This book was designed to encourage the adoption of simple matrix methods in teaching optics at the undergraduate and technical college level. Although these methods have been somewhat neglected in the past, the authors point to the economy and elegance with which, for a linear system, a wealth of input-output relations can be expressed by a single matrix. Moreover, the field of optics has been enormously enriched by contributions from other disciplines, such as microwave physics and electrical engineering, which employ matrix methods.
Because it is an introductory text, this work requires little prior knowledge and is confined to just two topics: paraxial imaging and polarization. For those with no previous acquaintance with matrix algebra, Chapter One introduces basic ideas of rectangular matrix arrays and gives the rules for adding them and for forming matrix products. Subsequent chapters deal with paraxial imaging properties of a centered optical system, optical resonators and laser beam propagation, matrices in polarization optics, and propagation of light through crystals.
Six helpful appendixes deal with such topics as aperture properties of centered lens systems, matrix representation of centering and squaring errors, and derivation of Mueller and Jones matrices. A bibliography completes this accessible guide to methods that will be of great assistance to students and workers not only in optics, but in such areas as laser engineering, optoelectronics, mechanical engineering, and more. 1975 edition.
By:
A. Gerrard, J. M. Burch, A. Gerard Imprint: Dover Publications Inc. Country of Publication: United States Edition: New edition Dimensions:
Height: 215mm,
Width: 135mm,
Spine: 18mm
Weight: 380g ISBN:9780486680446 ISBN 10: 0486680444 Series:Dover Books on Physics Pages: 384 Publication Date:15 February 2012 Audience:
General/trade
,
ELT Advanced
Format:Paperback Publisher's Status: Unspecified
"PREFACE CHAPTER I Introduction to matrix calculations I.1 Introductory discussion I.2 Matrix multiplication I.3 Null matrices I.4 Unit matrices I.5 Diagonal matrices I.6 Multiple products I.7 Matrix addition and subtraction I.8 Transpose matrices I.9 Determinants I.10 Division of matrices and matrix inversion I.11 Matrix diagonlaization I.12 Eigenvalues and eignevectors of a 2 x 2 unimodular matrix CHAPTER II Matrix methods in paraxial optics II.1 Introductory discussion II.2 Ray-transfer matrices II.3 The translation matrix T II.4 The refraction matrix R II.5 The ray-transfer matrix for a system II.6 Derivation of properties of a system from its matrix II.7 Illustrative problems II.8 Experimental determination of the matrix elements of an optical system II.9 Locating the cardinal points of a system II.10 Further problems II.11 Extension of ray-transfer method to reflecting systems CHAPTER III Optical resonators and laser beam propagation III.1 Review of results obtained for paraxial imaging systems III.2 Description of wave propagation in terms of geometrical optics III.3 ""Resolving power, etendue and the space-bandwidth product"" III.4 Marix representation of an optical resonator III.5 The distinction between stable and unstable resonators III.6 Propagation of a Gaussian beam and its complex cruvature parameter III.7 Predicting the output of a laser oscillator III.8 Application of the ABCD rule to mode-matching problems III.9 Ray-transfer matrices for distributed lens-like media III.10 Illustrative problems CHAPTER IV Matrices in polarization optics IV.1 Polarized light - its production and analysis IV.2 The Stokes parameters for specifying polarization IV.3 Use of the Mueller calulus for transforming a Stokes column IV.4 Experimental determination of the elements of a Mueller matrix or a Stokes column IV.5 Use of the Jones calculus for transforming a Maxwell column IV.6 Experimental determination of the elements of a Jones matrix or a Maxwell column IV.7 Illustrative problems soled by Mueller calculus and by Jones calculus CHAPTER V Propagation of light through crystals V.1 Introductory discussion V.2 Expression of vector operations in matrx form V.3 Dielectric properties of an anisotropic medium V.4 Propagation of plane waves in a uniaxial crystal V.5 Huygens wavelets in a uniaxial crystal APPENDIXES A Aperature properties of centred lens systems B Matrix representation of centring and squaring errors C Statistical derivation of the Stokes parameters D Derivation of Mueller matrices E Derivation of Jones matrices F Connection between Jones and Mueller calculi BIBLIOGRAPHY AND CONCLUSION INDEX"
