000			02390aam a2200385 a 4500
001			50460
003			0000000000
005			20240411193237.0
008			110425s2011 nyua b 001 0 eng
010			_a2011010656
015			_aGBB091928 _2bnb
016	7		_a015617945 _2Uk
020			_a0071622896 (hbk.) : _c£91.99
020			_a9780071622899 (hbk.) : _c£91.99
035			_a(Uk)015617945
040			_aStDuBDS _beng _cStDuBDS _dUk
042			_aukblsr
050	0	0	_aTK6564.3 _b.W38 2011
082	0	0	_a621.3824 _222
245	0	0	_aWaveform diversity : _btheory & applications / _cUnnikrishna Pillai ... [et al.].
260			_aNew York : _bMcGraw-Hill Professional ; _aLondon : _bMcGraw-Hill [distributor], _cc2011.
300			_axiii, 306 p. : _bill. ; _c24 cm.
336			_atext _2rdacontent
337			_aunmediated _2rdamedia
338			_avolume _2rdacarrier
500			_aFormerly CIP. _5Uk
504			_aIncludes bibliographical references and index.
520			_a"Cutting-edge transmitter and receiver waveform design techniques Optimum design can improve signal direction, interference, and noise suppression across various disciplines that utilize waveforms, including radar, sonar, and communications. Waveform Diversity explains the role of transmitter and receiver waveform design to boost overall performance. Written by experts in the field, this monograph covers joint transmitter receiver design, optimum design methods, constant envelope transmit signals, and sparsity-based receivers. Proven methods for mitigating noise and clutter and maximizing output signal power are included in this practical guide.Waveform Diversity covers: Waveform design and matched filtering New methods for optimum transmitter and receiver design Transmitter threshold energy and energy-bandwidth tradeoff Increasing transmit power efficiency with constant envelope transmit signals Optimum waveform design to reduce noise and clutter Discrete-time waveform design Sparsity-based receiver design methods"-- _cProvided by publisher.
650		0	_aAntenna radiation patterns.
650		0	_aBeamforming.
650		0	_aRadio _xTransmitter-receivers.
700	1		_aPillai, S. Unnikrishna, _d1955-
999			_c15751 _d15751