| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Heinbockel J.H. — Introduction to tensor calculus and continuum mechanics | 329 |
| Falconer K. — Fractal Geometry. Mathematical Foundations and applications | 273 |
| Falconer K. — Fractal Geometry: Mathematical Foundations and Applications | 307 |
| Evans L.C. — Partial Differential Equations | 20, 23, 295 |
| Wolf J.P. — The Scaled Boundary Finite Element Method | 5 |
| Meyer C.D. — Matrix analysis and applied linear algebra | 563, 572 |
| Shampine L.F., Allen R.C., Pruess Jr.S. — Fundamentals of numerical computing | 72 |
| Hormander L. — Notions of Convexity | 117 |
| Drazin P. — Introduction to Hydrodynamic Stability | 44 |
| Watkins D. — Fundamentals of matrix computations | 524 |
| Ladyzhenskaya O.A. — Mathematical theory of viscous incompressible flow | 21 |
| Biscamp D. — Magnetohydrodynamic turbulence | 16 |
| Aris R. — Vectors, Tensors and the Basic Equations of Fluid Mechanics | 70 |
| Becker A.A. — The Boundary Element Method in Engineering. A complete course | 21, 41 |
| Edwards H. — Advanced Calculus: A Differential Forms Approach | 339, 341, 348 |
| Clarke L.J. — Surface crystallography: an introduction to low energy electron diffraction | 118 |
| Edminister J.A. — Schaum's outline of electromagnetics | 114, 127 |
| Fock V. — The Theory of Space Time and Gravitation | 167, 172, 257, 262, 280 |
| Rutherford D.E. — Vector Methods | 85 |
| Chow W.W., Koch S.W. — Semiconductor-laser fundamentals | 85 |
| Duistermaat J.J., Kolk J.A.C. — Multidimensional Real Analysis II: Integration | 721, 750 |
| Egorov Y.U. (Ed), Gamkrelidze R.V. (Ed) — Partial Differential Equations I: Foundations of the Classical Theory | 14, 83 |
| Ziman J.M. — Elements of Advanced Quantum Theory | 119, 137, 139 |
| Kurth R. — Dimensional analysis and group theory in astrophysics | 169 |
| Planck M. — Introduction to Theoretical Physics | 212, 217ff. |
| Volakis J.L., Chatterjee A., Kempel L.C. — Finite element method for elecromagnetics | 7 |
| Zauderer E. — Partial Differential Equations of Applied Mathematics | 32, 212, 494, 560, 589, 623 |
| Haas A.E. — Introduction to theoretical physics, Vol. 1 and 2 | 186 |
| Schercliff J.A. — Vector Fields | 167, 173, 176, 195, 233, 284, 312, 316 |
| Raine D.J., Thomas E.G. — An Introduction to the Science of Cosmology | 188 |
| Nagaosa N. — Quantum field theory in condensed matter physics | 70 |
| Reist P.C. — Aerosol Science and Technology | 212, 215—216 |
| Kilmister C.W. — General theory of relativity | 38, 159 |
| Unertl W.N. — Physical Structure | 599 |
| Cracknell A.P., Wong K.C. — The Fermi Surface: Its Concept, Determination and Use in the Physics of Metals | 408 |
| Kunz K.S., Luebbers R.J. — The finite difference time domain method for electromagnetics | 328 |
| Dubrovin B.A., Fomenko A.T., Novikov S.P. — Modern Geometry - Methods and Applications. Part 1. The Geometry of Surfaces, Transformation Groups and Fields | 424 |
| Eschenauer H., Olhoff N., Schnell W. — Applied structural mechanics : fundamentals of elasticity, load-bearing structures, structural optimization | 50 |
| Demmel J.W. — Applied Numerical Linear Algebra | see also “model problem”, 265-279 |
| MacRobert T.M. — Spherical Harmonics an Elementary Treatise on Harmonic Functions with Applications | 145, 195 |
| Lieberman M.A., Lichtenberg A.J. — Principles of Plasma Discharges and Materials Processing | 28 |
| Jackson J.D. — Classical electrodynamics | 12 |
| Bracewell R.N. — The Fourier Transform and its applications | 92 |
| Streetman B.G. — Solid State Electronic Devices | 146, 182, 305 |
| Egorov Y.V., Shubin M.A. — Partial Differential Equations I (Foundations of the Classical) | 14, 83 |
| Carrol B.W., Ostlie D.A. — An introduction to modern astrophysics | 335 |
| Greiner W. — Classical electrodynamics | 12, 47 |
| Cherrington B.E. — Gaseous Electronics and Gas Lasers | 6, 123 |
| Davies B. — Integral Transforms and Their Applications | 169 |
| Neff H.P.Jr. — Introductory electromagnetics | 61—62, 88 |
| Lawden D.F. — An Introduction to Tensor Calculus, Relativity and Cosmology | 140 |
| Guru B.S., Hiziroğlu H.R. — Electromagnetic Field Theory Fundamentals | 59, 60 |
| Berman A. — Nonnegative Matrices in the Mathematical Sciences | 196 |
| Woodhouse N.M.J. — Geometric quantization | 152 |
| Àìåíçàäå Þ.À. — Òåîðèÿ óïðóãîñòè | 86 |
| Carl D. Meyer — Matrix Analysis and Applied Linear Algebra Book and Solutions Manual | 563, 572 |
| Demmel J. — Applied numerical linear algebra | 266-279 |
| Bjoerck A., Dahlquist G. — Numerical mathematics and scientific computation | 306 |
| Harman T.L., Dabney J.B., Richert N.J. — Advanced Engineering Mathematicas with MATLAB | 700 |
| Maxwell J.C. — Treatise on electricity and magnetism. Volume Two | 77, 148 |
| Courant R., Hilbert D. — Methods of Mathematical Physics. Volume 1 | 368 |
| Lee T.H. — Design of CMOS Radio-Frequency Integrated Circuits | 26 |
| Murray D.A. — Introductory Course In Differential Equations: For Students In Classical And Engineering Colleges | 186 |
| Gloub G.H., Ortega J.M. — Scientific Computing and Differential Equations | 247, 275ff |
| Stratton J.A. — Electromagnetic Theory | 162, 166—167, 230 |
| Yang W. — Fluidization, Solids Handling, and Processing: Industrial Applications | 826 |
| Vladimirov V. S. — Equations of mathematical physics | 33, 44 |
| Collatz L. — The numerical treatment of differential equations | 369, 371, 381, 386, 405, 410, 414, 417, 419, 422, 439, 445, 447, 451 |
| Brebbia C.A., Domingues J. — Boundary elements. An introductory course | 17, 123 |
| Churchill R.V. — Operational mathematics | 301, 307 |
| Goldsmid H.J. (ed.) — Problems in solid state physics | 11.11 |
| Wolfgang K. H. Panofsky, Phillips Panofsky, Melba Panofsky — Classical Electricity and Magnetism | 11, 149 |
| Gould H., Tobochnik J., Christian W. — An introduction to computer simulation methods | 384—387 |
| Anderssen R.S., de Hoog F.R., Lukas M.A. — The application and numerical solution of integral equations | 146 |
| Davis H.T. — Introduction to nonlinear differential and integral equations | 19 |
| Marder M.P. — Condensed matter physics | 538 |
| Slater J.C., Frank N.H. — Electromagnetism | 4, 23—27, 31, 63 |
| Hinrichsen D., Pritchard A. — Mathematical Systems Theory I: Modelling, State Space Analysis, Stability and Robustness | 41 |
| Kuttler K. — Notes for Partial Differrential Equations | 113 |
| Cloud M.J., Drachman B.C. — Inequalities: with applications to engineering | 88 |
| Collins G.W. — The virial theorem in stellar astrophysics | 7, 30 |
| Davies J.H. — The physics of low-dimensional semiconductors : an introduction | 330 |
| Biskamp D. — Magnetohydrodynamic Turbulence | 16 |
| Griffits D.J. — Introductions to electrodynamics | 83, 110, 235, 274 |
| Blum E.K., Lototsky S.V. — Mathematics of Physics and Engineering | 158, 168, 427 |
| Koonin S.E., Meredith D.C. — Computational Physics-Fortran Version | 55, 57, 121, 146, 158 |
| Sommerfeld A. — Thermodynamics and Statistical Mechanics | 20 |
| Israel W. (ed.) — Relativity, astrophysics and cosmology | 12 |
| Kubo R. — Thermodynamics | 22 |
| Israel W. — Relativity, Astrophysics and Cosmology | 12 |
| Kravens T.E. — Physic of Solar System Plasmas | 35—37, 264 |
| Attwood S.S. — Electric and Magnetic Fields | 167, 170, 437 |
| Slater J., Frank N. — Introduction to Theoretical Physics | 212, 217ff. |
| Shu-Ang Zhou — Electrodynamics of solids and microwave superconductivity | 19 |
| Kanwal R.P. — Generalized functions: Theory and technique | 187, 287 |
| Sturrock P. — Plasma Physics: An Introduction to the Theory of Astrophysical, Geophysical and Laboratory Plasmas | 9, 122 |
| Hejhal D.A. — The Selberg Trace Formula for PSL(2,R) (volume 2) | 645 |
| Ehrenberg W. — Electric Conduction in Semiconductors and Metals | 15, 16, 275, 278, 343 |
| Zorich V.A., Cooke R. — Mathematical analysis II | 298, 304, 493 |
| Wiedemann H. — Particle Accelerator Physics I: Basic Principles and Linear Beam Dynamics | 385 |
| Cheney W. — Analysis for Applied Mathematics | 203, 210 |
| Zorich V. — Mathematical Analysis | 298, 304, 493 |
| Falconer K. — Fractal geometry: mathematical foundations and applications | 307 |
| Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | 177, 183, 279 |
| Foster J., Nightingale J. — A Short Course in General Relativity (Longman mathematical texts) | 85—86 |
| Berman A., Plemmons R.J. — Nonnegative matrices in the mathematical sciences | 196 |
| Davies B. — Integral Transforms and their Applications | 169 |
| Dennery P., Krzywicki A. — Mathematics for Physicists | 351 |
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