Differential Equations and Mathematical Biology
Autor D. S. Jonesen Limba Engleză Paperback – 24 ian 2012
Preț: 383.53 lei
Nou
Puncte Express: 575
Preț estimativ în valută:
73.41€ • 76.30$ • 60.81£
73.41€ • 76.30$ • 60.81£
Carte tipărită la comandă
Livrare economică 05-19 februarie 25
Preluare comenzi: 021 569.72.76
Specificații
ISBN-13: 9789401159722
ISBN-10: 9401159726
Pagini: 352
Ilustrații: XII, 340 p.
Dimensiuni: 155 x 235 x 18 mm
Greutate: 0.49 kg
Ediția:Softcover reprint of the original 1st ed. 1983
Editura: SPRINGER NETHERLANDS
Colecția Springer
Locul publicării:Dordrecht, Netherlands
ISBN-10: 9401159726
Pagini: 352
Ilustrații: XII, 340 p.
Dimensiuni: 155 x 235 x 18 mm
Greutate: 0.49 kg
Ediția:Softcover reprint of the original 1st ed. 1983
Editura: SPRINGER NETHERLANDS
Colecția Springer
Locul publicării:Dordrecht, Netherlands
Public țintă
ResearchCuprins
1 Introduction.- 1.1 Population growth.- 1.2 Administration of drugs.- 1.3 Cell division.- 1.4 Differential equations with separable variables.- 1.5 General properties.- 1.6 Equations of homogeneous type.- 1.7 Linear differential equations of the first order.- Notes.- Exercises.- 2 Linear ordinary differential equations with constant coefficients.- 2.1 Introduction.- 2.2 First-order linear differential equations.- 2.3 Linear equations of the second order.- 2.4 Finding the complementary function.- 2.5 Determining a particular integral.- 2.6 Forced oscillations.- 2.7 Differential equations of order n.- 2.8 Simultaneous equations of the first order.- 2.9 Replacement of one differential equation by a system.- 2.10 The general system.- 2.11 The fundamental system.- 2.12 Matrix notation.- 2.13 Initial and boundary value problems.- 2.14 Solving the inhomogeneous differential equation.- Exercises.- 3 Modelling biological phenomena.- 3.1 Introduction.- 3.2 Heart beat.- 3.3 Blood flow.- 3.4 Nerve impulse transmission.- 3.5 Chemical reactions.- 3.6 Predator-prey models.- Notes.- Exercises.- 4 First-order systems of ordinary differential equations.- 4.1 Existence and uniqueness.- 4.2 Epidemics.- 4.3 The phase plane.- 4.4 Local stability.- 4.5 Stability.- 4.6 Limit cycles.- 4.7 Forced oscillations.- 4.8 Appendix: existence theory.- Exercises.- 5 Mathematics of heart physiology.- 5.1 The local model.- 5.2 The threshold effect.- 5.3 The phase plane analysis and the heart beat model.- 5.4 Physiological considerations of the heart beat cycle.- 5.5 A model of the cardiac pacemaker 139 Notes.- Exercises.- 6 Mathematics of nerve impulse transmission.- 6.1 Phase plane methods.- 6.2 Qualitative behaviour of travelling waves.- Notes.- Exercises.- 7 Chemical reactions.- 7.1 Wavefronts for theBelousov-Zhabotinskii reaction.- 7.2 Phase plane analysis of Fisher’s equation.- 7.3 Qualitative behaviour in the general case.- Notes.- Exercises.- 8 Predator and prey.- 8.1 Catching fish.- 8.2 The effect of fishing.- 8.3 The Volterra-Lotka model.- Exercises.- 9 Partial differential equations.- 9.1 Characteristics for equations of the first order.- 9.2 Another view of characteristics.- 9.3 Linear partial differential equations of the second order.- 9.4 Elliptic partial differential equations.- 9.5 Parabolic partial differential equations.- 9.6 Hyperbolic partial differential equations.- 9.7 The wave equation.- 9.8 Typical problems for the hyperbolic equation.- 9.9 The Euler-Darboux equation.- Exercises.- 10 Evolutionary equations.- 10.1 The heat equation.- 10.2 Separation of variables.- 10.3 Simples evolutionary equations.- 10.4 Comparison theorems.- Notes.- Exercises.- 11 Problems of diffusion.- 11.1 Diffusion through membranes.- 11.2 Energy and energy estimates.- 11.3 Global behaviour of nerve impulse transmissions.- 11.4 Global behaviour in chemical reactions.- Notes.- Exercises.- 12 Catastrophe theory and biological phenomena.- 12.1 What is a catastrophe?.- 12.2 Elementary catastrophes.- 12.3 Biology and catastrophe theory.- Exercises.- 13 Growth of tumours.- 13.1 Introduction.- 13.2 A mathematical model of tumour growth.- 13.3 A spherical tumour.- Notes.- Exercises.- 14 Epidemics.- 14.1 The Kermack-McKendrick model.- 14.2 Vaccination.- 14.3 An incubation model.- 14.4 Spreading in space.- Exercises.- Answers to exercises.