van der Giessen E., Wu Theodore Y.-T. — Advances in Applied Mechanics, Volume 37 :: Электронная библиотека попечительского совета мехмата МГУ

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van der Giessen E., Wu Theodore Y.-T. — Advances in Applied Mechanics, Volume 37

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Название: Advances in Applied Mechanics, Volume 37

Авторы: van der Giessen E., Wu Theodore Y.-T.

Аннотация:

This highly acclaimed series provides survey articles on the present state and future direction of research in important branches of applied solid and fluid mechanics.
Mechanics is defined as a branch of physics that focuses on motion and on the reaction of physical systems to internal and external forces.

Язык:

Рубрика: Физика/

Статус предметного указателя: Готов указатель с номерами страниц

ed2k: ed2k stats

Издание: 1 edition

Год издания: 2000

Количество страниц: 378

Добавлена в каталог: 31.10.2010

Операции: Положить на полку | Скопировать ссылку для форума | Скопировать ID

Предметный указатель

Goodyer, M. J      258 266 273
Gordoa, P. R.      214 230
Gouesbet, G.      181 25
Goussis, D. A.      194 231
Grant, H. L.      252 273
Grant, N. J.      293 362
Gray, D. R      246 273
Green, A. E      5 39 40 84
Greene, G. C.      250 273
Greene, J.      213 216 230
Greenspan, H. P.      91 122 138—141 164
Green’s function, free-space      22
Green’s second identity      22
Grilli, S.      18 87 92 164
Grimshaw, R. H. J.      41 45 66 67 69 84 85
Grossmann, S.      273
Grue, J.      67 84
Gumerman, R. J.      200 231
Gunaratne, G. H      205 231 252 257 273
Guthart, G.      76 77 84
Hadji, L.      204 231
Hall, J. V.      92 164
Hamilton — Cayley theorem      282 298 311 328
Hamiltonian structures      35—36
Hanada      268 274
Hanazaki, H.      67 84
Hashin, Z.      290 361
Hayhurst, D. R      292 301 362
Hebral, B.      252 257 268 273
Heitner, K. L.      150 164
Helisch, W      326 360 361 362
Hemmer, P. C.      214 232
Henderson, D.      76 85
Hennenberg, M      198 201 230 231 235
Hershey, A. V.      168 231
Heslot, F.      252 257 273
Hibberd, S.      91 123 164
Hilton, D. K.      263 264 270 275
Hirota, R.      54 84
Hoard, C. Q.      180 231
Hollis Hallett, A. C.      262 273
Holmes, D. S.      263 265 275 276
Homsy, G.      200 231
Hornung, H.      215 231
Hou, T. Y      23 82 84
Housner, G. W.      150 164
Howard, L. N.      252 273
Hozawa      174 177 231
Huang, D. B.      66 84
Huang, G. — H.      213 214 231
Huang, G. — X.      214 233
Huang, X.      263 265 275 276
Hult, J.      290 301 363
Hunt, J. C. R.      253 274
Hwang, L. — S.      91 125 164
Hyers, D. H.      42 84
Ichikawa, N.      268 274
Ierley, G. R.      214 230
Iida, T      268 274
Ikegami, K.      286 362
Ilschner, B.      293 294 362
Imaishi, N.      174 177 231
Incompressible deformation      315—318
Index/indicial notation      280
Intermediate-depth base      18—20
Interpolation methods for tensor functions      297—299
Inverse scattering transform (IST)      69 70—71
Ivanov, I. B.      201 202 233
Izakson, V. Kh      180 181 232
Jain, R. K      201 202 233
Jakowluk, A.      299 362
Jamond, C      203 229
Janiaud, B.      214 232
Jaumann derivative      294 327 354
Johnson, A. E.      339 362
Johnson, K.      266 276
Johnson, R. S.      170 212 216 230 212 214 215 230 232
Joo, S. W.      199 232
Joseph, D. D.      187 188 235
K $\acute{a}$ rm $\acute{a}$ n, Th. von      37 84
Kac, M      214 232
Kachanov, L.      291 303 362
Kadanoff, L      252 257 269 273
Kadomtsev — Petsviashvili (KP) equation      212
Kadomtsev, B. B.      80 84 212
Kanoglu, U.      91 164
Kao, J.      25 26 46 47 86
Karlsson, S. K. F.      266 274
Kats — Demyanets, V.      201 232
Kaup D. J.      35 84
Kawahara      214 232 236
Keller, J. B      67 84 100 164
Kelly, R. E      194 231
Keolian, R.      76 87
Kholpanov, L.      214 236
Kilgore, R. A.      250 266 274
Kim, S. K      92 164
Kirby, J.      18 78 84 87 92 164
Kistler, A. L.      252 274
Knobloch, E.      204 232
Kolomogorov, A. N.      253 258 274
Korteweg, D. J.      5 32 41 43 84 212 214 232
Korteweg-de Vries (KdV) unidirectional waves/equation      5 54—57 59 60 69— 70 128 143-144
Korteweg-de Vries — Burgers (KdV — B) equation      212
Koschmieder, E. L.      170 174 232
Koster, J. N.      201 235
Kotani      204 230
Koulago, A. E.      214 232
Kozhoukharova, Z. D.      177 232
Kraenkel, R. A.      182 183 232
Kraichnan, R. H.      252 274
Krajcinovic, D.      290 362
Kramer, L.      214 232
Krehl, P.      216 232
Krishnamurti, R.      246 274
kronecker      282 336 337
Kruskal, M. D.      5 70 88 213 216 222 230 238
Kudryashov, N. A.      214 232
Kupershmidt, B. A.      35 84
Kuramoto, Y      204 214 232
Kurdiumov, V.      213 214 231
Lagrange creep condition and      288
Lagrange multiplier method      323—324
Lagrange variables      92 120
Lagrangian — Eulerian method      see Wave run-up Lagrangian
Laing, R. A.      263 274
Laitone, E. V.      4 30 41 44 85 87
Lam constants      319
Lamb, H.      189 233
Lamb, S. H.      97 164
Lambert, R. B.      266 274
Landrini      67 83
Landweber, L.      67 86
Langmuir, D. B.      168 233
Langmuir, I.      168 233
Larraza, A.      76 83 85
Laser doppler velocimetry (LDV)      269
Lawing, P. L.      258 274
Lax, P. D.      57 85 216 233
Lebon, G.      202 203 228 229 234
Leckie, F. A.      292 301 362
Lee, S. — J.      66 67 69 85
Legros, J.      192 201 203 208 209 210 212 213 214 216 220 221 222 229 230 233 235
Lemaitre, J.      290 362
Levchenko, E. B      182 188 189 192 194 195 208 233
Levi — Civita      4 85
Li, Y.      91 93 164
Libchaber, A.      252 257 273
Ligget, J. A.      92 164
Lighthill, J.      3 85

Limat, L.      193 233
Lin, C. C      3 67 85
Lin, D. M      88
Linde, H.      174 188 190 192 208 221 222 233 235 237 238
Linear dispersive model      135—138
Linear nondispersive long (LNDL) wave equations      97 116
Linear nondispersive theory, asymptotic expansion of beach-wave function and the ray theory      110—116
Linear nondispersive theory, beach-wave function      94 98
Linear nondispersive theory, bidirectional model for normal      116—118
Linear nondispersive theory, edge waves on sloping plane beach      103 106
Linear nondispersive theory, normal run-up on a family of beaches      109
Linear nondispersive theory, normal run-up on parabolic beach      107— 109
Linear nondispersive theory, normal run-up on sloping plane beach      102—103
Linear nondispersive theory, oblique run-up on sloping plane beach      101—102
Linear nondispersive theory, summary of      94
Lipa, J.      265 274
Litewka, A.      286 290 362
Liu, H.      40 85
Liu, P. L. — F.      92 93 164 165
Liu, Q. S.      201 233
Loeschcke, K.      221 222 233
Lohse, D      269 273
Longshore current, wave-induced      153 157
Longshore edge waves      104—105
Longuet — Higgens, M. S.      23 85
Lou, S. — Y.      214 233
Low, A. R.      168 233
Lowengrub, J.      23 82
Lu, T. J.      355 361
Lucas, P. G. J.      268 276
Lucassen — Reynders, E. H.      197 209 233
Lucassen, J.      189 197 208 209 233
Luke, J. C.      49 82
Lumley, J. L.      253 275
L’vov, V.      251 274
Maddocks, J. R.      263 276
Madsen, P. A.      18 19 82 85 86
Maksimov, A. G.      237
Maldarelli, C      201 202 233
Manna, M. A.      182 183 232
Mao, Y      78 87
Mapped stress tensor      290
Mapped stress tensor, simplified theory based on      346—359
Maquardt — Levenberg algorithm, nonlinear      357
Maquet, J., G.      181 231
Marangoni effect      168 186—190 199—201 207
Marangoni number      172—177 181 188 192 194—199 202-220
Marton, I.      92 165
Mass and energy transfer between overtaking solitons      57—61
Material tensors of rank four      289—313
Material tensors of rank four, characteristic polynomial for fourth-order tensor      318—323
Material tensors of rank four, combinatorial method      324—327
Material tensors of rank four, formulations of constitutive equations and yield criteria      313—315
Material tensors of rank four, incompressibility and volume change      315—318
Material tensors of rank four, Lagrange multiplier method      323—324
Material tensors of rank four, simplified representations      327—330
Material tensors of rank two      289
Matley, R. G.      268 276
Maugin, G. A.      213 229
Maurer, J.      263 269 274 276
Maxworthy      32 51 57 85 87 216 222 233 237
Mazilu, P.      286 362
McCornick, W.      177 191 193 204 236 237
Mei, C. C.      19 67 85
Melville, W. K.      78 83 216 222 233
Meneveau, C.      254 275
Metcalfe, G. P.      245 274
Meydanli, S. G      289 327 361 362
Meyers, A.      286 362
Miao, G.      78 87
Mihaljan, J.      179 233
Miles, J. W      76 78 83 85 216 220 222 233
Mirie, R. M      51 54 57 86
Miura, R.      213 216 230
Mixed — Euler — Lagrange (MEL) approach      23
Mochalova, N.      214 236
Moilliet, A.      252 273
Monin, A. S.      246 251 274
Monkman — Grant rule      293—294
Monkman, F. G      293 362
Morzy $\acute{n}$ ska, J.      286 290 362
Murakami      268 274
Murakami, S.      290 294 362 363
Murray, R.      18 19 82 85
Naert, A.      252 257 268 273
Naghdi, P.      5 39 40 84
Nakai, H.      268 274
Nakano, A.      268 274
Nataf, H. — C      187 229
Navier — Stokes equations      51 67 171 180 203 243 270
Nekorkin, V. I.      213—216 233 237
Nekrasov, A. I.      4 85
Nelkin      253 274
Nepomnyashchy, A. A.      180 182 188 198 201 204 212 213 214 215 216 222 228 230 231 232 234 235 236 237
Net stress concept      293
Nield, D. A.      174 183 210 234
Niemela, J.      252 257 258 266 268 275
Nitschke, K.      203 234
Noiseux, G F.      91 101 164
Nonlinear constitutive equations for creep behavior      287—296
Nonlinear constitutive equations for elastic behavior      281—284
Nonlinear constitutive equations for plastic behavior      284—287
Nonlinear shallow-water model      118—119
Nonlinear wave interactions, applications      47—48
Nonlinear wave interactions, bidirectional long-wave model      48—51
Nonlinear wave interactions, binary head-on collisions of bidirectional solitons      51—54
Nonlinear wave interactions, binary overtaking collisions of unidirectional solitons      54—57
Nonlinear wave interactions, dissipative solitons and      212—226
Nonlinear wave interactions, mass and energy transfer between overtaking solitons      57—61
Nonlinear wave interactions, on run-up of solitary waves on parabolic beaches      127—134
Normal wave run-up, bidirectional model for      116—118
Normal wave run-up, on a family of beaches      109
Normal wave run-up, on parabolic beach      107—109
Normal wave run-up, on sloping plane beach      102—103
Normand, G      170 179 209 213 234
Norton — Bailey creep law      288
Norton’s creep law, tensorial generalization of      299—303
Norton’s power law      292
Nusselt number      252 266
Nwogu, O.      18 85
Oblique wave run-up on sloping plane beach      101—102
Ockendon, H.      76 86
Ockendon, J. R.      76 86
Odquist, F. K. G      301 363
Ohno, N.      290 294 363
Olver, P. J.      36 86
Onat, E.      290 363
Onsager, L.      253 275
Oron, A.      170 201 204 214 232 234
Orszag, S. A.      203 236
Osgood, W. R.      308 309 357 359 363
Ostrach, S.      170 234
Ouyang, Q.      205 231
P $\acute{e}$ rez — Cord $\acute{o}$ n, R.      179 194 234
P $\acute{e}$ rez — Garc $\acute{i}$ a, G      181 203 229 234
Palm, E.      67 84 180 234
Palmen, P.      289 361
Palmer, H. J.      177 188 234
Pantaloni, J.      203 229 234
Parabolic beaches, nonlinear effects on run-up of solitary waves on      127—134
Parabolic beaches, normal run-up on      107—109
Parmentier, P.      203 234
Parseghian, D.      214 232
Particle image velocimetry (PIV)      269
Patel, V. G      67 86
Pearson, J. R. A.      170 171—175 190 195 202 207 208 234
Peclet number      172
Pedersen, G.      92 164
Peinke, J.      252 257 268 273
Peregrine, D. H.      78 86 91 123 164

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