000			06105nam a2200529 a 4500
001			1morganclaypool200604cem003
003			APU
005			20150820155923.0
007			cr bn |||m|||a
008			081019s2006 caua fsb 000 0 eng d
020			_a9781598293661 (hpk.)
035			_a(OCoLC)68045906
035			_a(CaBNvSL)gtp00531423
040			_aCaBNvSL _beng _cCaBNvSL _dSARA _dWAN
050	0	0	_aQC760.4.M37 _bK36 2006
082	0	0	_221 _a537.6 _bKAN 2006
100	1		_aKantartzis, Nikolaos V. _916328
245	1	0	_aHigher order FDTD schemes for waveguide and antenna structures / _cNikolaos V. Kantartzis and Theodoros D. Tsiboukis.
246	3		_aHigher order finite-difference time-domain schemes for waveguide and antenna structures.
250			_a1st ed.
260			_aSan Rafael, Calif. : _bMorgan & Claypool Publishers, _cc2006.
300			_ax, 215 p. : _bill. ; _c24 cm.
490	1		_aSynthesis lectures on computational electromagnetics, _x1932-1716 ; _v#3.
500			_aPart of: Synthesis digital library of engineering and computer science.
500			_aTitle from PDF t.p. (viewed Oct. 19, 2008)
500			_aSeries from website.
504			_aIncludes bibliographical references.
505	0		_a1. Introduction -- 1.1. Time-domain modeling in computational electromagnetics -- 1.2. The FDTD method for waveguide and antenna analysis -- 1.3. The higher order FDTD formulation -- References -- 2. Conventional higher order FDTD differentiation -- 2.1. Introduction -- 2.2. Fundamentals -- 2.3. Development of the basic conventional algorithm -- 2.4. Higher order FDTD modeling of boundaries and material interfaces -- 2.5. Dispersion-optimized higher order FDTD techniques -- 2.6. Higher order FDTD schemes in curvilinear coordinates -- References -- 3. Higher order nonstandard FDTD methodology -- 3.1. Introduction -- 3.2. The nonstandard finite-difference algorithm -- 3.3. Development of the higher order nonstandard forms in Cartesian coordinates -- 3.4. Generalized higher order curvilinear FDTD method -- 3.5. Dispersion error and stability analysis -- 3.6. Issues of practical implementation -- References -- 4. Absorbing boundary conditions and widened spatial stencils -- 4.1. Introduction -- 4.2. Higher order FDTD formulation of analytical ABCs -- 4.3. Higher order PML absorbers -- 4.4. Widened spatial stencils and dissimilar media interfaces -- References -- 5. Structural extensions and temporal integration -- 5.1. Introduction -- 5.2. Modeling of lossy and dispersive media with higher order FDTD schemes -- 5.3. Improvement via the correction of material parameters -- 5.4. Enhanced spatial approximations -- 5.5. Generalizing temporal integration -- References -- 6. Hybrid and alternative higher order FDTD schemes -- 6.1. Introduction -- 6.2. Hybrid second-order and higher order FDTD techniques -- 6.3. Discrete singular convolution and symplectic operators -- 6.4. The higher order ADI-FDTD method -- 6.5. Higher order weighted essentially nonoscillatory schemes in the time domain -- References -- 7. Selected applications in waveguide systems -- 7.1. Introduction -- 7.2. Excitation schemes and open-end truncation -- 7.3. Multimodal higher order FDTD analysis -- 7.4. Applications : numerical results -- References -- 8. Selected applications in antenna structures -- 8.1. Introduction -- 8.2. Excitation issues and feeding models -- 8.3. Analysis of essential structures -- 8.4. Contemporary antenna configurations -- References.
506			_aAbstract freely available; full-text restricted to subscribers or individual document purchasers.
510	0		_aCompendex.
510	0		_aINSPEC.
510	0		_aGoogle scholar.
510	0		_aGoogle book search.
520			_aThis publication provides a comprehensive and systematically organized coverage of higher order finite-difference time-domain or FDTD schemes, demonstrating their potential role as a powerful modeling tool in computational electromagnetics. Special emphasis is drawn on the analysis of contemporary waveguide and antenna structures. Acknowledged as a significant breakthrough in the evolution of the original Yee's algorithm, the higher order FDTD operators remain the subject of an ongoing scientific research. Among their indisputable merits, one can distinguish the enhanced levels of accuracy even for coarse grid resolutions, the fast convergence rates, and the adjustable stability. In fact, as the fabrication standards of modern systems get stricter, it is apparent that such properties become very appealing for the accomplishment of elaborate and credible designs.
520			_aThis publication provides a comprehensive and systematically organized coverage of higher order finite-difference time-domain or FDTD schemes, demonstrating their potential role as a powerful modeling tool in computational electromagnetics. Special emphasis is drawn on the analysis of contemporary waveguide and antenna structures. Acknowledged as a significant breakthrough in the evolution of the original Yee's algorithm, the higher order FDTD operators remain the subject of an ongoing scientific research. Among their indisputable merits, one can distinguish the enhanced levels of accuracy even for coarse grid resolutions, the fast convergence rates, and the adjustable stability. In fact, as the fabrication standards of modern systems get stricter, it is apparent that such properties become very appealing for the accomplishment of elaborate and credible designs.
530			_aAlso available in print.
538			_aMode of access: World Wide Web.
538			_aSystem requirements: Adobe Acrobat Reader.
650		0	_aAntennas (Electronics) _xMathematical models. _916329
650		0	_aFinite differences. _916330
650		0	_aTime-domain analysis. _916331
650		0	_aWave guides _xMathematical models. _916332
700	1		_aTsiboukis, Theodoros D. _916333
730	0		_aSynthesis digital library of engineering and computer science. _916281
830		0	_aSynthesis lectures on computational electromagnetics (Online), _v#3. _916336
942			_2lcc _cBook
999			_c8642 _d8642