| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Taylor M.E. — Partial Differential Equations. Basic theory (vol. 1) | 443 |
| O'Malley R.E. — Introduction to Singular Perturbations | 48 |
| Nayfeh A.H. — Perturbation Methods | 308, 361, 374—377, 379 |
| Masujima M. — Path integral quantization and stochastic quantization | 1 |
| Ott E. — Chaos in dynamical systems | 346 |
| Maugin G.A. — Nonlinear waves in elastic crystals | 278 |
| Friedlander S. (Ed), Serre D. (Ed) — Handbook of Mathematical Fluid Dynamics, Vol. 4 | 690, 694 |
| Borovikov V.A., Kinber B.Ye. — Geometrical theory of diffraction | 60 |
| Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.1) | 26—1, 27—1 f |
| Kerker M. — The scattering of light | 19—22 |
| Debye P. — Polar Molecules | 135 |
| Zajac A. — Optics | 36, 149, 243 |
| Zauderer E. — Partial Differential Equations of Applied Mathematics | 89, 107, 703, 732, 738, 740, 749, 765, 798 |
| Audretsch J. — Entangled World: The Fascination of Quantum Information and Computation | 4 |
| Stephani H. — Relativity: an introduction to special and general relativity | 165 |
| De Felice F., Clarke C.J.S. — Relativity on curved manifolds | 235 |
| Banerjee P.P., Poon T.-C. — Principles of applied optics | 16 |
| Bao G., Cowsar L., Masters W. — Mathematical Modeling in Optical Science | 6, 10, 37 |
| Levi-Civita T. — The Absolute Differential Calculus (Calculus of Tensors) | 334 |
| Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.2) | I-26-1, I-27-1 f |
| Zimmer E. — Revolution in Physics | 137 |
| Hughston L.P., Tod K.P., Bruce J.W. — An Introduction to General Relativity | 162 |
| Berger M., Cole M. (translator) — Geometry I (Universitext) | 6.6.5, 6.8.4 |
| Achenbach J.D. — Wave propagation in elastic solids | 139 |
| Goodman J.W. — Introduction to Fourier Optics | 19, 32 |
| Levy M. — Parabolic equation methods for electromagnetic wave propagation | 63, 79 |
| Aczel J., Dhombres J. — Functional equations in several variables with applications to mathematics, information theory and to the natural and social sciences | 74 |
| Stratton J.A. — Electromagnetic Theory | 343 |
| Mclachlan D. — X-ray crystal structure | 167 |
| Vanderlugt A. — Optical signal processing | see “Optics, geometrical” |
| Schulman L.S. — Techniques and applications of path integration | 164—169 |
| Slater J.C. — Quantum Theory of Atomic Structure vol1 | 42 |
| Sears F.W. — Optics | 60 |
| Volovik G. — Artificial black holes | 6 |
| Welford W. — Useful Optics | 1, 2 |
| Thompson Philip A. — Compressible-fluid dynamics | 215 |
| Fuchs D., Tabachnikov S. — Mathematical omnibus: Thirty lectures on classical mathematics | 265, 377 |
| Carmeli M. — Classical Fields: General Gravity and Gauge Theory | 185, 188, 389, 390, 395 |
| Landau L.D., Lifshitz E.M. — The classical theory of fields | 140 |
| Jähne B. — Spatio-Temporal Image Processing | 15 |
| Pattabhi V., Gautham N. — Biophysics | 77, 92, 218 |
| Hermann R. — Differential geometry and the calculus of variations | 136 |
| Stratton J.A. — Electromagnetic Theory | 343 |
| Israel W. (ed.) — Relativity, astrophysics and cosmology | 99-101 |
| Synge J.L. — Relativity: The general theory | 30, 225, 372ff |
| Wurfel P. — Physics of Solar Cells: From Principles to New Concepts | 26 |
| Taylor M.E. — Partial Differential Equations. Nonlinear Equations (vol. 3) | 441 |
| Dickey F.M., Holswade S.C. — Laser beam shaping. Theory and techniques | 54—70, 127, 163, 165—168 |
| Gould H., Tobochnik J., Christian W. — An introduction to computer simulation methods | 240 |
| Lemons D.S. — Perfect form: Variational principles, methods, and applications in elementary physics | 3—5 |
| Lauterborn W., Kurz T. — Coherent optics | 9 |
| Lauterborn W., Kurz T. — Coherent optics | 9 |
| Wilson W.F.R.S. — Theoretical physics. Volume II. Electromagnetism and optics | 235, 238 |
| Friedlander S.(ed.), Serre D.(ed.) — Handbook of Mathematical Fluid Dynamics | 291, 313, 318, 319, 327, 328, 344, 346 |
| Datta S. — Electronic transport in mesoscopic systems | 279—282 |
| Hademenos G.J. — Applied physics | 131 |
| Tsang L., Kong J.A. — Scattering of electromagnetic waves (Vol 3. Advanced topics) | 83 |
| Israel W. (ed.) — Relativity, astrophysics and cosmology | 99—101 |
| Stoker J. J. — Water Waves: The Mathematical Theory with Applications | 133 |
| Israel W. — Relativity, Astrophysics and Cosmology | 99—101 |
| Hume-Rothery W. — Electrons, Atoms, Metals and Alloys | see "Optics" |
| Groesen E., Molenaar J. — Continuum Modeling in the Physical Sciences (Monographs on Mathematical Modeling and Computation) | 207 |
| Feynman R., Leighton R., Sands M. — Lectures on Physics 2 | I-26-1, I-27-1 f |
| Davies P. — The New Physics | 271 |
| Cheney W. — Analysis for Applied Mathematics | 162 |
| Guillemin V., Sternberg S. — Symplectic techniques in physics | 34 |
| Moeller K. — Optics: Learning by Computing, with Examples Using Maple, MathCad®, Matlab®, Mathematica®, and Maple® (Undergraduate Texts in Contemporary Physics) | 1 |
| Halpern A., Erlbach E. — Beginning Physics II: Waves, Electromagnetism, Optics and Modern Physics | 329 |
| Bell J., Kearsley M., Pitaevskii L. — Course of Theoretical Physics, Volume 8, Volume 8, Second Edition: Electrodynamics of Continuous Media | 290—3 |
| Landau L.D., Lifshitz E.M. — Course of Theoretical Physics, Volume 8: Electrodynamics of Continuous Media | 290—3 |
| Bell J.S., Kearsley M.J. — Course of Theoretical Physics, Volume 8: Electrodynamics of Continuous Media | 290—3 |
| L.D. Landau, E.M. Lifshitz — Electrodynamics of Continuous Media | 290—3 |
| L.D. Landau — Electrodynamics of Continuous Media | 290—3 |
| L. D. LANDAU, E. M. LIFSHITZ — ELECTRODYNAMICS OF CONTINUOUS MEDIA | 290—3 |
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