Lecture 1 - Introduction to waves, 1D wave equation and its solutions
Lecture 2 - 1D Light waves
Lecture 3 - Characteristics of light waves - amplitude, absolute phase, wavelenght and frequency
Lecture 4 - Phase, Phase velocity and Phase delay
Lecture 5 - Complex notation for the description light waves and superposition
Lecture 6 - Maxwell's equations to the 3D wave equation and its solutions
Lecture 7 - Recap of Week 1
Lecture 8 - 3D wave equation and plane waves
Lecture 9 - Complex notation for Electric fields, Superposition and interference
Lecture 10 - Fabry-Perot inteferometer and it transmittance
Lecture 11 - Physical interpretation of FP transmittance
Lecture 12 - Recap of Fabry-Perot modes
Lecture 13 - Free spectral range of a Fabry-Perot etalon
Lecture 14 - Resonator modes and optical pulses - insight
Lecture 15 - Table - Top Coherent and Incoherent Imaging
Lecture 16 - Recap of Etalon free spectral range
Lecture 17 - Line width and finesse of an etalon
Lecture 18 - Actual resonator modes
Lecture 19 - Resonator configurations and stability
Lecture 20 - Recap of optical resonators
Lecture 21 - Introduction of light pulses
Lecture 22 - Complex amplitude, Gaussian pulse
Lecture 23 - Recap of light pulses
Lecture 24 - Introduction of Fourier Transforms
Lecture 25 - Tutorial 1
Lecture 26 - Motivating Fourier Transforms
Lecture 27 - Fourier Transform Properties
Lecture 28 - Frequency domain electric field
Lecture 29 - Recap of Fourier transform properties
Lecture 30 - Frequency domain description of pulses
Lecture 31 - Spectral Phase
Lecture 32 - Recap of spectral phase
Lecture 33 - Instantaneous Frequency and group delay
Lecture 34 - Phase wrapping, blanking, and Tayor series expansion
Lecture 35 - Recap of instantaneous frequency, phase wrapping, and phase blanking
Lecture 36 - Frequency domain phase expansion, group delay dispersion
Lecture 37 - Absolute Phase
Lecture 38 - Recap of concepts + discussion
Lecture 39 - Absolute Phase (revisited)
Lecture 40 - Carrier envelope phase, frequency comb
Lecture 41 - Discussion
Lecture 42 - Recap of concepts
Lecture 43 - First order phase
Lecture 44 - Second order phase
Lecture 45 - Recap of first order and second order phase
Lecture 46 - Chirped pulse: Instantaneous frequency and Fourier transform
Lecture 47 - Group delay, nonlinearly chirped pulse
Lecture 48 - Recap of chirped pulses
Lecture 49 - Quadratic chirp pulses
Lecture 50 - Higher order spectral phase
Lecture 51 - Recap and discussion on higher order phase
Lecture 52 - Relative importance of intensity and phase
Lecture 53 - Pulse propagation through a medium
Lecture 54 - Recap of pulse propagation and pulse length
Lecture 55 - Discussion of RMS pulse width and uncertainty principle
Lecture 56 - Time-bandwidth product
Lecture 57 - Recap of previous module
Lecture 58 - Introduction of Lorentz Oscillator Model
Lecture 59 - Effect of matter on light
Lecture 60 - Recap of Lorentz oscillator, Polarization tensor
Lecture 61 - Dynamics of electrons in the Lorentz oscillator
Lecture 62 - Solving the inhomogeneous wave equation
Lecture 63 - Inhomogeneous wave equation, absorption coefficient, refractive index
Lecture 64 - Nonlinear response of matter
Lecture 65 - Origin of nonlinear optical effects
Lecture 66 - Wave equation in an inert gas
Lecture 67 - Perturbation theory and second harmonics
Lecture 68 - Numerical simulation strategy
Lecture 69 - Atoms in the presence of fields
Lecture 70 - Ionization models
Lecture 71 - Attosecond pulse generation and metrology
Lecture 72 - Nonlinear optics review
Lecture 73 - Nonlinear response of matter to light
Lecture 74 - Sum and difference frequency generation
Lecture 75 - Recap of sum and difference frequency generation, second harmonic generation
Lecture 76 - Generalized nonlinear effects, conservation laws in SHG
Lecture 77 - Phase matching in SHG, polarization dependent refractive index
