Physics 42200 Waves & Oscillations Lecture 41 Review Spring 2013 Semester Matthew Jones
Final Exam Date:Tuesday, April 30 th Time:1:00 to 3:00 pm Room: Phys 112 You can bring two double-sided pages of notes/formulas. Bring something to write with. You shouldn t need a calculator.
Polarization Today s Review of Optics Reflection and transmission Linear and circular polarization Stokes parameters/jones calculus Geometric optics Laws of reflection and refraction Spherical mirrors Refraction from one spherical surface Thin lenses Optical systems (multiple thin lenses, apertures, stops) Thick lenses, ray tracing, transfer matrix Aberrations
Wednesday s Review of Optics Interference Double-slit experiments Fresnel s double-mirror, double-prism, Lloyd s mirror Thin films, Michelson interferometer Multiple beam interferometry, Fabry-Perot interferometer Diffraction Fraunhofer diffraction Single-slit, multiple-slit diffraction Diffraction gratings Fresnel diffraction
Polarization General representation:, = cos( + ) Light intensity: =, = = = Linear polarization: is constant Circular polarization Orthogonal components out of phase by = ±, = ( cos ± " sin ) Right circular polarization: + Left circular polarization: - Degree of polarization: % = & /( & + ( )
Polarization Make sure you understand the following geometry: * is the component of that is perpendicular to plane of incidence is the component of that is parallel to plane of reflection In this example, only has an * component ( = 0) while,only has a, component (, * = 0).
Polarization Fresnel equations: -. * = sin /. / 0 sin /. + / 0 -. = tan /. / 0 tan /. + / 0 4 = ( 6/( 7 89: ; 5 5 * 89: ; 5 <; 4 4 = =>8 ; 5 89: ; 4 5 89: ; 5 <; 4 =>8 ; 5?; 4 You have to calculate / 0 using Snell s law.
Polarization Brewster s angle, / : /. + / 0 = 90 B 0when /. / (polarization by reflection) When light is at normal incidence, /. = / 0 = 0and = 0 B * = -. * = D E D D E + D * = 0 = 2D E. D * E + D When D E < D, B * = 1(phase changes by I).
Stokes Parameters Stokes selected four filters Each filter transmits exactly half the intensity of unpolarized light E J Unpolarized: filters out ½ the intensity of any incident light. Linear: transmits only horizontal component Linear: transmits only light polarized at 45 = 2 E = 2 E 2 = 2 2 J = 2 J 2 Circular: transmits only R- polarized light Stokes parameters
Stokes Parameters The Stokes parameters that describe a mixture of polarized light components is the weighted sum of the Stokes parameters of each component. Example: Two components 40% has vertical linear polarization 60% has right circular polarization Calculate Stokes parameters: 1 = E 1 = 0.4 0 J 0 Degree of polarization: + 0.6 1 0 0 1 = 1 0.4 0 0.6 % = E + + J = 0.4 + (0.6 ) = 0.72
Mueller Matrices = E O = P J Example: right circular polarizer Incident unpolarized light = 1, E = 0, = 0, J = 0 Emerging circular polarization Mueller matrix: = 1 2, E = 0, = 0, J = 1 2 P = 1 2 1 0 0 1 0 0 0 0 0 0 0 0 1 0 0 1
Jones Calculus Applies to, not intensity Light must be coherent Electric field vectors: Q (, ) = Q cos + R Q S (, ) = S " cos + R S Jones vector: T = QU.V W S U.V X = 1 Q + S Q S U.Z
Jones Calculus Examples: Horizontal linear polarization: Q = 1 0 Vertical linear polarization: S = 0 1 Linear polarization at 45 : \] = E 1 1 Right circular polarization: ^ = E 1 U?./ = E Left circular polarization: ` = E 1 U <./ = E 1 _ 1 _
Jones Calculus and are related by a 2x2 matrix (the Jones matrix): = b If light passes through several optical elements, then = b ( b b E Examples: Transmission through an optically inactive material: b = 1 0 0 1 Rotation of the plane of linear polarization (eg, propagation through a sugar solution) b = cos d sin d sin d cos d
Geometric Optics Law of reflection: / E O = / E Law of refraction (Snell s law): D E sin / E = D sin / Make sure you understand the geometry and sign conventions for lenses and mirrors: E e + E eo = E f where g = - In this diagram, g, B, h and h are all positive.
Spherical Refracting Surfaces j D E i D E h l h. D > D E + D = D D E h l h. m All quantities are positive here. j i h l h. D E + D = D D E h l h. m D E D > D E (same formula but now R<0)
Thin Lenses 1 + 1 1 = D h l h n 1 1 = 1. m E m g o p = h. /h l (transverse magnification) You should be able to calculate image positions and draw ray diagrams: Object F o F i Optical axis Image
Multiple Thin Lenses v le v.e v l v. j h le g E g E u g g h le Two techniques: Calculate position of intermediate image formed by first lens, then the final image formed by second lens Use front/back focal lengths: Front focal length: f. f. l. = f 6(s?f 7 ) s?(f 6 <f 7 ) Back focal length: b. f. l. = g (u g E ) u (g E + g )
Two approaches: Thick Lenses Calculate positions of intermediate images formed by each spherical refracting surface Calculate positions of principle planes: Focal length: E f = D 1 E ^6 E^7 Principal planes: w E = f (?E s (^7 + (?E s (^6^7, w = f (?E s (^6
Ray Tracing Ray vector: B. = D.d. x. Transfer matrix: y = 1 0 u/d 1 Refraction matrix: m = 1 z 0 1, z = ( 4?( 5 ^ Mirror matrix: P = 1 2D/m 0 1 x E d E x
Aberrations Images usually suffer from some degree of distortion Seidel s primary aberrations Spherical Coma Astigmatism Field curvature Distortion Chromatic aberrations
Typical Exam Questions An optical system consists of a horizontal linear polarizer, a solution of dextrorotary sugar, which rotates the plane of polarized light by +45, followed by a left circular polarizing filter. (a) Write the Mueller matrices for each component (b) Calculate the intensity of transmitted light if the incident light is unpolarized (c) Calculate the intensity of transmitted light if the incident light is left circular polarized (d) Is the system symmetric? That is, is the intensity of transmitted light the same if the paths of all light rays are reversed?
Typical Exam Questions An optical system consists of a thin lens with focal length g and a concave spherical mirror with radius m as shown: u (a) Where is the effective focal point of this combination of optical elements? (b) What is the transverse magnification?
Typical Exam Questions Answer one, or the other, but not both (a) Describe two types of optical aberration and techniques that can be used to minimize them. (b) Compare and contrast the assumptions and main features of Fraunhoferand Fresnel diffraction. Under what circumstances is Fraunhoferdiffraction a special case of Fresnel diffraction?