1. Introduction to Optical Electronics
Quantum (Photon) Optics (Ch 12)
Resonators (Ch 10)
Electromagnetic Optics (Ch 5)
Wave Optics (Ch 2 & 3)
Ray Optics (Ch 1)
Photons & Atoms (Ch 13)
Laser Amplifiers (Ch 14)
Lasers (Ch 15)
Photons in Semiconductors (Ch 16)
Semiconductor Photon Detectors (Ch 18)
Semiconductor Photon Sources (Ch 17)
Optics
Physics
Optoelectronics

2. Traveling Waves in a Planar-Mirror ResonatorU3 U2 U1
r = r1 r2 U0
r e-jU
r e-j + U0 U

3. Traveling Waves in a Planar-Mirror Resonatord
r1r2 e-j2 + E0 E
r1r2 e-j E

4. Modes of a System

5. Modes of a Lossy Resonator
For large F

6. Impact of Reflectivity (r) Imax held constant

7. Spectrum Analyzer
T = Transmittance

8. Optical Cavities Exercise 1.4-7 (PS 1)d R1 R2 M1 M2 or

9. Resonator Stability Diagramc d e -1 1
Symmetrical
Resonators g1 g2
Planar (R1 = R2 = ∞)
Symmetrical confocal (R1 = R2 = -d)
Symmetrical concentric (R1 = R2 = -d/2)
Confocal / planar (R1 = -d, R2 = ∞)
Concave / convex (R1 < 0, R2 > 0

10. The Gaussian Beam

11. Matching Gaussian Beam to Spherical Mirrorsd
R1 = R(z1)
Phase fronts
-R2 = R(z2) z1 z2

12. Exercise 9.2-1 Maximum Resonator Length for Confined Rays
Phase fronts R2 z1 z2
A resonator is constructed using two concave mirrors of radii 50 cm and 100 cm. Determine the maximum resonator length for which rays satisfy the confinement condition

13. Exercise 9.2-2: Matching Gaussian Beams to a Plano-Concave Resonatord R1 R2
z = 0 z2
Determine the following in terms of (d /R2):
Confinement Condition (stability)
Depth of Focus
Beam Radius at the waist and at each of the mirrors

14. Spherical-Mirror Resonators Hermite-Gaussian Modesz1 z2 d
Phase fronts

15. Exercise 9.2-3: Resonance Frequencies of a Confocal Resonator
A symmetrical confocal resonator has a length d = 30 cm, and the medium has refractive index n = 1. Determine the frequency spacing F and the displacement frequency ( / )F. Determine all the resonance frequencies that lie within the band 5 x 1014  2 x 109 Hz.