1. EE 5551 Fiber Optic Communications Fall 2008, Sun Tue Thr 1:00-2:00 pm EE343 Instructor: Yazan A Alqudah Office Location EE446 Phone: Ext 339332

2. EE 5551 An introductory Course to Fiber Optic Communications Gain general knowledge about the technology Why fiber optics What the pieces are Have essential understanding about components important to optical networking Characteristics Working principle Prepare for further in depth exploration and design

3. EE 5551 Course Goal: Familiar with basic concepts (carrier frequency, bandwidth, bit rate-distance, etc) and terminologies (DWDM, EDFA, etc) used in fiber optic communications technology Develop a general understanding of basic analog and digital signal sampling, transmission and receiving in communications Understanding the origin of loss and causes of various dispersion in optical fibers Understanding basic dielectric waveguides theory Develop an essential understanding of operation principles of fiber optic components( light sources, light detectors, light amplifier, modulators, and filters, etc) Familiarity with the trend and design consideration of fiber optic networks

4. Prerequisite Basic geometric optics, reflection, refraction and interference Continuous-time linear systems Solid state devices: principle of semiconductor p-n junctions, forward and inverse bias and light emitting process

5. Resources Text Book Optical Fiber Communications, Gerd Keiser, 3 th edition. McGraw-Hill Recommended References Fiber-Optic Communications Systems, Govind P. Agrawal, 2 nd ed., John Wiley & Sons, Inc. Fiber Optic Communications, Joseph C. Palais, 5 th ed., Pearson Prentice Hall. Optics, Eugene Hecht, 3 rd ed., Addision-Wesley 1998

6. Course Contents Introduction to fiber optics Light propagation in optical waveguide Critical components in optic fiber communications Fiber optic networks

7. Part I: Introduction to Fiber Optic Communications Objectives: – Describe in general the evolution of optical networks – Describe the operating principles of fiber optic systems; identify the capabilities and limitations – Get to know the system components such as laser, detectors, amplifiers, multiplexers, demultiplexers, and describe how they are used – Familiar with bandwidth, bit rate, fiber loss, and understanding sampling Contents covered – Development of fiber optics – Bandwidth and data transmission speed – Review basic geometrical optics

8. Part II: Light propagation in optical waveguides Learning objectives: – Describe various types of optical fibers – Explain fiber dispersion, attenuation and other properties – Explain the key features of optical fiber, which make them suited for long distance high speed communications – Explain how physical effects inside optical fiber can limit communications speeds and distances Contents to be covered – Analysis of light propagation in optical fiber – Fiber applications and types – Fiber attenuation, dispersion and nonlinear effects – Optic fiber manufacturing

9. Part IIIa. Critical Components: Transmitters and Receivers Learning objectives – Discuss light sources for fiber optic systems – Explain fiber optic transmitters – Explain fiber optic receivers and receiver sensitivity Contents to cover – Light sources: LEDs and lasers – Transmitters – Receivers and detectors

10. Part IIIb. Critical Components: Passive Components Learning objectives – Describe couplers and how they work – Discuss planar waveguides – Explain wavelength division multiplexers – Describe optical isolators – Explain dispersion compensators Contents to cover – Couplers and taps – Planar waveguides – Attenuators and filters – Wavelength-division multiplexers – Other passive components

11. Part IIIc. Critical Components: Active Components Learning objectives: – Understand operation principle of various active components: Modulators, switches, wavelength converters – Understand function and impact of fiber amplifiers Contents – Repeaters and regenerators – Modulators – Optical switches – Wavelength converters – Optical amplifiers

12. Fiber Optic Network Learning objectives – Explain how optical networks are evolving towards higher information rates, functionality, switch connectivity, metropolitan and local areas Contents to cover – Multiplexing technique, wavelength and time division – Fiber optic network architecture – Current trends in fiber optic networks

13. Grading Policy Homework, Quizzes ( in class, announced and unannounced), and attendance 10% Two in-class midterm exams50% (25% each) Final exam 40%