10A培太阳能充电控制器原理图加代码完全开放

5G无线通信系统关键技术（剑桥大学出版社） 2017年出版 对于5G所有最新技术进行了详细说明 很全的工具书Key Technologies for5G Wireless SystemsVINCENT W. S, WONGUniversity of British ColumbiaROBERT SCHOBERUniversity of Erlangen-NurembergDERRICK WING KWAN NGUniversity of New South WalesLI-CHUN WANGNational Chiao-Tung University即CAMBRIDGEUNIVERSITY PRESSCAMBRIDGEUNIVERSITY PRESSUniversity Printing House. Cambridge CB2 SBS. United KindomOne Liberty Plaza, 20h Floor New York, NY I(H0X, USA477 williamstown Road, port Melbourne, yic 3207 australia48424, 2nd Floor, Ansar Rod, Daryaganj. Delhi- I l4XH2, India79 Anson Road, #o6-(/ 00, Singapore 079%MCambridge University Press is part of the Lniversity of CambridgeIt furthers the University s mission by disseminating knowledge in the pursuit ofeducation, leaming and research at the highest international levels of excellence.www.cermbrid吧eInformtiononthistitlewww.cambridgeorg/978110713241810,1017③781316771655C Cambridge University Press 2017This puhlication is in copyright. Subjcct to sututonry exceptionand to the provisions of relewant collective licensing agreementsno reproduction of any part may take place without the writtenpermission of Cutmbridgre University Press.First published 2(117Printed in the United Kingdom by TJ International Ltd. Padstow, CornwallA catalogue recor for this pudlieafiove is aailable fromm the British LibraryLibrary of Congress Cataloging- in Pi hlicaiomz dataNames: Wong, Vincent W.S., editorTitle: Key technologies for 5G wireless systems/edited by Vincent W.S. Wong [and 3 otherOther titles key technologies for five g wireless svstemsDescription: Carmbrisige: New York, NY: Cambridge Lniversity Press, 2017.Identifiers: l CCN 2016045220)1 ISBN 9781 172418 (hardback)Subjects: LCSH: Wireless communication systems, I Machine-to-machinecommunications. Internet of things.Classitication: LCC TKs1032K49 2(17 DDC 621.38450-dc23LcrecordavailaBleathttps://lccnioc-gov/2016m5220)ISBN 978-1-107-17241- HardbackCambridge University Press has no responsibility for the persistence or accuracy ofURLs for extermal or third-party Internet websites referred to in this puhlication,and does not guarantee that any content on such websites is, or will remainaccurate of appropriateContentsList of Contributorspage xvIPrefaceKXIOverview of New Technolog ies for 5G SystemsVincent W S, Wong, Robert Schober, Derrick Wing Kwan Ng, and Li-Chun Wang1.1 Introduction1.2 Cloud Radio Access Networks1.3 Cloud Computing and Fog Computing1. 4 Non-orthogonal Multiple Access1. 5 Flexible Physical Layer Design334.4671. 6 Massive MIMo1. 7 Full-Duplex Communications1. 8 Millimeter wave1.9 Mobile Data Offloading, LTE-Unlicensed, and Smart Data Pricing131. 10 IoT M2M. and D2D1. I1 Radio Resource Management, Interference Mitigation, and Caching61. 12 Energy Harvesting Communications1. 13 Visible Light Communication19Acknowledgments20ReferencesPart I Communication Network Architectures for 5G Systems25Cloud Radio Access Networks for 5G Systems27Chih-Lin I, Jinn Huang, Xueyan Husang, Rongwved Ren, and Yami. Chen2.1 Rethinking the Fundamentals for 5G Systems272 User- Centric Networks2923 C-RAN Basics292.3.1 C-RAN Challenges Toward SGI302.4 Next Generation Fronthaul Interface (NGFI: The FH Solutionfor SGC-RAN312. 4.1 Proof-of-Concept Development of NGFI33Contents2.5 Proof-of-Concept Verification of Virtualized C-RAN2.5.1 Data packets3725.2 Test Procedure382.5.3 Test Results392. 6 Rethinking the Protocol Stack for C-RAN2.6.1 Motivation402.6.2 Multilevel Centralized and Distributed Protocol Stack402.7 Conclusion45AcknowledgmentsReferencesFronthaul-Aware Design for Cloud Radio Access Networks48Liang Liu, Wei Yu, and Osvaldo Simeone3. 1 Introduction483.2 Fronthaul-Aware Cooperative Transmission and Reception493. 2.1 Uplink513.2.2 Downlink573.3 Fronthaul-Aware Data Link and Physical layers61.3. I Uplink633.3.2 Downlink693.4 Conclusion73Acknowledgments74References74MobEdge computing76Ben Liang4.1 Introduction764.2 Mobile Edge Computing774.3 Reference architecture794.4 Benefits and Application Scenarios804 4.1 User-Oriented Use cases4. 4.2 Operator-Oriented Use Ca814 5 Research challenges824.5.1 Computation Offloading824.5.2 Communication Access to Computational Resources834.5.3 Multi-resource Schedulin844.5 4 Mobility Management854.5.5 Resource Allocation and Pricing4.5.6 Network functions virtualization864.5, 7 Security and Pri864.5.8 Integration with Emerging Technologies874.6 Conclusion88ReferencesContentsDecentralized Radio Resource Management for Dense HeterogeneousWireless networksAbolfazl Mehhodniya and Fumiyuki Adach5.1 Introduction925.2 System Model935.2.1 SINR Expression5.2.2 Load and Cost Function Expressions955.3 Joint BSCSA/UECSA ON/OFF Switching Scheme965.3.1 StrateTy Selection and Beacon Transmission53.2 UE AssocIation5.3.3 Proposed Channel Segregation Algorithms985.3.4 Mixed-Strategy Update3.4 Computer Simulation5.5 Conclusion104Acknowledgments04References105Part ll Physical Layer Communication Techniques107Non-Orthogonal Multiple Access(NOMA)for 5G Systems109Wei Llang, Zhiguo Ding, and H. Vincent Poor6.1 Introduction1106.2 NOMA in Single-Input Single-Output(SISO)Systems1126.2.1 The basics of nomaI126. 2. 2 Impact of User Pairing on NOMA136.2,3 Cognitive Radio Inspired NOMA6. 3 NOMA in MIMO Systems1206.3.1 System Model for MIMO-NOMA Schemes1216.3.2 Design of Precoding and Detection Matrices with Limited CSIT 1236.3.3 Design of Precoding and Detection Matrices with Perfect CSIT 1266.4 Summary and Future Directions128ReferencesFlexible Physical Layer Design133Maximilian Matthe, Martin Danneberg, Dan Zhang, and Gerhard Fettweis7.1 Introduction1337. 2 Generalized Frequency Division Multiplexing357.3 Software-Defined waveform1377. 3. 1 Time Domain Processing1387.3.2 Implementation Architecture1387.4 GFDM Receiver Design14174 Synchronization unit1427. 4.2 Channel Estimation Unit1474.3 MIMo-GFDM Detection Unit145Contents7.5 Summary and Outlook147Acknowledgments148References488Distributed Massive MIMO in Cellular Networks15IMichail Matthaiou and Shi Jin8. I Introduction15l8. 2 Massive MIMO: Basic Principles1528.2.1 Uplink Downlink Channel Models1538.2.2Favorable Propagation1548.3 Performance of Linear Receivers in a Massive MIMO Uplink1548.4 performance of linear precoders in a massive mimo downlink1578. s Channel estimation in massive mimo systems1588.5.1 Uplink Transmission1598.5.2 Downlink Transmission1608.6 Applications of Massive MIMO Technology1618.6.1 Full-Duplex Relaying with Massive Antenna Arrays1618.6.2 Joint Wireless Information Transfer and Energy Transfer forDistributed massive mimo1638.7 Open Future Research Directions1678. 8 Conclusionl68References169Full-Duplex Protocol Design for 5G Networks172Tanelf Ahonen and Risto wichman9.1 Introduction1729. 2 Basics of Full-Duplex Systems1739.2.1 In-Band Full-Duplex Operation Mode1739.2.2 Self-Interference and Co-channel Interference1749.2.3 Full-Duplex Transceivers in Communication Links1759. 2. 4 Other Applications of Full-Duplex Transceivers1789.3 Design of Full-Duplex Protocols1799.3, 1 Challenges and Opportunities in Full-Duplex Operation1799.3.2 Full-Duplex Communication Scenarios in 5G NetworksR9.4 Analysis of Full-Duplex Protocols1829.4.1 Operation Modes in Wideband Fading Channels1829. 4, 2 Full- Duplex Versus Half-Duplex in Wideband Transmission1849.5 Conclusion1849.5.1 Prospective Scientific Research DirectionsI849.5.2 Full-Duplex in Commercial 5G Networks185RLItrtncekl8610Millimeter Wave Communications for 5G Networks188Jiho Song, Miguel R Castellanos, and David J. LoweContentsⅸx10.1 Motivations and Opportunities18810.2 Millimeter Wave Radio Propagation18910. 2.1 Radio Attenuation1890. 2. 2. Free-Space Path LOSs19I10.2.3 Severe shadow19310.2 4 Millimeter Wave Channel model19310.2.5 Link Budget Analysis19410.3 Beamforming Architectures19510.3, Analog beamforming solutions19610.3.2 Hybrid Beamforming Solutions20010.3.3 Low-Resolution Receiver Architecture2010.4 Channel Acquisition Techniques20110.4.1 Subspace Sampling for Beam Alignment20210.4.2 Compressed Channel estimation Techniques20510.5 Deployment Challenges and Applications20710.5.1 EM Exposure at Millimeter Wave Frequencies20710.5.2 Heterogeneous and Small-Cell Networks208Acknowledgments209References209Interference Mitigation Techniques for Wireless Networks214Koralia N Pappi and George K, Karag annidis1 1.1 Introduction21411.2 The Interference Management Challenge in the 5G vision21411. 2. 1 The 5G Primary Goals and Their Impact on Interference2141 1.2.2 Enabling Technologies for Improving Network Efficiencyand Mitigating Interference21611.3 Improving the Cell-Edge User Experience: Coordinated Multipoint218I 1.3.1 Deployment Scenarios and Network Architecture2181 13. 2 CoMP Techniques for the Uplink22011.3.3 CoMP Techniques for the Downlink2211 1.4 Interference Alignment: Exploiting Signal Space Dimensions2231 1.4.1 The Concept of Linear Interference Alignment224L1. 4.2 The Example of the X-Channel225I 1. 4.3 The K-User Interference Channel and Cellular NetworksAsymptotic Interference Alignment22611.4.4 Cooperative Interferenee Networks22711.4.5 Insight from IA into the Capacity Limits of Wireless Networks 22711.5 Compute-and-Forward Protocol: Cooperation at the ReceiverSide for the Uplink22811.5.1 Encoding and Decoding of the CoF Protocol22811.5.2 Achievable-Rate Region and Integer Equation Selection23011.5.3 Advantages and Challenges of the CoF Protocol232IL6 Conclusion233References233

基于matlab的纠错码源码实现。在编码端，根据BCH码的（n，k）产生生成矩阵G和校验矩阵H

【实例简介】YUV颜色空间下成熟苹果识别，包括测试图片，程序，实验报告等

matlab代码，基于正则化的图像超分辨重建与处理，用PSNR值确定重建效果

人脸识别的MATLAB代码，可成功运行，附编译的教程和orl人脸库。代码可实现从人脸库选择任意一张照片，进而检测出是第几个人。欢迎有需要的朋友下载。

【实例简介】神州飞航 1553B板卡自带程序 包括BC RT BM功能

【实例简介】自己写的MFC学生成绩管理系统，包括增删改查，以及ADO数据库连接代码简单，结构清楚明白，易于理解

全国省市区街道数据，带编码，有单独的省、市、区、街道JSON文件，以及整合在一起的JS文件，根据需求自己选择。

关于认知无线电频谱分配方面的知识，希望对寻找资源的同学有帮助第37卷第19期何利,郑湘渝,刘振坤:基于图着色理论的最大效用频谱分配算法9542最大平均效用ISAA,但小于CSGC的时问开销。但是由图2可知,在同一图2分别给出了CSGC、ISAA和MUAA3种算法在用频谱数目下,MUAA算法的最大平均效用是最高的,并且随户取值为7和12时的最大平均效用。随着系统中频谱数的不着系统中频谱数目的増多,MUAA算法的最大平均效用高于淅增加,3种算法的最大平均效用基本呈现上升趋势,但是SAA算法,ISAA算法和(S(C算法的效用相同。MUAA算MUAA算法的最大平均效用増加趋势大于CSGC和ISAA算法以牺牲较少的时间开销获得了较大的系统效用,可见,法,这是因为随着频谱数目增加,MUAA算法的用户提高了MUAA算法是这3种算法中最优的。频谱的复用率。5结束语120本文研究了认知无线电网络屮基于图论着色模型的频谱H-ISAAMUAA分配算法,在分析CSGC、ISAA存在的问题基础上,提出兼CSGC顾系统效用和时间开销的MUAA算法,并对3种算法在系统效用和时间开销方面进行仿真比较。仿真结果表明,MUAA算法是有效的。下一步工作是将ISAA的并行计算方法应用2个到MUAA屮,在不增加时间开销的基础上,提高频谱分配的系统效用。参考文献[1] Shared Spectrum Company. Dynamic Spectrum Use[EB/OLI频谱数日(2007-04-25).http://www.sharedspectrum.com(an=7[2]Zheng Haitao, Peng Chunyi. Collaboration and Fairness inOpportunistic Spectrum Access[C]/Proc. of the 40th AnnuaMUAAInlernatiunal Conference on Communications. Seoul Kurea: Ieee3]廖楚林,陈劼,唐有喜,等.认知无限电中的并行频谱分配算法[J.电子与信息学报,2007,29(7:1608-1611[4 Wang Jiao, Huang Yuqing, Jiang Hong. Improved algorithm ofSpectrum Allocation Based on Graph Coloring Model in CognitiveRadio[clproc. of International Conference on Communicationsand Mubile Conputing. Washington D. C, USA: IEEE CoInputer频谱数目ociety,2009:353-357[S]彭振,赵知劲.基于混合蛙跣算法的认知无线电频谱分配[门.图2CsGC、ISAA和MUAA的最大平均效用计算机工程,2010,36(6):210-212.综上所述,由图1可知,MUAA算法的时间开销稍大」编辑陆燕菲(上接第92页信道下本地频谱感知和认知网络合作频谱感知进行研究和仿真,结果表明,合作频谱感知能明显改善 Rician衰洛信道的检测效果。下一步工作是研究其他衰落信道如 Nakagami信道下无线认知网络的合作频谱感知参考文献[]周贤伟.软件无线电M].北京:国防工业出版社,2008AWGN[2 Ghascmi A, Sousa E s. Collaborative Spcctrum Sensing forOpportunistic Access in Fading Environments[C]//Proc. of the Ist10IEEE SYmp. on Dynamic Spectrum Access Networks, Baltimore,103锴误警报概率USA: IEEE Press. 2005: 131-136图4不同用户数目时合作频谱感知的ROC曲线[3] Digham FF, Alouini M S, Simon M K On the Energy Detection of4绪束语Unknown Signals over Fading Channels[C]/Proc. of ICC"03在深度阴影衰落环境屮,认知用户需要合作频谱感知来Ottawa Canada: IEEE Press. 2003: 3575-3579检测到主用户的存在。 Rician信道模型适用于郊区或农村建4 Fctc b a.认知无线电技术lMJ.赵知劲,郑什链,尚俊娜,译模,以后将可能广泛应用,因此,对 Rician衰落信道的认知北京:科学出版社,2008网络合作频谱感知的研究具有重要意义。本文对 Rician衰落编辑金胡考C1994-2012ChinaAcademicJournalElcctronicPublishinghOusc.Allrightsrescrved.http://www.cnki.nct

KPCA+SVM源代码，用matlab仿真实现，很实用