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Ames W.F. — Numerical methods for Partial Differential Equations
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Название: Numerical methods for Partial Differential EquationsАвтор: Ames W.F. Аннотация: This volume is designed as an introduction to the concepts of modern numerical analysis as they apply to partial differential equations. The book contains many practical problems and their solutions, but at the same time, strives to expose the pitfalls — such as overstability, consistency requirements, and the danger of extrapolation to nonlinear problems methods used on linear problems. Numerical Methods for Partial Differential Equations, Third Edition reflects the great accomplishments that have taken place in scientific computation in the fifteen years since the Second Edition was published. This new edition is a drastic revision of the previous one, with new material on boundary elements, spectral methods, the methods of lines, and invariant methods. At the same time, the new edition retains the self-contained nature of the older version, and shares the clarity of its exposition and the integrity of its presentation.
Язык: Рубрика: Математика /Численные методы /Численный анализ /Статус предметного указателя: Готов указатель с номерами страниц ed2k: ed2k stats Издание: Second EditionГод издания: 1977Количество страниц: 367Добавлена в каталог: 18.02.2005Операции: Положить на полку |
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Предметный указатель
Simpson’s rule 18 Simultaneous first-order equations, explicit methods 203—208 Simultaneous first-order equations, hybrid methods 209—212 Simultaneous first-order equations, implicit method 209 Simultaneous first-order equations, stability 206 Sincovec, R. F. 304 319 Singularity 230—238 Singularity transformations 236 Singularity, boundary 95 Singularity, corner 160 Singularity, interior 232 233 Singularity, jump phenomena 265 Singularity, mesh refinement 234 Singularity, Motz — Woods method 234—236 Singularity, re-entrant corner 234 Singularity, removal by transformation 236 237 Singularity, shock 265 Singularity, subtracting out 233 Singularity, time to occurrence 265 Skan, S. W. 322(16) 349 Slattery, J. C. 159 164 Smith, J. 278 316 Smolitskiy, K. L. 304 319 336 350 Sneddon, I. N. 97 161 Snyder, M. A. 138 141 Soare, M. 274 315 Sokolnikoff, I. S. 275 316 Solution properties 41 Solution, classical 334 Solution, weak 334 Sorenson, H. W. 322 349 Sound wave propagation, equations for 175 271 Southwell, R. V. 2 39 106 162 Spectral radius 109 111 Spectral radius, comparison 111 Spectral radius, Gauss — Seidel 111 Spectral radius, Jacobi 111 Spencer, D. E. 3 39 41 90 246 312 Splitting method 307—310 Splitting method, accuracy 309 Splitting method, applied to diffusion 309 Splitting method, Samarskii’s 283 Stability 28 29 47 66 222 Stability analysis, extension of matrix 59 Stability analysis, Fourier 47 55 Stability analysis, matrix 56—61 Stability condition, eigenvalue requirements 56 Stability condition, explicit method 45 48 Stability condition, von Neumann 46 Stability, John’s definition 29 Stability, limit of first-order method 222 Stability, over- 197—199 Stability, pointwise 29 198 Stability, stepwise 29 198 Stabilizing corrections method 307 (see also “Alternating direction implicit method as a fractional steps method”) Standard deviation 26 Star see “Computational molecules” Stationary functional method 324 Steep gradients, importance 90 Stein, L. R. 244 312 Stein, P. 111 162 Stencil see “Computational molecules” Stepwise stability 198 Stewart, J. P. 325 349 Stiefel, E. 136 163 275 316 Stirling’s formula 11 Stoker, J. J. 265 315 Stone, H. L. 255 313 Strang, W. G. 219 228 249(46) 313 343 350 Stream function 77 284 Stream function equation, implicit method for 284—289 Stream function vorticity method, for Navier-Stokes equations 283—291 Street, R. L. 294(186) 318 String vibration, nonlinear 201 202 Stroud, A. H. 326 349 Subdomain method 322 Successive approximations, method of 82 Successive over-relaxation (SOR) 2 106 119—122 Successive over-relaxation (SOR), applications 124 125 130—134 Successive over-relaxation (SOR), extensions 125—130 Successive over-relaxation (SOR), Garabedian’s 125 Successive over-relaxation (SOR), lines (rows) 146 147 Successive over-relaxation (SOR), optimum 124 Successive over-relaxation (SOR), optimum parameters 127—129 Successive over-relaxation (SOR), rate of convergence 117 Successive over-relaxation (SOR), self-adjoint equations 148 Swartz, B. 332 349 Swope, R. D. 7 9 39 176 227 Symmetric diffusion equation, numerical method 237 Symmetric diffusion equation, spherically 237 Symmetric operator 334 Symmetrization 114 Synge, J. L. 320 348 Szarski, J. 339 350 Szego, G. 326 349 Szewczyk, A. A. 286 290(169) 317 Takami, H. 283 290 316 Talbot, G. P. 263 314 Tamada, K. 10 39 Taniuti, T. 6 39 179 186 227 265 270 315 Tateyama, N. 149 156 Taub, A. H. 263(93) 314 Taussky, O. 101 161 Taylor, T. D. 299 318 Thoman, D. C. 286 290(169) 317 Thomas algorithm 52 68 146 203 288 Thomas, L. H. 184 228 Thorn, A. 283 316 Thornhill, C. K. 262 314 Threadline equation, direct calculation of primitive variables 176 Three-dimensional molecule, seven point 259 Time constants 270 Time quasilinear system 202 203 Time to singularity development 265—267 Timoshenko, S. P. 97 161 232 245 311 312 324 349 Todd, J. 112 162 Tomotika, S. 10 39 Topp, L. J. 320(9) 348 Torsion equation 97 Torsional rigidity 97 Townsend, A. A. 282 317 Transformation, Hopf 76 Transformation, singularity removal 236 237 Transformation, von Mises 78 Transpiration cooling 77 Trapezoidal rule 97 Traveling threadline, vibrations 202 Trial functions, weighted residual methods choice 336 Trial functions, weighted residual methods choice, completeness in energy requirement 336 Tridiagonal algorithm 52 68 146 203 288 Tridiagonal matrix 52 68 72 288 Trigger, K. R. 239 312 Troesch, B. A. 249(46) 313 Trulio, J. G. 239 312 Truncation errors, Crank — Nicolson equation 61 Truncation errors, DuFort-Frankel 61 Truncation errors, explicit equation 61 Trutt, F. C. 159 164 234 311 Tsingow, M. 263(93) 314 Tukey, J. 305 319 Turner, J. 221 229 Turner, M. J. 320 348 Two-level implicit formula 55 Umoto, J. 149 156(63) 163 Uniqueness theorems, hyperbolic equations 167—170 Uniqueness theorems, parabolic equations 42 Unstable method 17 Upper bounds, for nonlinear parabolic equations 339—342 van de Vooren, A. I. 128 129 130 162 Varga, R. S. 53 91 108 113 115 122 139 141 143 145 147 149 150 152(62) 153 154(62) 156(62) 162 163 274 275 278 315 316 Variable coefficients 64—70 Variance 26 Vector fields, classification 295—297 Vector fields, classification, irrotational 295—297 Vector fields, classification, solenoidal 295—297 Vector potential 295—298 Vector potential method 294—299 Velocity potential 10 Vibration, beam 3 279—281 Vibration, explicit method 280 Vibration, higher-order equations 279—281 Vibration, implicit method 280 281 Vicario, A. A. 177 227 Vichnevetsky, R. 299(197) 318 Villadsen, J. V. 325 349 Viswanathan, R. V. 33 40 Vitasek, E. 276(136) 316 336(48) 350 Vliegenthart, A. C. 128 129 130 von Karman, T. 323 349 von Mises transformation 38 von Neumann, J. 263(93) 314 Vorticity 284 Vorticity equation 284 Vorticity equation with alternating direction implicit method 290 Vorticity equation with DuFort-Frankel molecule 289 Vorticity equation, explicit algorithm 285—289 Vorticity, boundary conditions 286 287 298 299 Vorticity, production 287 Vorticity, vector 297 Wachspress, E. L. 125 153 154 156 163 164 260 314 Walsh, J. L. 33 40 Warlick, C. H. 138 Warten, R. 236 311 Wasow, W. R. 15 24 29 33 40 56 65 76 91 104 107 108 146 162 249 276 313 Watter, W. 304 319 336 339 350 Wave equation 8 38 Wave equation, characteristics 165 Wave equation, domain of influence 166 Wave equation, general solution 165 166 Wave equation, interval of dependence 166 Wave equation, pure initial value problem 165 Wave propagation, along moving string 37 Weak solution 334 Weather prediction, numerical 260—262 Weighted residual methods 320—333 Weighted residual methods, boundary 321 Weighted residual methods, Bubnov — Galerkin 323 Weighted residual methods, collocation 322 Weighted residual methods, general 323 Weighted residual methods, integral 323 Weighted residual methods, interior 321 Weighted residual methods, least squares 322 Weighted residual methods, mixed 321 Weighted residual methods, residuals 321 Weinberger, H. F. 336 337 350 Weinstein, A. 232 311 Welch, J. E. 290 318 Well-posed problem 41 92 Well-posed problem, nonlinear parabolic 74 Weller, R. 30 40 Wendroff, B. 217 221 228 229 241 242 243 263 312 332 349 Wessel, W. R. 281 317 Westphal, H. 339 350 Wheeler, M. F. 133 160 163 Whiteman.J. R. 238 312 Whitham, G. B. 244(29) 312 Widlund, O. B. 156 163 Wielandt, H. 249 313 Wiener, N. 1 39 Wilkes, J. O. 289 317 Wilkinson, J. H. 247 249 313 Willoughby, R. 98(8) 161 Winslow, A. M. 160 164 Wise, H. 258 314 Woinowsky-Krieger, S. 232 311 Woodall, S. R. 291 316 Woods, L. C. 259 314 Wright, K. 325 349 Yamada, H. 323 349 Yanenko, N. N. 283 307 309 310 317 Yasinsky, J. B. 336 350 Yohe, M. 258 313 Young, D. M. 33 40 44 90 101 106 118 120 124 130 133 137 138 139 144 149 150 152(62) 154(62) 156(62) 160 162 163 Zabusky, N. J. 10 39 265 315 Zaiser, J. N. 37(61) 40 176(6) 202(6) 227 265(105) 315 Zajac, E. E. 197 199 228 Zienkiewicz, O. C. 320 343 348 Zlamal, M. 238(13) 278 312 316 Zondek, B. 106 145 162 ‘False’ boundary, applications of 51 193 ‘Leapfrog’ finite difference approximation 207 208 ‘Leapfrog’ finite difference approximation, stability 207 208 ‘Oh’ notation, big 11 12 ‘Oh’ notation, class of functions 13 ‘Oh’ notation, little 13 ‘Oh’ notation, misuse 12 ‘Power law’ viscosity 160 ‘Relaxation’ method 274 ‘Staggered’ finite difference scheme 216 217
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