Synopses & Reviews
From its inception nearly 30 years ago, the optical subdiscipline now referred to as nonimaging optics, has experienced dramatic growth. The term nonimaging optics is concerned with applications where imaging formation is not important but where effective and efficient collection , concentration, transport and distribution of light energy is - i.e. solar energy conversion, signal detection, illumination optics, measurement and testing. This book will incorporate the substantial developments of the past decade in this field.
* Includes all substantial developments of the past decade in the rapidly moving field of nonimaging optics
* The only authoritative reference on nonimaging optics, from the leader in the field
Review
Govind Agrawal - "Nonimaging Optics" is very popular in the industry, and the
book should do quite well if it is written from the point of
view of an Engineer. Prof. ROLAND WINSTON is "the expert" in
this field and should do a very good job. We just hired one
of his colleagues from Germany here at the Institute of Optics,
and he will be teaching a course on this topic.
Review
t hired one
of his colleagues from Germany here at the Institute of Optics,
and he will be teaching a course on this topic.
Review
"This is the right book for all who need to collect light efficiently." - OPN Optics & Photonics News, Sept. 2006
Table of Contents
1. Nonimaging Optical Systems and Their Uses
2. Some Basic Ideas in Geometrical Optics
3. Some Designs of Image-Forming Concentrators
4. Nonimaging Optical Systems
5. Developments and Modifications of the Compound
Parabolic Concentrator
6. The Flow-line Method for Designing Nonimaging Optical Systems
7. Concentrators for Prescribed Irradiance
8. Simultaneous Multiple Surface Design Method
9. Imaging Applications of Nonimaging Concentrators
10. Consequences of Symmetry (by Narkis Shatz and John C. Bortz)
11. Global Optimization of High-Performance Concentrators (by Narkis Shatz and John C. Bortz)
12. A Paradigm for a Wave Description of Optical Measurements
13. Applications to Solar Energy Concentration
14. Manufacturing Tolerances
Appendices A-M
APPENDIX A: Derivation and Explanation of the Étendue Invariant, Including the Dynamical Analogy;
Derivation of the Skew Invariant
APPENDIX B: The Edge-Ray Theorem
APPENDIX C: Conservation of Skew and Linear Momentum
APPENDIX D: Conservation of Etendue for
Two-Parameter
APPENDIX E: Perfect Off-Axis Imaging
APPENDIX F: The Luneberg Lens
APPENDIX G: The Geometry of the Basic Compound Parabolic Concentrator Bundles of Rays
APPENDIX H: The qi/qo Concentrator
APPENDIX I: The Truncated Compound Parabolic Concentrator
APPENDIX J: The Differential Equation for the 2D Concentrator Profile with Nonplane Absorber
APPENDIX K: Skew Rays in Hyperboloidal Concentrator
APPENDIX L: Sine Relation for Hyperboloid/Lens Concentrator
APPENDIX M: The Concentrator Design for Skew Rays