Optical Design for LED Solid State Lighting: A Guide

This document was uploaded by one of our users. The uploader already confirmed that they had the permission to publish it. If you are author/publisher or own the copyright of this documents, please report to us by using this DMCA report form.

Simply click on the Download Book button.

Yes, Book downloads on Ebookily are 100% Free.

Sometimes the book is free on Amazon As well, so go ahead and hit "Search on Amazon"

Light-emitting diodes (LEDs) are considered the most important light source of the 21st century owing to advantages of energy saving, long life, fast response, high colour performance, and environmental benefit. We believe that accurately understanding the light performances of LEDs and using them skilfully is an important capability for optical designers.


This book provides an overview of the light performance of LED SSL and can further effectively apply optical design to SSL at different levels. Optical Design for SSL is classified into four levels including LED die, package, component, and system. All approaches are aimed at teaching readers to precisely determine the spatial and chromatic light performance of an LED and increasing the optical utilization factor of an LED luminaire to achieve optical energy efficiency.


Recommended for optical designers, illumination designers, LED optical engineers, students - upper level undergraduate and graduates.


Key Features:


- Presents an essential guidebook for optical design in LED Lighting

- Includes thorough explanations of LED light performance and limitations

- Proposes four-level optical design in LED lighting

- Includes chapter summaries

- Provides a reader-friendly approach to ensure precision


Author(s): Ching-Cherng Sun, Tsung-Xian Lee
Series: IOP Series in Emerging Technologies in Optics and Photonics
Publisher: IOP Publishing
Year: 2022

Language: English
Pages: 218
City: Bristol

PRELIMS.pdf
Preface
Author biographies
Ching-Cherng Sun
Tsung-Xian Lee
CH001.pdf
Chapter 1 Introduction of LED solid-state lighting
1.1 The past, present, and future of LEDs
1.2 Working principle of LEDs
1.3 Luminous efficiency evaluation of LEDs
1.4 LED die and its package
1.5 Radiometry and photometry
1.6 Four-level optical designs and considerations
References
CH002.pdf
Chapter 2 Basic optics
2.1 Propagation of light
2.2 Complex representation of light waves
2.3 Huygens’ principle
2.4 The speed of light
2.5 Wavefront
2.6 Polarization
2.7 Fresnel equations of reflection
Total reflection
Total transmission
Example 2.1
2.8 Interaction between light and matter
Example 2.2
2.9 Basic principle of geometrical optics
2.10 Mirrors and lenses
Planar mirrors
Elliptical mirrors
Hyperbolic mirrors
Parabolic mirrors
Spherical mirrors
Spherical lenses
2.11 Prisms
Minimum deviation
Reflecting prisms
The right-angle prism
The Dove prism
The Porro prism
The penta prism
The rhomboid prism
2.12 Gaussian optics
Spherical refracting surface
2.13 Thin lens
2.14 Thick lens
2.15 Spherical mirror
2.16 Paraxial ray tracing
Example 2.3
Example 2.4
References
CH003.pdf
Chapter 3 LED die-level light extraction optics
3.1 Challenge in LED light extraction efficiency
3.1.1 Total internal reflection loss
3.1.2 Fresnel reflection loss
3.1.3 Material absorption loss
3.2 Effective solutions for LEE enhancement
3.2.1 Die shaping
3.2.2 Surface roughening/texturing
3.2.3 Patterned sapphire substrate
3.2.4 Photonics crystal
3.3 LED light extraction analytical method and simulation
3.4 Case studies of LEE simulation
3.5 Quantum photon recycling mechanism on LEE
3.6 Current crowding effect on LEE
3.7 Microstructure and light-scattering on LEE
References
CH004.pdf
Chapter 4 LED package-level primary optics
4.1 Optical considerations in LED packaging
4.2 Primary optics for high luminous efficiency
4.3 Primary optics to shape light distribution
4.4 Primary optics for low spatial color deviation
4.5 Phosphor modelling
References
CH005.pdf
Chapter 5 Light source modeling
5.1 Light source characteristics
5.2 The propagation fields
5.3 LED light source modelling
5.4 Case studies of light source modeling
References
CH006.pdf
Chapter 6 LED component-level secondary optics
6.1 Essential principle of optical flux transfer
6.2 Typical optical elements for secondary optics
6.3 High-directional LED illumination
6.4 Angular radiation extension by a diffuser
References
CH007.pdf
Chapter 7 LED system-level LED lighting optics
7.1 LED street/roadway lighting
7.2 LED headlamps
7.3 LED backlight
7.4 Optical design for other applications
References