000			09117nam a2201681 i 4500
001			7434881
003			IEEE
005			20220712205928.0
006			m o d
007			cr |n|||||||||
008			160412s2016 nju ob 001 eng d
020			_a9781119060239 _qelectronic bk.
020			_z9781119060345 _qprint
020			_z1119060230 _qelectronic bk.
020			_z9781119060215 _qelectronic bk.
020			_z1119060214 _qelectronic bk.
024	7		_a10.1002/9781119060239 _2doi
035			_a(CaBNVSL)mat07434881
035			_a(IDAMS)0b00006484fee223
040			_aCaBNVSL _beng _erda _cCaBNVSL _dCaBNVSL
050		4	_aTK5103.484
082	0	4	_a621.3/8216 _223
100	1		_aChoi, Kwonhue, _eauthor. _928807
245	1	0	_aProblem-based learning in communication systems using MATLAB and simulink / _cKwonhue Choi and Huaping Liu.
264		1	_aPiscataway, New Jersey : _bIEEE Press., _c2016.
264		2	_a[Piscataqay, New Jersey] : _bIEEE Xplore, _c[2016]
300			_a1 PDF (490 pages).
336			_atext _2rdacontent
337			_aelectronic _2isbdmedia
338			_aonline resource _2rdacarrier
490	1		_aIEEE Series on Digital & Mobile Communication
504			_aIncludes bibliographical references and index.
505	0		_aMatlab and Simulink Basics -- Numerical Integration and Orthogonal Expansion -- Fourier Series and Frequency Transfer Function -- Fourier Transform -- Convolution -- Low Pass Filter and Band Pass Filter Design -- Sampling and Reconstruction -- Correlation and Spectral Density -- Amplitude Modulation -- Quadrature Multiplexing and Frequency Division Multiplexing -- Hilbert Transform, Analytic Signal, and SSB Modulation -- Voltage-Controlled Oscillator and Frequency Modulation -- Phase-Locked Loop and Synchronization -- Probability and Random Variables -- Random Signals -- Maximum Likelihood Detection for Binary Transmission -- Signal Vector Space and Maximum Likelihood Detection I -- Signal Vector Space and Maximum Likelihood Detection II -- Correlator-Based Maximum Likelihood Detection -- Pulse Shaping and Matched Filter -- Ber Simulation at the Waveform Level -- QPSK and Offset QPSK in Simulink -- Quadrature Amplitude Modulation in Simulink -- Convolutional Code -- Fading, Diversity, and Combining -- Orthogonal Frequency Division Multiplexing in AWGN Channels -- Orthogonal Frequency Division Multiplexing Over Multipath Fading Channels -- Mimo System Part I: Space Time Code -- Mimo System Part II: Spatial Multiplexing -- Near-Ultrasonic Wireless Orthogonal Frequency Division MULTIPLEXING MODEM DESIGN.
506	1		_aRestricted to subscribers or individual electronic text purchasers.
520			_aDesigned to help teach and understand communication systems using a classroom-tested, active learning approach. This book covers the basic concepts of signals, and analog and digital communications, to more complex simulations in communication systems. Problem-Based Learning in Communication Systems Using MATLAB and Simulink begins by introducing MATLAB and Simulink to prepare readers who are unfamiliar with these environments in order to tackle projects and exercises included in this book. Discussions on simulation of signals, filter design, sampling and reconstruction, and analog communications are covered next. The book concludes by covering advanced topics such as Viterbi decoding, OFDM and MIMO. In addition, this book contains examples of how to convert waveforms, constructed in simulation, into electric signals. It also includes problems illustrating how to complete actual wireless communications in the band near ultrasonic frequencies. A content-mapping table is included in this book to help instructors easily find lab projects for communications, wireless communications, and signal and systems classes. Special features of this book: . Discusses communication concepts and algorithms, which are explained using simulation projects, accompanied by MATLAB and Simulink. Provides step-by-step code exercises and instructions to implement execution sequences. Includes a companion website that has MATLAB and Simulink model samples and templates (link provided below) This book is intended for students and instructors, enrolled in or teaching communications systems, analog and digital communications, and wireless communication courses. Kwonhue Choi is a Professor in the Department of Information and Communication Engineering and the Principal Director of Broadband Wireless Communication (BWC) Laboratory at Yeungnam University, Korea. His research areas include efficient multiple access, diversity schemes, and cooperative communications for Fifth-Generation (5G) and beyond systems. He is the inventor of FADAC-OFDM and PSW (Properly scrambled Walsh) codes. Huaping Liu is a Professor with the School of Electrical Engineering and Computer Science at Oregon State University, USA. He was formerly a cellular network radio frequency systems engineer specializing on modeling, simulating, optimizing, and testing various digital communication systems. Dr. Liu received his PhD in Electrical Engineering at New Jersey Institute of Technology, USA.
530			_aAlso available in print.
538			_aMode of access: World Wide Web
588	0		_aPrint version record.
630	0	0	_aMATLAB. _93506
630	0	0	_aSIMULINK. _99756
630	0	7	_aMATLAB. _2fast _93506
630	0	7	_aSIMULINK. _2fast _99756
650		0	_aWireless communication systems. _93474
650		0	_aOrthogonal frequency division multiplexing. _926117
650		7	_aOrthogonal frequency division multiplexing. _2fast _926117
650		7	_aWireless communication systems. _2fast _93474
655		4	_aElectronic books. _93294
695			_aAWGN
695			_aAWGN channels
695			_aAerospace electronics
695			_aAlgorithm design and analysis
695			_aAmplitude modulation
695			_aApproximation error
695			_aBand pass filters
695			_aBand-pass filters
695			_aBandwidth
695			_aBaseband
695			_aBinary phase shift keying
695			_aBit error rate
695			_aClocks
695			_aCommunication systems
695			_aConvolution
695			_aConvolutional codes
695			_aCorrelation
695			_aDelays
695			_aDemodulation
695			_aDesign methodology
695			_aDigital filters
695			_aDistortion
695			_aDiversity reception
695			_aEncoding
695			_aFace
695			_aFading channels
695			_aFinite element analysis
695			_aFourier series
695			_aFourier transforms
695			_aFrequency conversion
695			_aFrequency division multiplexing
695			_aFrequency measurement
695			_aFrequency modulation
695			_aFrequency-domain analysis
695			_aGain
695			_aGaussian distribution
695			_aGaussian noise
695			_aGenerators
695			_aGuidelines
695			_aHistograms
695			_aImpulse responses
695			_aIndexes
695			_aInformation filtering
695			_aInformation filters
695			_aLinear systems
695			_aLinearity
695			_aLow pass filters
695			_aMATLAB
695			_aMIMO
695			_aMatched filters
695			_aMathematical model
695			_aMaximum likelihood detection
695			_aMicrowave integrated circuits
695			_aMultipath channels
695			_aMultiplexing
695			_aNoise measurement
695			_aOFDM
695			_aPassband
695			_aPhase locked loops
695			_aPresses
695			_aProbability density function
695			_aPulse generation
695			_aPulse shaping methods
695			_aQuadrature amplitude modulation
695			_aRadio frequency
695			_aRandom variables
695			_aRayleigh channels
695			_aReceivers
695			_aReceiving antennas
695			_aSections
695			_aShape
695			_aSignal reconstruction
695			_aSimulation
695			_aSimulink
695			_aSoftware packages
695			_aSpace-time codes
695			_aSpread spectrum management
695			_aSynchronization
695			_aTime-domain analysis
695			_aTime-frequency analysis
695			_aTransfer functions
695			_aTransmitters
695			_aTransmitting antennas
695			_aUltrasonic wireless communication
695			_aVectors
695			_aVoltage-controlled oscillators
695			_aWireless communication
695			_aWorld Wide Web
700	1		_aLiu, Huaping, _eauthor. _928808
710	2		_aIEEE Xplore (Online Service), _edistributor. _928809
710	2		_aWiley, _epublisher. _928810
776	0	8	_iPrint version: _aChoi, Kwonhue _tProblem-Based Learning in Communication Systems Using MATLAB and Simulink _d: Wiley,c2016 _z9781119060239
830		0	_aIEEE series on mobile & digital communication. _96802
856	4	2	_3Abstract with links to resource _uhttps://ieeexplore.ieee.org/xpl/bkabstractplus.jsp?bkn=7434881
942			_cEBK
999			_c74442 _d74442