High Collection Nonimaging Optics

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High Collection Nonimaging Optics W. T. WELFORD Optics Section Department of Physics Imperial College of Science, Technology and Medicine University of London London, England R. WINSTON Enrico Fermi Institute and Department of Physics University of Chicago Chicago, Illinois ACADEMIC PRESS, INC. Harcourt Brace Jovanovich, Publishers San Diego New York Berkeley Boston London Sydney Tokyo Toronto

Contents Preface xi Chapter 1 Concentrators and Their Uses 1.1 Concentrating Collectors 1 1.2 Definition of the Concentration Ratio; the Theoretical Maximum 3 1.3 Uses of Concentrators 6 Chapter 2 Some Basic Ideas in Geometrical Optics 2.1 The Concepts of Geometrical Optics 9 2.2 Formulation of the Ray-Tracing Procedure 10 2.3 Elementary Properties of Image-Forming Optical Systems 14 2.4 Aberrations in Image-Forming Optical Systems 16 2.5 The Effect of Aberrations in an Image-Forming System on the Concentration Ratio 18 2.6 The Optical Path Length and Fermat's Principle 20 2.7 The Generalized Etendue or Lagrange Invariant and the Phase Space Concept 22 2.8 The Skew Invariant 28 2.9 Different Versions of the Concentration Ratio 28 Chapter 3 Some Designs of Image-Forming Concentrators 3.1 Introduction 31 3.2 Some General Properties of Ideal Image-Forming Concentrators 31

V/ Contents 3.3 Can an Ideal Image-Forming Concentrator Be Designed? 39 3.4 Media with Continuously Varying Refractive Index 44 3.5 Another System of Spherical Symmetry 46 3.6 Image-Forming Mirror Systems 48 3.7 Conclusions on Image-Forming Concentrators 50 Chapter 4 Nonimaging Concentrators: The Compound Parabolic Concentrator 4.1 Light Cones 53 4.2 The Edge-Ray Principle 54 4.3 The Compound Parabolic Concentrator 55 4.4 Properties of the Compound Parabolic Concentrator 62 4.5 Cones and Paraboloids as Concentrators 72 Chapter 5 Developments and Modifications of the Basic Compound Parabolic Concentrator 5.1 Introduction 77 5.2 The Dielectric-Filled CPC with Total Internal Reflection 77 5.3 The CPC with Exit Angle Less Than тг/2 82 5.4 The Concentrator for a Source at a Finite Distance 84 5.5 The Two-Stage CPC 86 5.6 The CPC Designed for Skew Rays 87 5.7 The Truncated CPC 91 5.8 The Lens-Mirror CPC 95 Chapter 6 Developments of the Compound Parabolic Concentrator for Nonplane Absorbers 6.1 2D Collection in General 99 6.2 Extension of the Edge-Ray Principle 100 6.3 Some Examples 102 6.4 The Differential Equation for the Concentrator Profile 105 6.5 Mechanical Construction for 2D Concentrator Profiles 105 6.6 The Most General Design Method for a 2D Concentrator 108 6.7 A Constructive Design Principle for Optimal Concentrators 113 Chapter 7 Flowline Approach to Nonimaging Concentration 7.1 The Concept of the Flowline 115 7.2 Lines of Flow from Lambertian Radiators: 2D Examples 116 7.3 3D Example 118 7.4 A Simplified Method for Calculating Lines of Flow 121

Contents vii 7.5 Properties of the Lines of Flow 122 7.6 Application to Concentrator Design 123 7.7 The Hyperboloid of Revolution as a Concentrator 124 7.8 Elaborations of the Hyperboloid: The Truncated Hyperboloid 125 7.9 The Hyperboloid Combined with a Lens 126 7.10 The Hyperboloid Combined with Two Lenses 127 7.11 Generalized Flowline Concentrators with Refractive Components 127 Chapter 8 Physical Optics Aspects of Concentrators and Collectors 8.1 Introduction 131 8.2 Etendue in the Physical Optics Model 132 8.3 Defining Generalized Radiance 133 8.4 Efficiency of 2D Concentrators in the Scalar Wave Model 134 8.5 Efficiency of 3D Concentrators: An Image-Formation Approach 137 8.6 The Quantum Optics Approach 140 8.7 Resonance Effects 141 8.8 Focusing in Electromagnetic Theory 142 8.9 More about Generalized Radiance 143 8.10 Conclusions 145 Chapter 9 Shape Tolerances and Manufacturing Methods for Nonimaging Optical Components 9.1 Optical Tolerances 147 9.2 Tolerances for Nonimaging Concentrators 148 9.3 Ray-Tracing Results 149 9.4 Peaks in the Emergent Light Distribution 150 9.5 Reflectors for Uniform Illumination 160 9.6 Materials and Manufacture 163 Chapter 10 Applications to Solar Energy Concentration 10.1 The Requirements for Concentrators 165 10.2 Earth-Sun Geometry 167 10.3 Insolation Characteristics 171 10.4 Collector Design 172 10.5 Nonevacuated CPCs 179 10.6 Evacuated CPCs 182 10.7 An Advanced CPC: The Integrated Concentrator 183 10.8 Nonimaging Secondary Concentrators 192

VIH Contents Chapter 11 Illumination of Optical Systems and Instruments 11.1 Introduction: The Radiance Theorem 201 11.2 Radiance of Laboratory Light Sources 202 11.3 Conventional Illumination Systems for Instruments 203 11.4 Nonimaging Optics in Light Collection for Instruments 205 11.5 Lasers as Sources for Optical Instruments 209 11.6 Fiber Optics Applications 213 11.7 Collection of Cerenkov and Other Radiation 214 11.8 Concentration of Radiation in Detector Systems Limited by Detector Noise 215 11.9 Stray-Radiation Shields 218 11.10 Optical Pumping and General Condensing Problems 219 11.11 Biological Analogs 220 Appendix A Derivation and Explanation of the Etendue Invariant, Including the Dynamical Analogy; Derivation of the Skew Invariant A.1 The Generalized Etendue 223 A.2 Proof of the Generalized Etendue Theorem 225 A.3 The Mechanical Analogies and Liouville's Theorem 227 A.4 The Skew Invariant 228 A. 5 Conventional Photometry and the Etendue 230 Appendix В The Impossibility of Designing a "Perfect" Imaging Optical System: The Corresponding Nonimaging Problem 231 Appendix С The Lüneburg Lens 237 Appendix D The Geometry of the Basic Compound Parabolic Concentrator 243 Appendix E The 0j/0 o Concentrator 247 Appendix F The Concentrator Design for Skew Rays 249 F.l The Differential Equation 249 F.2 The Ratio of Input to Output Areas for the Concentrator 250 F.3 Proof That Extreme Rays Intersect at the Exit Aperture Rim 254 F.4 Another Proof of the Sine Relation for Skew Rays 255 F.5 The Frequency Distribution of Л 256

Contents IX Appendix G The Truncated Compound Parabolic Concentrator 259 Appendix H The Differential Equation for the 2D Concentrator Profile with Nonplane Absorber 263 Appendix I Deriving a Formula for Generalized Radiance 267 Appendix J Skew Rays in Hyperboloid Concentrator 271 Appendix К Sine Relation for Hyperboloid Lens Concentrator 273 References 275 Index 281

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