Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
Wolf E.L. — Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | |
Ito K. — Encyclopedic Dictionary of Mathematics. Vol. 2 | 341.D |
Tennekes H., Lumley J.L. — A First Course in Turbulence | 198, 201,226 |
Schweizer W. — Numerical quantum dynamics | 4 |
Hyvarinen A. — Independent Component Analysis | 16 |
Bender C., Orszag S. — Advanced Mathematical Methods for Scientists and Engineers | 543p |
Henrici P. — Applied and Computational Complex Analysis (Vol. 2) | 471 |
Atkins P.W., Friedman R.S. — Molecular Quantum Mechanics | 23 |
Williamson R.E., Crowell R.H., Trotter H.F. — Calculus of vector functions | 318 |
Dill K.A., Bromberg S. — Molecular Driving Forces: Statistical Thermodynamics in Chemistry and Biology | 14 |
Levine I.N. — Molecular Spectroscopy | 9 |
Curtain R.F., Pritchard A.J. — Functional Analysis in Modern Applied Mathematics | 80 |
Debnath L., Mikusinski P. — Introduction to Hilbert Spaces with Applications | 365 |
Appell J.M., Kalitvin A.S., Zabrejko P.P. — Partial Integral Operators and Integro-Differential Equations | 433 |
Behnke H., Bachmann F., Fladt K. — Fundamentals of Mathematics, Volume III: Analysis | 95 |
Gorenflo R., Vessella S. — Abel Integral Equations: Analysis and Applications | 39 |
Serre D. — Handbook of Mathematical Fluid Dynamics, Vol. 1 | 5—8, 10, 14, 22, 23, 44, 47 |
Hensley D. — Continued Fractions | 79, 87, 155, 156, 158, 206 |
Gershenfeld N. — The Nature of Mathematical Modelling-Neil Gershenfeld | 169 |
Raabe D. — Computational materials science | 57 |
Greiner W. — Quantum mechanics. An introduction | 38, 50, 147, 341 |
Galwey N.V. — Introduction to Mixed Modelling: Beyond Regression and Analysis of Variance | 6, 8, 157, 158, 334, 342,343 |
Duistermaat J.J., Kolk J.A.C. — Multidimensional Real Analysis II: Integration | 644 |
Shiffer M.M., Bowden L. — Role of Mathematics in Science | 41 |
Holden A.V. — Chaos | 275 |
Petrov V.V. — Sums of Independent Random Variables | 3 |
Barlow R. — Statistics: A Guide and Reference to the Use of Statistical Methods in the Physical Sciences | 23, 24 |
Chorin A.J. — Vorticity and turbulence | 26, 27 |
Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.1) | 6—8 f |
Kurth R. — Dimensional analysis and group theory in astrophysics | 21 |
Purdom R.W., Brown C.A. — The analysis of algorithms | see “Density function” |
Ito K. — Encyclopedic Dictionary of Mathematics | 341.D |
Galindo A., Pascual P. — Quantum Mechanics Two | I 90, 97, II 203 |
Gnedenko B.V., Kolmogorov A.N. — Limit Distributions for Sums of Independent Random Variables | 23 |
Dirac P.A.M. — The Principles of Quantum Mechanics | 258 |
Zajac A. — Optics | 138 |
Zauderer E. — Partial Differential Equations of Applied Mathematics | 6 |
Sokolnikoff I.S. — Mathematics of Physics and Modern Engineering | 632, 634 |
Holden A.V. — Chaos | 275 |
Hinton D., Schaefer P.W. — Spectral Theory and Computational Methods of Sturm-Liouville Problems | 308 |
Kubo R., Toda M., Hashitsume N. — Statistical physics II. Nonequilibrium statistical mechanics | 4 |
Kolmogorov A.N., Fomin S.V. — Introductory real analysis | 367 |
Rickayzen G. — Green's functions and condensed matter | 16 |
Bingham N.H., Goldie C.M., Teugels J.L. — Regular variation | see “Density” |
Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.2) | I-6-8 f |
Peleg Y., Pnini R., Zaarur E. — Schaum's outline of theory and problems of quantum mechanics | 155 |
Kubo R. — Statistical Mechanics: An Advanced Course with Problems and Solutions | 4 |
Dirac P.A.M. — The Principles of Quantum Mechanics, Vol. 27 | 258 |
Galindo A., Pascual P. — Quantum Mechanics One | 90, 97 |
Englert B.G. (Ed) — Quantum Mechanics | 257, 258 |
Lichtenberg A.J., Liebermen M.A. — Regular and Chaotic Dynamics | see also “Invariant distribution” |
Cercignani C. — Theory and Application of the Boltzman Equation | 3, 8, 9, 10, 11, 30, 31, 32, 35, 50, 79, 98 |
Tarantola A. — Inverse problem theory and methods for model parameter estimation | 5, 7, 159 |
Feller W. — Introduction to probability theory and its applications (Volume II) | see “Densities” |
Wolf E.L. — Nanophysics and nanotechnology: an introduction to modern concepts in nanoscience | 51, 66 |
Gardiner C.W.W., Haken H. — Handbook of Stochastic Methods: For Physics, Chemistry and the Natural Sciences | 28 |
Orlando T.P., Delin K.F. — Foundations of Applied Superconductivity | 227 |
Baker G.A., Gammel J.L. — The Padé Approximant in Theoretical Physics | 139 |
Gray C.G., Gubbins K.E. — Theory of molecular fluids | 149—156 |
Mehta M.L. — Random Matrices | 79, 471, 495, 608 |
ter Haar D. — Elements of Statistical Mechanics | 216 |
Slater J.C. — Quantum Theory of Atomic Structure vol1 | 53—57, 105—108 |
Mazo R.M. — Brownian Motion: Flucuations, Dynamics, and Applications | 55 |
Halzen F., Martin A.D. — Quarks and Leptons: An Introductory Course in Modern Particle Physics | 71, 74, 103 |
Binmore K. — Fun and Games: A Text on Game Theory | 512 |
Bates D.R. — Quantum Theory | 44 |
Shankar R. — Principles of quantum mechanics | 121 |
West B.J., Bologna M., Grigolini P. — Physics of Fractal Operators | 215—222 |
Risken H. — The Fokker-Planck equation: methods of solution and applications | 14 |
Cotterill R.M.J. — Biophysics: An Introduction | 375 |
Murrel J.N., Bosanac S.D. — Introduction to the Theory of Atomic and Molecular Collisions | 6 |
Nelson W.B. — Recurrent events data analysis for product repairs, disease recurrences, and other applications | 28 |
Flogge S. (ed.) — Encyclopedia of Physics. Thermodynamics of Gases | 153, 160, 218 |
Azaroff L.V. — Introduction to Solids | 205 |
Adomian G. — Stochastic Systems | 59, 242, 297 |
Nouredine Z. — Quantum Mechanics: Concepts and Applications | 29, 174 |
Duistermaat J.J, Kolk J.A.C. — Distributions: theory and applications | 35 |
Mandel L., Wolf E. — Optical Coherence and Quantum Optics | 5 |
Atkins P. — Molecular Quantum Mechanics | 18 |
Lena P., Lebrun F. — Observational Astrophysics (Astronomy and Astrophysics Library Series) | 437 |
Mitchell T.M. — Machine Learning | 165 |
Puri P.R. — Mathematical methods of quantum optics | 11, 99 |
Kemble E. C. — The fundamental principles of quantum mechanics | 220 |
Dirac P.A.M. — The Principles of Quantum Mechanics | 258 |
Carroll R.W. — Mathematical physics | 57 |
Bransden B., Joachain C. — Physics of Atoms and Molecules | 58, 141 |
Podgorsak E. — Radiation Physics for Medical Physicists | 83 |
Gould H., Tobochnik J., Christian W. — An introduction to computer simulation methods | 212, 250—251, 274, 430—433, 690 |
McGuire J.H. — Electron correlation dynamics in atomic collisions | 140 |
Jeffreys H. — Theory of probability | 24 |
Atkins P.W., Friedman R.S. — Molecular Quantum Mechanics | 18 |
Leighton R.B. — Principles of Modern Physics | 93 |
HarrisR. — Nonclassical physics: beyond Newton's view | 98, 110, 111, 123, 146, 156, 160, 234 |
Behnke H., Bachmann F., Fladt K. — Fundamentals of mathematics. Volume III. Analysis | 95 |
Greiner W. — Relativistic quantum mechanics. Wave equations | 148, 168 |
Bates D.R. — Quantum Theory. I. Elements | 44 |
Hartmann A.K., Rieger H. — Optimization Algorithms in Physics | 330 |
ter Haar D. — Elements of Statistical Mechanics | 216 |
Cercignani C. — Rarefied Gas Dynamics | 2, 3, 5, 7, 11, 16, 31, 33 117, 120, 207, 209 |
Feynman R., Leighton R., Sands M. — Lectures on Physics 2 | I-6-8 f |
Krane K.S. — Introductory nuclear physics | 12 |
Lipparini E. — Modern many-particle physics: atomic gases, quantum dots and quantum fluids | 175, 177, 189 |