| Introduction | p. 1 |
| An elastic medium with sources of external and internal stresses | p. 9 |
| Medium with sources of external stresses | p. 9 |
| Medium with sources of internal stresses | p. 17 |
| Discontinuities of elastic fields in a medium with sources of external and internal stresses | p. 25 |
| Elastic fields far from the sources | p. 30 |
| Notes | p. 33 |
| Equilibrium of a homogeneous elastic medium with an isolated inclusion | p. 35 |
| Integral equations for a medium with an isolated inhomogeneity | p. 35 |
| Conditions on the interface between two media | p. 40 |
| Ellipsoidal inhomogeneity | p. 43 |
| Ellipsoidal inhomogeneity in a constant external field | p. 48 |
| Inclusion in the form of a plane layer | p. 54 |
| Spheroidal inclusion in a transversely isotropic medium | p. 56 |
| Crack in an elastic medium | p. 59 |
| Elliptical crack | p. 64 |
| Radially heterogeneous inclusion | p. 69 |
| Elastic fields in a medium with a radially heterogeneous inclusion | p. 69 |
| Thermoelastic problem for a medium with a radially heterogeneous inclusion | p. 75 |
| Multilayered spherical inclusion | p. 77 |
| Axially symmetric inhomogeneity in an elastic medium | p. 84 |
| Multilayered cylindrical inclusion | p. 93 |
| Notes | p. 96 |
| Thin inclusion in a homogeneous elastic medium | p. 97 |
| External expansions of elastic fields | p. 97 |
| Properties of potentials (4.4) and (4.5) | p. 99 |
| External limit problems for a thin inclusion | p. 103 |
| Thin soft inclusion | p. 103 |
| Thin hard inclusion | p. 105 |
| Internal limiting problems and the matching procedure | p. 107 |
| Singular models of thin inclusions | p. 110 |
| Thin ellipsoidal inclusions | p. 111 |
| Notes | p. 116 |
| Hard fiber in a homogeneous elastic medium | p. 117 |
| External and internal limiting solutions | p. 117 |
| Principal terms of the stress field inside a hard fiber | p. 120 |
| Stress fields inside fibers of various forms | p. 125 |
| Cylindrical fiber | p. 125 |
| Prolate ellipsoidal fiber | p. 129 |
| Fiber in the form of a double cone | p. 130 |
| Curvilinear fiber | p. 135 |
| Notes | p. 137 |
| Termal and electric fields in a medium with an isolated inclusion | p. 139 |
| Fields with scalar potentials in a homogeneous medium with an isolated inclusion | p. 139 |
| Ellipsoidal inhomogeneity | p. 141 |
| Constant external field | p. 141 |
| Linear external field | p. 141 |
| Spheroidal inhomogeneity in a transversely isotropic medium | p. 143 |
| Multilayered spherical inclusion in a homogeneous medium | p. 143 |
| Thin inclusion in a homogeneous medium | p. 147 |
| Axisymmetric fiber in a homogeneous media | p. 152 |
| Homogeneous elastic medium with a set of isolated inclusions | p. 155 |
| The homogenization problem | p. 155 |
| Integral equations for the elastic fields in a medium with isolated inclusions | p. 158 |
| Tensor of the effective elastic moduli | p. 160 |
| The effective medium method and its versions | p. 162 |
| Differential effective medium method | p. 169 |
| The effective field method | p. 172 |
| Homogeneous elastic medium with a set of ellipsoidal inclusions | p. 177 |
| Elastic medium with a set of spherically layered inclusions | p. 180 |
| The Mori-Tanaka method | p. 181 |
| Regular lattices | p. 186 |
| Thin inclusions in a homogeneous elastic medium | p. 192 |
| Elastic medium reinforced with hard thin flakes or bands | p. 195 |
| Elastic medium with thin hard spheroids (flakes) of the same orientation | p. 197 |
| Elastic medium with thin hard spheroids homogeneously distributed over the orientations | p. 198 |
| Elastic medium with thin hard unidirected bands of the same orientation | p. 200 |
| Elastic media with thin soft inclusions and cracks | p. 202 |
| Thin soft inclusions of the same orientation | p. 205 |
| Homogeneous distribution of thin soft inclusions over the orientations | p. 205 |
| Elastic medium with regular lattices of thin inclusions | p. 206 |
| Plane problem for a medium with a set of thin inclusions | p. 210 |
| A set of thin soft elliptical inclusions of the same orientation | p. 211 |
| Homogeneous distribution of thin inclusions over the orientations | p. 212 |
| Regular lattices of thin inclusions in plane | p. 214 |
| A triangular lattice of cracks | p. 216 |
| Collinear cracks | p. 217 |
| Vertical row of parallel cracks | p. 217 |
| Matrix composites reinforced by short axisymmetric fibers | p. 218 |
| Elastic medium reinforced with unidirectional multilayered fibers | p. 226 |
| Thermoelastic deformation of composites with multilayered spherical or cylindrical inclusions | p. 229 |
| The point defect model in the theory of composite materials | p. 234 |
| Effective elastic properties of hybrid composites | p. 239 |
| Two different populations of inclusions in a homogeneous matrix (hybrid composite) | p. 240 |
| Two-point correlation functions for a hybrid composite with sets of cylindrical and spheroidal inclusions | p. 244 |
| Overall elastic moduli of three-phase composites | p. 250 |
| Conclusions | p. 256 |
| Notes | p. 257 |
| Multiparticle interactions in composites | p. 259 |
| The effective field method beyond the quasicrystalline approximation | p. 259 |
| Mean values of some homogeneous random fields | p. 262 |
| General scheme for constructing multipoint statistical moments | p. 268 |
| The operator of the effective properties | p. 272 |
| Pair interactions between inclusions | p. 274 |
| Notes | p. 280 |
| Thermo- and electroconductive properties of composites | p. 281 |
| Integral equations for a medium with isolated inclusions | p. 281 |
| The effective medium method | p. 283 |
| Differential effective medium method | p. 286 |
| The effective field method | p. 288 |
| Random set of thin inclusions | p. 291 |
| Dielectric properties of composites with high volume concentrations of inclusions | p. 294 |
| The EFM in application to two-phase composites (the quasicrystalline approximation) | p. 295 |
| The EFM beyond the quasicrystalline approximation | p. 299 |
| Effective dielectric permittivity in 3D-case | p. 303 |
| Interaction between two inclusions in the 2D-case | p. 308 |
| Dielectric properties of the composites in 2D-case | p. 311 |
| Discussion and conclusion | p. 314 |
| Cross-properties relations | p. 316 |
| Notes | p. 318 |
| Special tensor bases of four rank tensors | p. 321 |
| E-basis | p. 321 |
| P-basis | p. 322 |
| [Gamma]-basis | p. 324 |
| R-basis | p. 324 |
| Averaging the elements of the E-, P-, [gamma]-, and R-bases | p. 325 |
| Tensor bases of rank four tensors in 2D-space | p. 326 |
| Generalized functions connected with the Green function of static elasticity | p. 329 |
| The Green functions of static elasticity in the k-representation | p. 329 |
| The Green functions of static elasticity in the x-representation | p. 330 |
| The Green functions of static elasticity in 2D-case | p. 337 |
| Special presentation of the K-operator | p. 339 |
| Properties of some potentials of static elasticity concentrated on surfaces | p. 343 |
| Gauss' and Stokes' integral theorems | p. 343 |
| Derivatives of the double-layer potential of static elasticity | p. 344 |
| Potentials with densities that are tensors of a surface [Omega] | p. 349 |
| Transition through the layers in the problems of thermoelasticity for multilayered inclusions | p. 353 |
| Elastic and thermoelastic problems for a spherical multilayered inclusion | p. 353 |
| Elastic and thermoelastic problems for a cylindrical multilayered inclusion | p. 354 |
| Correlation functions of random sets of spherical inclusions | p. 357 |
| The Percus-Yevick correlation function of nonpenetrating sets of spheres in the 3D-case | p. 357 |
| The Percus-Yevick correlation function of nonpenetrating sets of spheres in the 2D-case | p. 357 |
| Correlation functions of the Boolean random sets of spheres and cylinders | p. 358 |
| Random models of two populations of inclusions | p. 359 |
| References | p. 365 |
| Index | p. 375 |
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