The world's ever-growing demand for power has created an urgent need for new efficient and sustainable sources of energy and electricity. Today's consumers of portable electronics also demand devices that not only deliver more power but are also environmentally friendly. Fuel cells are an important alternative energy source, with promise in military, commercial and industrial applications, for example power vehicles and portable devices. A fuel cell is an electrochemical device that directly converts the chemical energy of a fuel into electrical energy. Fuel cells represent the most efficient energy conversion technologies to-date and are an integral part in the new and renewable energy chain (e.g., solar, wind and hydropower). Fuel cells can be classified as either high-temperature or lowtemperature, depending on their operating temperature, and have different materials requirements. This book is dedicated to the study of high temperature fuel cells. In hightemperature fuel cells, the electrolyte materials are ceramic or molten carbonate, while the electrode materials are ceramic or metal (but not precious metal). High operation temperature fuel cells allow internal reforming, promote rapid kinetics with non-precious materials and offer high flexibilities in fuel choice, and are potential and viable candidate to moderate the fast increase in power requirements and to minimize the impact of the increased power consumption on the environment. 'Materials for High Temperature Fuel Cells' is part of the series on Materials for Sustainable Energy and Development edited by Prof. Max Q. Lu. The series covers advances in materials science and innovation for renewable energy, clean use of fossil energy, and greenhouse gas mitigation and associated environmental technologies.
Preface p. xi
Series Preface p. xiii
Introduction p. xv
The Physiology of 3D Perception p. 1
Binocular Viewing or Human Stereopsis p. 1
The Mismatch of Accommodation and Disparity and the Depths of Focus and of Field p. 3
Distance Scaling of Disparity p. 6
Interocular Crosstalk p. 7
Psychological Effects for Depth Perception p. 10
High-Level Cognitive Factor p. 10
Acknowledgments p. 11
References p. 11
Stereoscopic Displays p. 13
Stereoscopic Displays with Area Multiplexing p. 13
Retarders for the generation of polarizations p. 13
Wire grid polarizers for processing of the second view p. 20
Stereoscopic display with two LCDs p. 22
Combined Area and Time Division Multiplex for 3D Displays p. 26
Stereoscopic Time Sequential Displays p. 31
Time sequential viewing with an active retarder p. 31
Fast time sequential 3D displays by the use of OCB LCDs p. 33
Time sequential 3D displays with black insertions p. 33
Special Solutions for Stereoscopic Displays p. 41
Stereoscopic Projectors p. 48
Interleaved, Simultaneous, and Progressive Addressing of AMOLEDs and AMLCDs p. 60
Photo-Induced Alignment for Retarders and Beam Splitters p. 68
Acknowledgments p. 68
References p. 69
Autostereoscopic Displays p. 73
Spatially Multiplexed Multiview Autostereoscopic Displays with Lenticular Lenses p. 73
Spatially Multiplexed Multiview Autostereoscopic Displays with Switchable Lenticular Lenses p. 85
Autostereoscopic Displays with Fixed and Switchable Parallax Barriers p. 95
Time Sequential Autostereoscopic Displays and Directional Backlights p. 104
Time sequential displays with special mirrors or 3D films p. 105
Time sequential displays with directionally switched backlights p. 109
Depth-Fused 3D Displays p. 115
Single and Multiview 3D Displays with a Light Guide p. 125
Test of 3D Displays and Medical Applications p. 129
Acknowledgments p. 129
References p. 130
Assessment of Quality of 3D Displays p. 133
Introduction and Overview p. 133
Retrieving Quality Data from Given Images p. 135
Algorithms Based on Objective Measures Providing Disparity or Depth Maps p. 136
The algorithm based on the sum of absolute differences p. 136
Smoothness and edge detection in images p. 140
An Algorithm Based on Subjective Measures p. 146
The Kanade-Lucas-Toman (KLT) Feature Tracking Algorithm p. 153
Special Approaches for 2D to 3D Conversion p. 158
Conversion of 2D to 3D images based on motion parallax p. 159
Conversion from 2D to 3D based on depth cues in still pictures p. 161
Conversion from 2D to 3D based on gray shade and luminance setting p. 162
Reconstruction of 3D Images from Disparity Maps Pertaining to Monoscopic 2D or 3D Originals p. 165
Preprocessing of the depth map p. 165
Warping of the image creating the left and the right eye views p. 167
Disocclusions and hole-filling p. 172
Special systems for depth image-based rendering (DIBR) p. 176
Acknowledgments p. 182
References p. 183
Integral Imaging p. 185
The Basis of Integral Imaging p. 186
Enhancement of Depth, Viewing Angle, and Resolution of 3D Integral Images p. 188
Enhancement of depth p. 189
Enlargement of viewing angle p. 193
Enhancing resolution p. 195
Integral Videography p. 196
Convertible 2D/3D Integral Imaging p. 207
Acknowledgments p. 214
References p. 214
Holography for 3D Displays p. 217
Introduction and Overview p. 217
Recording a Hologram and Reconstruction of the Original 3D Image p. 218
A Holographic Screen p. 227
Digital Holography Based on the Fourier Transform p. 229
A Holographic Laser Projector p. 232
Acknowledgments p. 235
References p. 235
Volumetric 3D Displays p. 237
The Nature of Volumetric Displays p. 237
Accessing and Activating Voxels in Static Volumetric Displays p. 238
Swept Volume or Mechanical 3D Displays p. 245
Acknowledgments p. 252
References p. 252
A Shot at the Assessment of 3D Technologies p. 253
Index p. 257
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