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Subsea optics and imaging /
The use of optical methodology, instrumentation and photonics devices for imaging, vision and optical sensing is of increasing importance in understanding our marine environment. Subsea optics can make an important contribution to the protection and sustainable management of ocean resources and cont...
| Clasificación: | Libro Electrónico |
|---|---|
| Otros Autores: | , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Burlington :
Elsevier Science,
2013.
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| Colección: | Woodhead Publishing series in electronic and optical materials.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Cover; Subsea opticsand imaging; Copyright; Contents; Contributor contact details; Woodhead Publishing Series in Electronic and Optical Materials; Preface; Part I Introduction and historic review of subsea optics and imaging; 1 Subsea optics: an introduction; 1.1 Light within aquatic media; 1.2 Fundamentals of marine optics; 1.3 Optical properties of natural waters; 1.4 Optical classification of water bodies; 1.5 Conclusion and future trends; 1.6 Sources of further information and advice; 1.7 References; 2 Subsea imaging and vision: an introduction; 2.1 Introduction.
- 2.2 A 'potted' and selective history of underwater imaging and vision2.3 Subsea optical imaging; 2.4 Extended range imaging systems; 2.5 Plankton imaging and profiling systems; 2.6 Hybrid systems; 2.7 Future trends; 2.8 Sources of further information and advice; 2.9 References; 3 The history of subsea optics; 3.1 Introduction; 3.2 Exploring the arcane colouring of natural waters; 3.3 Blue reflecting and green transmitting water; 3.4 The principles of Capri's Blue Grotto; 3.5 Historical pieces of laboratory equipment; 3.6 Historical pieces of field equipment; 3.7 Ocean colour comparator scales.
- 3.8 Conclusion3.9 Remarkable notes and thoughts; 3.10 References; Part II Biogeochemical optics in the environment; 4 Measurement of hyperspectral underwater light fields; 4.1 Hyperspectral versus multispectral radiometry; 4.2 Radiometry fundamentals; 4.3 Sensor design and collector geometry; 4.4 Spectral resolution, noise levels and temporal response; 4.5 Radiometer calibration and deployment; 4.6 Hyperspectral characteristics of natural waters; 4.7 Significance of transpectral processes; 4.8 Conclusion and future trends; 4.9 References; 5 Colored dissolved organic matter in seawater.
- 5.1 Introduction5.2 Optical properties of CDOM; 5.3 Measurement of CDOM; 5.4 Applications of CDOM measurement in the ocean; 5.5 Future trends; 5.6 Sources of further information and advice; 5.7 References; 6 Optical assessment of nutrients in seawater; 6.1 Introduction; 6.2 Direct optical measurement; 6.3 Indirect optical measurement; 6.4 Conclusion and future trends; 6.5 References; 7 Bioluminescence in the sea; 7.1 Introduction; 7.2 Measurement of bioluminescence in the ocean; 7.3 Propagation of bioluminescence in and out of the ocean; 7.4 Future trends; 7.5 Acknowledgements; 7.6 References.
- 8 Optical assessment of harmful algal blooms (HABs)8.1 Introduction: addressing the diversity of harmful algal blooms; 8.2 Algal features for bio-optical assessment; 8.3 Scale and resolution in surveillance of algal blooms; 8.4 Emerging advancement in bio-optical sensor technologies; 8.5 Transfer to operational oceanography; 8.6 References; 9 Optical techniques in studying suspended sediments, turbulence and mixing in marine environments; 9.1 Introduction; 9.2 Particles in seawater: their mass, density and settling speed; 9.3 Particle size distributions; 9.4 Particles and turbulence.