Technology Letters, vol. 51, no. 10, pp. 2318–2323, Oct. 2009.

    • T. Yuan, G.-D. Lim, Y. Zheng, L.-W. Li, and M.-S. Leong, “An integrated CMOS low-power UWB transmitter,” Microwave and Optical Technology Letters, vol. 51, no. 6, pp. 1431–1436, Jun. 2009.

    • T. Yuan, N. Yuan, and L.-W. Li, “A novel series-fed taper antenna array design,” IEEE Antennas and Wireless Propagation Letters, vol. 7, pp. 362–365, 2008.

    • T. Yuan, N. Yuan, L.-W. Li, and M.-S. Leong, “Design and analysis of phased antenna array with low sidelobe by fast algorithm,” Progress In Electromagnetics Research, vol. 87, pp. 131–147, 2008.

    • T. Yuan, C.-W. Qiu, L.-W. Li, M. S. Leong, and Q. Zhang, “Elliptically shaped ultra-wideband patch antenna with band-notch features,” Microwave and Optical Technology Letters, vol. 50, no. 3, pp. 736–738, Mar 2008.

    • T. Yuan, L.-W. Li, M.-S. Leong, J.-Y. Li, and N. Yuan, “Efficient analysis and design of finite phased arrays of printed dipoles using fast algorithm: Some case studies,” Journal of Electromagnetic Waves and Applications, vol. 21, no. 6, pp. 737–754, 2007.

    • T. Yuan, C.-W. Qiu, L.-W. Li, S. Zouhdl, and M.-S. Leong, “Sensitivity analysis of iterative adjoint technique for microstrip circuits optimization,” Microwave and Optical Technology Letters, vol. 49, no. 3, pp. 607–609, Mar 2007.

    • X. Zhang, Q.-S. Wu, L. Zhu, G.-L. Huang, and T. Yuan, “Resonator-fed wideband and high-gain patch antenna with enhanced selectivity and reduced cross-polarization,” IEEE Access, vol. 7, pp. 49918–49927, 2019.

    • X. Zhang, T.-Y. Tan, Q.-S. Wu, L. Zhu, S. Zhong, and T. Yuan, “Pin-loaded patch antenna fed with a dual-mode SIW resonator for bandwidth enhancement and stable high gain,” IEEE Antennas and Wireless Propagation Letters, vol. 20, no. 2, pp. 279–283, Feb. 2021.

    • X. Zhang, K.-D. Hong, L. Zhu, X.-K. Bi, and T. Yuan, “Wideband differentially fed patch antennas under dual high-order modes for stable high gain,” IEEE Transactions on Antennas and Propagation, vol. 69, no. 1, pp. 508–513, Jul. 2020.

    • G.-L. Huang, S.-G. Zhou, C.-Y.-D. Sim, T.-H. Chio, and T. Yuan, “Lightweight perforated waveguide structure realized by 3-D printing for RF Applications,” IEEE Transactions on Antennas and Propagation, vol. 65, no. 8, pp. 3897–3904, Aug. 2017.

    • G.-L. Huang, S.-G. Zhou, and T. Yuan, “Development of a wideband and high-efficiency waveguide-based compact antenna radiator with binder-jetting technique,” IEEE Transactions on Components, Packaging and Manufacturing Technology, vol. 7, no. 2, pp. 254–260, Feb. 2017.

    • G.-L. Huang, S.-G. Zhou, and T. Yuan, “Design of a compact wideband feed cluster with dual-polarized sum- and difference-patterns implemented via 3-D metal printing,” IEEE Transactions on Industrial Electronics, vol. 65, no. 9, pp. 7353–7362, Sept. 2018.

    • G.-L. Huang, C.-Z. Han, W. Xu, T. Yuan, and X. Zhang, “A compact 16-way high-power combiner implemented via 3-D metal printing technique for advanced radio-frequency electronics system applications,” IEEE Transactions on Industrial Electronics, vol. 66, no. 6, pp. 4767–4776, Jun. 2019.

    • G.-L. Huang, C.-Y.-D. Sim, S. Liang, W. Liao, and T. Yuan, “Low-profile flexible UHF RFID tag design for wristbands applications,” Wireless Communications and Mobile Computing, vol. 2018, Article ID 9482919, pp. 1–13, Jun. 2018.

    • P. Zhang, J. Xu, S. Zhong, H. Feng, L. Huang, T. Yuan, and J. Zhang, “Design of reconfigurable SDR platform for antenna selection aided MIMO communication system,” IEEE Access, vol. 7, pp. 169267–169280, 2019.

    • S. Zhong, H. Feng, P. Zhang, J. Xu, L. Huang, T. Yuan, and Y. Huo, “User oriented transmit antenna selection in massive multi-user MIMO SDR systems,” Sensors, vol. 20, no. 17, 4867, pp. 1–15, Apr. 2020.

    • S. Zhong, H. Feng, P. Zhang, J. Xu, H. Luo, J. Zhang, T. Yuan, and L. Huang, “Deep learning based antenna selection for MIMO SDR system,” Sensors, vol. 20, no. 23, 6987, pp. 1–15, Dec. 2020.

    • Z. Chen, H.-Z. Li, H. Wong, X. Zhang, and T. Yuan, “A circularly-polarized-reconfigurable patch antenna with liquid dielectric,” IEEE Open Journal of Antennas and Propagation, vol. 2, pp. 396–401, Mar. 2021.

    • J. Li, S. Li, G.-L. Huang, T. Yuan, and M. M. Attallah, “Monolithic 3D-printed slotted hemisphere resonator bandpass filter with extended spurious-free stopband,” Electronics Letters, vol. 55, no. 6, pp. 331–333, Mar. 2019. (Invited Feature Article)

    • J. Li, C. Guo, L. Mao, J. Xiang, G.-L. Huang, and T. Yuan, “Monolithically 3-D printed hemispherical resonator waveguide filters with improved out-of-band rejections,” IEEE Access, vol. 6, pp. 57030–57048, 2018.

    • J. Li, K.-D. Hong, and T. Yuan, “Slotted hemispherical resonators for 3-D printed waveguide filters with extended spurious-free stopbands,” IEEE Access, vol. 7, pp. 130221–130235, 2019.

    • X.-K. Bi, X. Zhang, G.-L. Huang, and T. Yuan, “Compact microstrip NWB/DWB BPFs with controllable isolation bandwidth for interference rejection,” IEEE Access, vol. 7, pp. 49169–49176, 2019.

    • X.-K. Bi, G.-L. Huang, X. Zhang, and T. Yuan, “Design of wideband and high-gain slotline antenna using multi-mode radiator,” IEEE Access, vol. 7, pp. 54252–54260, 2019.

    • X.-K. Bi, X. Zhang, S.-W. Wong, S.-H. Guo, and T. Yuan, “Reconfigurable-bandwidth DWB BPF with fixed operation frequency and controllable stopband,” IEEE Transactions on Circuits and Systems II: Express Briefs, early access.

    • X.-K. Bi, X. Zhang, S.-W. Wong, S.-H. Guo, and T. Yuan, “Synthesis design of Chebyshev wideband bandpass filters with independently reconfigurable lower passband edge,” IEEE Transactions on Circuits and Systems II: Express Briefs, early access.

    • X.-K. Bi, X. Zhang, S.-W. Wong, S.-H. Guo, and T. Yuan, “Design of notched-wideband bandpass filters with reconfigurable bandwidth based on terminated cross-shaped resonators,” IEEE Access, vol. 8, pp. 37416–37427, 2020.

    • X.-K. Bi, X. Zhang, S.-W. Wong, T. Yuan, and S.-H. Guo, “Design of equal-ripple dual-wideband bandpass filter with minimum design parameters based on cross-shaped resonator,” IEEE Transactions on Circuits and Systems II: Express Briefs, vol. 67, no. 10, pp. 1780–1784, Oct. 2020.

    • X. Bi, S. Guo, Z. Zhong, K. Hong, W. He, and T. Yuan, “Reconfigurable single-/dual-wideband bandpass filters based on a novel topology,” Electronics, vol. 9, no. 12, pp. 1–14, Dec. 2020.

    • X.-K. Bi, S.-H. Guo, Y.-J. Zhu, and T. Yuan, “A wideband slotted spherical waveguide antenna based on multi-mode concept,” Electronics, vol. 9, no. 1656, pp. 1–11, Oct. 2020.

    • J.-J. Liang, G.-L. Huang, J.-N. Zhao, Z.-J. Gao, and T. Yuan, “Wideband phase-gradient metasurface antenna with focused beams,” IEEE Access, vol. 7, pp. 20767–20772, 2019.

    • J.-J. Liang, G.-L. Huang, K.-W. Qian, S.-L. Zhang, and T. Yuan, “An azimuth-pattern reconfigurable antenna based on water grating reflector,” IEEE Access, vol. 6, pp. 34804–34811, 2018.

    • J.-J. Liang, G.-L. Huang, W. Xu, T. Yuan, and S. Zhang, “A triple-band antenna for MIMO WLAN applications,” International Journal of RF and Microwave Computer-Aided Engineering, vol. 28, no. 5, Article ID e21251, Jun. 2018.

    • J.-J. Liang, G.-L. Huang, W. Xu, T. Yuan, and S. Zhang, “Self‐diplexed antenna based on loading asymmetric grounding‐vias,” International Journal of RF and Microwave Computer-Aided Engineering, vol. 28, no. 5, Article ID e21243, Jun. 2018.

    • J.-J. Liang, G.-L. Huang, S.-L. Zhang, T. Yuan, G.-M. Zhang, and M. Amin, “Compact differential-fed dual-band antenna via loading shorting pin,” International Journal of RF and Microwave Computer-Aided Engineering, vol. 28, no. 9, Article ID e21497, Nov. 2018.

    • K.-W. Qian, G.-L. Huang, J.-J. Liang, B. Qian, and T. Yuan, “An LTCC interference cancellation device for closely spaced antennas decoupling,” IEEE Access, vol. 6, pp. 68255–68262, 2018.

    • K.-D. Hong, X. Zhang, L. Zhu, X.-K. Bi, and T. Yuan, “Slot loading effect on impedance and radiation performance of high-gain patch antenna under TM03-mode operation,” International Journal of RF and Microwave Computer-Aided Engineering, Article ID e21967, Sept. 2019.

    • K.-D. Hong, X. Zhang, L. Zhu, X.-K. Bi, Z. Chen, and T. Yuan, “A self-balanced wideband patch antenna fed with a U-resonator for stable radiation performance,” IEEE Antennas and Wireless Propagation Letters, vol. 19, no. 4, pp. 661–665, Apr. 2020.

    • 洪凯东,张晓,祝雷,陈哲,袁涛,“高阶模高增益贴片天线的分析与设计综述,”深圳大学学报理工版,vol. 38,no. 1,pp. 69–76,Jan. 2021.

    • C.-Z. Han, G.-L. Huang, T. Yuan, and J.-Z. Wang, “Design of a T-shaped antenna based on characteristic mode manipulation for metal-framed handset application,” Electronics, vol. 7, no. 10, Article ID 209, Oct. 2018.

    • C.-Z. Han, S.-M. Liao, K.-D. Hong, G.-L. Huang, T. Yuan, W. Hong, and C.-Y.-D. Sim, “A frequency-reconfigurable antenna with 1-mm nonground portion for metal-frame and full-display screen handset applications using mode control method,” IEEE Access, vol. 7, pp. 48037–48045, 2019.

    • C.-Z. Han, M.-L. Fan, Z.-P. Zhong, Q.-F. Zeng, G.-L. Huang, W. Xu, and T. Yuan, “A compact planar inverted-F antenna with U-shaped strip for all-metal-shell handset application,” International Journal of RF and Microwave Computer-Aided Engineering, vol. 28, no. 5, Article ID e21245, Jun. 2018.

    • C.-Z. Han, G.-L. Huang, T. Yuan, W. Hong, and C.-Y.-D. Sim, “A frequency-reconfigurable tuner-loaded coupled-fed frame-antenna for all-metal-shell handsets,” IEEE Access, vol. 6, pp. 64041–64049, 2018.

    • C.-Z. Han, L. Xiao, Z. Chen, and T. Yuan, “Co-located self-neutralized handset antenna pairs with complementary radiation patterns for 5G MIMO applications,” IEEE Access, vol. 8, pp. 73151–73163, 2020.

    • X.-T. Yuan, W. He, K.-D. Hong, C.-Z. Han, Z. Chen, and T. Yuan, “Ultra-wideband MIMO antenna system with high element-isolation for 5G smartphone application,” IEEE Access, vol. 8, pp. 56281–56289, 2020.

    • X.-T. Yuan, Z. Chen, T. Gu, and T. Yuan, “A wideband PIFA-pair-based MIMO antenna for 5G smartphones,” IEEE Antennas and Wireless Propagation Letters, vol. 20, no. 3, pp. 371–375, Jan. 2021.

    • Z.-P. Zhong, J.-J. Liang, M.-L. Fan, G.-L. Huang, W. He, X.-C. Chen, and T. Yuan, “A compact CPW-fed UWB antenna with quadruple rejected bands,” Microwave and Optical Technology Letters, vol. 61, pp. 2795–2800, Aug. 2019.

    • Z.-P. Zhong, X. Zhang, J.-J. Liang, C.-Z. Han, M.-L. Fan, G.-L. Huang, and T. Yuan, “A compact dual-band circularly-polarized antenna with wide axial-ratio beamwidth for vehicle GPS satellite navigation application,” IEEE Transactions on Vehicular Technology, vol. 68, no. 9, pp. 8683–8692, Sept. 2019.

    • Z.-P. Zhong, J.-J. Liang, G.-L. Huang, and T. Yuan, “A 3D-printed hybrid water antenna with tunable frequency and beamwidth,” Electronics, vol. 7, no. 10, Article ID 230, Oct. 2018.

    • Z.-P. Zhong, X. Zhang, Y.-J. Zhu, S.-M. Liao, C.-Z. Lu, X.-K. Bi, and T. Yuan, “Compact dual-band printed quadrifilar helix antenna for practical hand-held devices,” International Journal of RF and Microwave Computer-Aided Engineering, vol. 30, no. 11, Article ID e22384, Nov. 2020.

    • Y.-J. Zhu, J. Li, X. Zhang, T. Yuan, Z.-P. Zhong, T.-Y. Tan, and X.-K. Bi, “A 3-D printed spherical antenna with bandwidth enhancement under operation of dual resonance,” IEEE Access, vol. 8, pp. 19345–19352, 2020.

    • S.-M. Liao, B.-J. Zhang, Z. Chen, C.-Z. Han, F. Zhang, and T. Yuan, “Wideband miniaturized 8-element sub-6 GHz MIMO antenna system for mobile handset applications,” IEICE Electronics Express, 2019, vol. 16, no. 23, pp. 1–6, Nov. 2019.

    • X.-K. Bi, X. Zhang, S.-W. Wong, S.-H. Guo, and T. Yuan, “Reconfigurable-bandwidth DWB BPF with fixed operation frequency and controllable stopband,” IEEE Transactions on Circuits and Systems II: Express Briefs, vol. 68, no. 1, pp. 141–145, Jan. 2021.

    • K.-D. Hong, S. Zhong, X. Zhang, L. Zhu, Z. Chen, and T. Yuan, “A monolithic missile radome with improved radiation patterns for application in frequency modulated continuous wave radar,” AEU-International Journal of Electronics and Communications, vol. 132, Article ID: 153653, Apr. 2021.

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    • 一种方向图可重构的贴片天线,中国发明,202010350438.8,2020.04.28.(授权)

    • 一种具有稳定高增益的宽带贴片天线,中国发明,202010494149.5,2020.06.03.

    • 几何塑形微波谐振器,中国发明,202010661081.5,2020.07.10,ZL 202010661081.5,CN 111987403 B.(授权)

    • 紧凑型自隔离宽带天线及移动终端,中国发明,202010745068.8,2020.07.29.

    • 一种双频可展宽波束宽度的贴片天线,中国发明,202011443575.2,2020.12.08.

    • 集成sub-6GHz频段和毫米波频段的共口径天线体及相应的终端,中国发明,202110235678.8,2021.03.03.

    • 一种应用于共口径天线体测试的结构,中国发明,202110236586.1,2021.03.03.

    • 基于低介电损耗液体材料的圆极化可重构贴片天线,中国发明,202110236940.0,2021.03.03.

    • 一种适用于多天线测试的转接装置及其使用方法,中国发明,ZL 202110289735.0,CN 112798830 B.(授权)

    • 一种方向图可重构的高增益贴片天线,中国发明,202110403259.0,2021.04.15.(授权)

    • 谐振腔波导滤波器,中国发明,202110412614.0,2021.04.16.

    • 同轴—波导适配器,中国实用新型,202121306300.4,2021.06.10.

    标准:

    • 国家标准:基于用户面的定位业务技术要求/测试方法 终端——深圳大学为参与单位,袁涛为起草人,待报批

    • 国家标准:LTE移动通信终端支持北斗定位的测试方法——深圳大学为参与单位,袁涛为起草人,制定中

    • 行业标准:无线终端空间射频辐射功率和接收机性能测量方法 第 9 部分:5G NR 无线终端(Sub-6GHz)——深圳大学为参与单位,袁涛为起草人,报批

    • 行业标准:无线终端空间射频辐射功率和接收机性能测量方法 第 1 部分:通用要求——深圳大学为参与单位,袁涛为起草人,报批

    • 行业标准:紧急情况下移动终端位置信息传送测试方法——深圳大学为参与单位,袁涛为起草人,报批

    • 行业标准:终端 MIMO 天线性能要求和测量方法 第 1 部分:LTE 无线终端——深圳大学为参与单位,袁涛为起草人,报批

    • 团体标准:移动互联网+智能家居系统 应用场景设计指南(2020年9月30日发布实施)——深圳大学为参与单位,袁涛为起草人

    • 团体标准:支持北斗的移动通信终端定位技术要求及测试方法 第4部分:空间射频性能(2019年6月17日发布实施)——深圳大学为第二起草单位,袁涛为第二起草人

    论著:

    • 林辉,陈哲,袁涛,《5G移动终端天线设计》,北京:人民邮电出版社,2021年9月第1版,ISBN:978-7-115-56525-9,字数:209千字(英译:《Antenna Design for 5G Mobile Terminals》,Posts & Telecom Press)

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