Call number:
MOP 45315(4) / Mitte
In:
Progress in optics
Description / Table of Contents:
CONTENTS: CHAPTER I. HIGHER ORDER ABERRATION THEORY. - 1. INTRODUCTION. - 2. MODERN FOKMULATION OF SCHWARZSCHILD'S ABERRATION THEORY. - 3. THE SCHWARZSCHILD-SMITH ABERRATION COEFFICIENTS. - 4. THE INTRINSIC COEFFIClENTS OF A REFRACTING SURFACE. - 5. THE HERZBERGER ABERRATION COEFFICIENTS. - REFERENCES. - CHAPTER II. APPLICATIONS OF SHEARING INTERFEROMETRY. - 1. INTRODUCTION. - 2. EXAMINATION OF OPTICAL COMPONENTS. - 3. STUDIES OF ILLUMINATION PROPERTIES. - 4. EXAMINATION OF LARGE TRANSPARENT OBJECTS. - 5. STUDIES OF PHYSICO-CHEMICAL PHENOMENA IN LIQUIDS. - 6. EXAMINATION OF MICROSCOPIC OBJECTS. - REFERENCES. - CHAPTER III. SURFACE DETERIORATION OF OPTICAL GLASSES. - 1. INTRODUCTION. - 2. SOME OBSERVATIONS ON CORROSION OF GLASS BY SOLUTIONS. - 3. CRYSTALLITES GROWN ON THE GLASS SURFACE. - 4. STRUCTURE AND PROPERTIES OF THE AOYAKE LAYER. - 5. CONCLUSION. - REFERENCES. - CHAPTER IV. OPTICAL CONSTANTS OF THIN FILMS. - 1. OPTICAL CONSTANTS AND STRUCTURE OF TRANSPARENT THIN FILMS. - 2. OPTICAL CONSTANTS OF ABSORBING THIN FILMS. - ACKNOWLEDGEMENT. - REFERENCES. - CHAPTER V. THE MIYAMOTO-WOLF DIFFRACTION WAVE THE HISTORY OF THE DIFFRACTION WAVE SECTION I. THE SCALAR DIFFRACTION THEORY. - 1. THE HELMHOLZ-HUYGENS PRINCIPLE. - 2. DIFFRACTION WAVE FOR AN ARBITRARY INCIDENT WAVE. - 3. THE MIYAMOTO-WOLF DERIVATION OF THE VECTOR POTENTIAL W(P, Q). - 4. SIMPLE DERIVATION OF THE VECTOR POTENTIAL W(P, Q). - 5. VECTOR POTENTIAL W(P, Q) IN CASE WHERE THE SOLUTION U(Q) SATISFIES THE SOMMERFELD CONDITION AT INFINITY. - 6. A GEOMETRIC DERIVATION OF THE VECTOR POTENTIAL W(P, Q). - 7. TWO FURTHER REPRESENTATIONS OF THE VECTOR POTENTIAL W(P, Q). - 8. VECTOR POTENTIALS FOR BOUNDED SPACES. - 9. THE TWO-DIMENSIONAL HELMHOLTZ EQUATION. - 10. PHYSICAL PROPERTIES OF THE VECTOR POTENTIAL W(P, Q) AND OF THE CORRESPONDING DIFFRACTION WAVE. - 11. APPROXIMATE FORMULAE FOR THE VECTOR POTENTIAL W(P, Q). - 12. REFLECTION CONES. - 13. DIFFRACTION WAVE FOR THE SCALAR WAVE EQUATION. - SECTION II. DIFFRACTION THEORY OF ELECTROMAGNETIC AND DIRAC-ELECTRON WAVES. - 1. TENSOR POTENTIALS OF ELECTROMAGNETIC FIELDS DERIVED USING THE LORENTZ-LARMOR PRINCIPLE. - 2. TENSOR POTENTIALS OF THE ELECTROMAGNETIC FIELDS DERIVED FROM KOTTLER'S FORMULATION OF THE HUYGENS PRINCIPLE. - 3. DIFFRACTION WAVE IN THE KIRCHHOFF THEORY OF DIRAC-ELECTRON WAVES. - CONCLUSION. - REFERENCES. - CHAPTER VI. ABERRATION THEORY OF GRATINGS AND GRATING MOUNTINGS. - 1. INTRODUCTION. - 2. ABERRATION TYPES. - 3. FIRST ORDER PROPERTIES OF CONCAVE GRATINGS. - 4. PROPERTIES OF CONCAVE GRATINGS DEPENDENT ON TERMS OF THE FOURTH DEGREE IN THE GRATING COORDINATES. - 5. THE NEWER MOUNTINGS OF THE CONCAVE GRATING. - 6. PLANE GRATING MOUNTINGS. - 7. NON-SPHERICAL GRATINGS AND NON-LINEAR RULINGS. - 8. ABERRATION TOLERANCES. - REFERENCES. - CHAPTER VII. DIFFRACTION AT A BLACK SCREEN PART I: KIRCHHOFF'S THEORY. - 1. INTRODUCTION. - 2. THE FIRST SALTUS PROBLEM. - 3. THE SECOND SALTUS PROBLEM. - 4. CONCLUDING REMARKS. - 5. MATHEMATICAL APPENDIX
Type of Medium:
Monograph available for loan
Pages:
343 S.
Location:
MOP - must be ordered
Branch Library:
GFZ Library
