Classical Optics and its Applications

Masud Mansuripur received a Bachelor of Science degree in Electrical Engineering from Arya-Mehr University of Technology in Tehran, Iran (1977), a Master of Science in Electrical Engineering from Stanford University (1978), a Master of Science in Mathematics from Stanford University (1980), and a Ph.D. in Electrical Engineering from Stanford University (1981). He has been Professor of Optical Sciences at the University of Arizona since 1988. His areas of research include: optical data storage, optical signal processing, magneto-optical properties of thin magnetic films, radiation pressure, interaction of light with sub-wavelength structures, and the optical and thermal characterization of thin films and stacks. A Fellow of the Optical Society of America, he has published more than 250 papers in various technical journals, holds eight patents, has given numerous invited talks at international scientific conferences, and has been a contributing editor of Optics & Photonics News, the magazine of the Optical Society of America. Professor Mansuripur's published books include Introduction to Information Theory (1987) and The Physical Principles of Magneto-optical Recording (1995).

Preface; Introduction; 1. Abbe's sine condition; 2. Fourier optics; 3. Effect of polarization on diffraction in systems of high numerical aperture; 4. Gaussian beam optics; 5. Coherent and incoherent imaging; 6. First-order temporal coherence in classical optics; 7. The Van Cittert-Zernike theorem; 8. Partial polarization, Stokes parameters, and the Poincarè Sphere; 9. Second-order coherence and the Hanbury Brown–Twiss experiment; 10. What in the world are surface plasmons?; 11. Surface plasmon polaritons on metallic surfaces; 12. The Faraday effecy; 13. The magneto-optical Kerr effect; 14. The Sagnac interferometer; 15. Fabry-Perot etalons in polarized light; 16. The Ewald-Oseen extinction theorem; 17. Reciprocity in classical Linear optics; 18. Optical pulse compression; 19. The uncertainty principle in classical optics; 20. Omni-directional dielectric mirrors; 21. Optical vortices; 22. Geometric-optical rays, Poynting's vector, and field momenta; 23. Doppler shift, stellar aberration, and convection of light by moving Media; 24. Diffraction gratings; 25. Diffractive optical elements; 26. The talbot effect; 27. Some quirks of total internal reflection; 28. Evanescent coupling; 29. Internal and external conical refraction; 30. Transmission of light through small elliptical apertures; 31. The method of Fox and Li; 32. The beam propagation method; 33. Launching light into a Fiber; 34. The optics of semiconductor diode lasers; 35. Michelson's dtellar interferometer; 36. Bracewell's interferometric telescope; 37. Scanning optical microscopy; 38. Zernike's method of phase contrast; 39. Polarization microscopy; 40. Nomarski's differential interference contrast microscope; 41. The Van Leeuwenhoek microscope; 42. Projection photolithography; 43. Interaction of light with subwavelength structures; 44 The Ronchi test; 45. The Shack-Hartmann Wavefront sensor; 46. Ellipsometry; 47. Holography and holographic interferometry; 48. Self-focusing in non-linear optical media; 49. Spatial optical solitons; 50. Laser-induced heating of multilayers; Index.