Boundary Integral and Singularity Methods for Linearized Viscous FlowCambridge University Press, 28 Şub 1992 - 259 sayfa The aim of this book is to bring together classical and recent developments in the particular field of Newtonian flow at low Reynolds numbers. The methods are developed from first principles, alternative formulations are compared, a variety of configurations are addressed, the proper mathematical framework is discussed in the context of functional analysis and integral-equation-theory, and procedures of numerical solution in the context of the boundary element method are introduced. The text contains a fair amount of original material pertaining, in particular, to the properties and explicit form of the Green's functions, and the theory of the integral equations that arise from boundary integral representations. |
İçindekiler
I | 1 |
III | 3 |
IV | 7 |
V | 9 |
VI | 14 |
VIII | 16 |
IX | 19 |
X | 22 |
LII | 116 |
LIII | 117 |
LIV | 120 |
LV | 121 |
LVI | 124 |
LVII | 127 |
LVIII | 130 |
LIX | 133 |
XI | 24 |
XII | 29 |
XIII | 30 |
XIV | 31 |
XV | 35 |
XVI | 38 |
XVII | 45 |
XIX | 48 |
XX | 51 |
XXI | 55 |
XXII | 58 |
XXIII | 60 |
XXIV | 61 |
XXV | 62 |
XXVI | 66 |
XXVIII | 68 |
XXIX | 71 |
XXX | 76 |
XXXI | 80 |
XXXII | 82 |
XXXIII | 84 |
XXXIV | 87 |
XXXV | 88 |
XXXVI | 89 |
XXXVIII | 91 |
XXXIX | 93 |
XLI | 94 |
XLII | 95 |
XLIII | 96 |
XLIV | 99 |
XLV | 100 |
XLVI | 103 |
XLVII | 104 |
XLVIII | 107 |
XLIX | 109 |
L | 113 |
LI | 114 |
LX | 139 |
LXI | 141 |
LXII | 143 |
LXIII | 145 |
LXIV | 147 |
LXV | 148 |
LXVI | 151 |
LXVII | 155 |
LXVIII | 156 |
LXIX | 157 |
LXX | 159 |
LXXI | 162 |
LXXII | 163 |
LXXIII | 167 |
LXXIV | 171 |
LXXV | 176 |
LXXVI | 177 |
LXXVII | 180 |
LXXVIII | 182 |
LXXIX | 190 |
LXXX | 192 |
LXXXI | 196 |
LXXXII | 198 |
LXXXIII | 199 |
LXXXV | 201 |
LXXXVI | 202 |
LXXXVII | 203 |
LXXXVIII | 205 |
LXXXIX | 206 |
XC | 208 |
XCII | 210 |
XCIII | 212 |
XCIV | 215 |
| 249 | |
| 257 | |
Diğer baskılar - Tümünü görüntüle
Sık kullanılan terimler ve kelime öbekleri
arbitrary axisymmetric biharmonic equation boundary conditions boundary element boundary integral equation boundary integral representation coefficients component compute constant continuity equation corresponding curvature defined density derive distribution disturbance flow divergence theorem dl(x domain of flow double-layer potential ds(x eigensolutions eigenvalues equal to zero expression external Faxen relation flow due flow produced fluid force and torque Fredholm integral equation Gij(x Green's function infinite infinite flow infinity interface internal flow linear marker points matrix mean curvature method normal vector obtain particle plane wall point force pole potential dipole Pozrikidis problem radius represents the flow respect right-hand side rigid body motion rotation single-layer potential solution sphere Stokes equation Stokes flow stream function stress tensor stresslet Substituting surface force surface integral symmetric Tijk Tijk(x torque torque exerted translation two-dimensional values vanishes velocity field x₁ σο дхі дхк