Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 5 Laser-Fiber Connection. Content Launching optical power into a fiber Fiber-to-Fiber coupling Fiber Splicing and connectors.

Published byHarold Perkins Modified over 9 years ago

Similar presentations

Presentation on theme: "Chapter 5 Laser-Fiber Connection. Content Launching optical power into a fiber Fiber-to-Fiber coupling Fiber Splicing and connectors."— Presentation transcript:

1 Chapter 5 Laser-Fiber Connection

2 Content Launching optical power into a fiber Fiber-to-Fiber coupling Fiber Splicing and connectors

3 Coupling Efficiency [5-1] SourceOptical Fiber

4 Radiance (Brightness) of the source B= Optical power radiated from a unit area of the source into a unit solid angle [watts/(square centimeter per stradian)]

5 Surface emitting LEDs have a Lambertian pattern: [5-2]

6 Edge emitting LEDs and laser diodes radiation pattern For edge emitting LEDs, L=1 [5-3]

7 Power Coupled from source to the fiber [ 5-4]

8 Power coupled from LED to the Fiber [5-5]

9 Power coupling from LED to step-index fiber Total optical power from LED: [5-6] [5-7]

10 Equilibrium Numerical Aperture

11 Examples of possible lensing schemes used to improve optical source-to-fiber coupling efficiency

12 Laser diode to Fiber Coupling

13 Fiber-to-Fiber Joint Fiber-to-Fiber coupling loss: Low loss fiber-fiber joints are either: 1- Splice (permanent bond) 2- Connector (demountable connection) [5-8]

14 Different modal distribution of the optical beam emerging from a fiber lead to different degrees of coupling loss. a) when all modes are equally excited, the output beam fills the entire output NA. b) for a steady state modal distribution, only the equilibrium NA is filled by the output beam.

15 Mechanical misalignment losses Lateral (axial) misalignment loss is a dominant Mechanical loss. [5-9]

16 Longitudinal offset effect Losses due to differences in the geometry and waveguide characteristics of the fibers [5-10] E & R subscripts refer to emitting and receiving fibers.

17 Experimental comparison of Loss as a function of mechanical misalignment

18 Fiber end face Fiber end defects

19 Fiber splicing Fusion Splicing

20 V-groove optical fiber splicing

21 Optical Fiber Connectors Some of the principal requirements of a good connector design are as follows: 1- low coupling losses 2- Interchangeability 3- Ease of assembly 4- Low environmental sensitivity 5- Low-cost and reliable construction 6- Ease of connection

22 Connector Return Loss

Download ppt "Chapter 5 Laser-Fiber Connection. Content Launching optical power into a fiber Fiber-to-Fiber coupling Fiber Splicing and connectors."

Similar presentations

Chapter Twenty-Four: Fiber Optics

Chapter Twenty-Four: Fiber Optics
Session 4: Termination and Splices. 2 FO Connectors Specifications Specifications Loss Repeatability Environment (temp, humidity, vibration, etc.) Reliability.

Session 4: Termination and Splices. 2 FO Connectors Specifications Specifications Loss Repeatability Environment (temp, humidity, vibration, etc.) Reliability.
Optical sources Lecture 5.

Optical sources Lecture 5.
Chapter 8 Optical fiber splicing Attenuation curve for silica optical fiber.

Chapter 8 Optical fiber splicing Attenuation curve for silica optical fiber.
Transmisi Optik Pertemuan 10 Matakuliah: H0122 / Dasar Telekomunikasi Tahun: 2008.

Transmisi Optik Pertemuan 10 Matakuliah: H0122 / Dasar Telekomunikasi Tahun: 2008.
©UCL 2004 17 TH IEEE/LEOS Conference Puerto Rico, 7-11 th November, 2004 Multimode Laterally Tapered Bent Waveguide Ioannis Papakonstantinou, David R.

©UCL TH IEEE/LEOS Conference Puerto Rico, 7-11 th November, 2004 Multimode Laterally Tapered Bent Waveguide Ioannis Papakonstantinou, David R.
Fiber Optics BASIC FIBER OPTIC LINK.

Fiber Optics BASIC FIBER OPTIC LINK.
Optical Fiber Basics Part-3

Optical Fiber Basics Part-3
Tutorial on optical fibres F. Reynaud IRCOM Limoges Équipe optique F. Reynaud IRCOM Limoges Équipe optique Cargèse sept 2002.

Tutorial on optical fibres F. Reynaud IRCOM Limoges Équipe optique F. Reynaud IRCOM Limoges Équipe optique Cargèse sept 2002.
Fiber Optics Defining Characteristics: Numerical Aperture Spectral Transmission Diameter.

Fiber Optics Defining Characteristics: Numerical Aperture Spectral Transmission Diameter.
Fiber-Optic Communications James N. Downing. Chapter 5 Optical Sources and Transmitters.

Fiber-Optic Communications James N. Downing. Chapter 5 Optical Sources and Transmitters.
Fiber-Optic Communications

Fiber-Optic Communications
Introduction to Fiber Optics

Introduction to Fiber Optics
Fiber Optic Light Sources

Fiber Optic Light Sources
Chapter 10 Optical fiber measuring instruments and testing single-mode fiber networks.

Chapter 10 Optical fiber measuring instruments and testing single-mode fiber networks.
© DIAMOND SA / 09-01 / 1 Performance & Intermateability Comparison between different ferrule technologies.

© DIAMOND SA / / 1 Performance & Intermateability Comparison between different ferrule technologies.
Chapter 8 Basic System Design.

Chapter 8 Basic System Design.
Fundamental of Fiber Optics. Optical Fiber Total Internal Reflection.

Fundamental of Fiber Optics. Optical Fiber Total Internal Reflection.
Light Sources for Optical Communications EE 8114 Xavier Fernando RCL Lab.

Light Sources for Optical Communications EE 8114 Xavier Fernando RCL Lab.
Chapter 4 Photonic Sources.

Chapter 4 Photonic Sources.

Similar presentations

Ads by Google