PHY 1001
praneeth kumarにより
1. PROPAGATION OF EM WAVES IN OPTICAL FIBRE
1.1. Light propagation through fibres
1.2. Acceptance angle
1.3. Numerical aperature
1.4. Types of fibre
2. LASER PRINCIPLE AND ENGINEERING APPLICATIONS
2.1. Laser Characteristics
2.2. Einstein's coefficient
2.3. Absorption and emission
2.3.1. Numericals
2.3.2. Derivation
2.4. Population Inversion
2.5. 2,3,4 level laser
2.6. Pumping schemes
2.7. Gain coefficient
2.8. Components of LASERs
2.9. Different LASERs
2.9.1. Nd-YAG
2.9.2. He-Ne
2.9.3. CO2
2.9.4. Dye
3. NANO PHYSICS
3.1. Intro to nano material
3.2. Moore's law
3.3. Properties of nano materials
3.4. Quantum well, wire, dot
3.5. Nano Tube
3.5.1. Properties
3.5.2. Applications
4. EM THEOY AND ITS APPLICATIONS
4.1. Pyhsics of divergence
4.2. Gradient and curl
4.3. Surface and Volume Integral
4.4. Maxwell Equations
4.5. Wave Equation
4.6. EM waves
4.7. Phase velocity
4.8. Group Velocity
4.9. Wave Guide
5. SPECIAL THEORY OF RELATIVITY
5.1. Galilean relativity
5.2. Postulate of special theory of relativity
5.3. Frame of reference
5.4. Simultaneity
5.5. Length contraction and time Dilation
6. INTRODUCTION TO MODERN PHYSICS
6.1. Compton effect
6.1.1. numerical
6.1.2. derivation
6.2. Planck's concept
6.2.1. Derivation
6.3. matter waves
6.3.1. Properties
6.4. Davission Germer experiment
6.4.1. e
6.5. Hesenberg uncertainity principle
6.6. wave function
6.7. Schrodinger equation
6.7.1. derivation
6.7.2. numerical
7. APP OF QUANTUM PHYSICS
7.1. Praticle in a 1-D box
7.1.1. eigen values
7.2. 3-D Analysis
7.3. Tunelling effect
7.3.1. numericals
7.4. Scanning Tunneling Microscope
8. OPTOELECTRONIC DEVICES AND APPLICATIONS OF OPTICAL FIBRES
8.1. LASER diode
8.2. Detectors
8.2.1. Photo electron
8.2.2. PN
8.2.3. PIN