A modular hyperspectral thermal camera that combines a wide field-of-view with a low erroneous recognition rate is described. The modular hyperspectral thermal camera provides such low erroneous recognition rates without any requirement for cryogenically cooling the associated optical components. Th
A modular hyperspectral thermal camera that combines a wide field-of-view with a low erroneous recognition rate is described. The modular hyperspectral thermal camera provides such low erroneous recognition rates without any requirement for cryogenically cooling the associated optical components. The modular nature of the hyperspectral thermal camera permits easy exchange of the optical components and so provides a device that is easily calibrated and varied in resolution. In addition the modular nature allows the hyperspectral thermal camera to be readily converted to a broad band thermal camera, a full field spectrograph or a thermal bandpass filter camera, as required.
대표청구항▼
The invention claimed is: 1. A modular hyperspectral thermal imaging camera comprising a transmissive diffraction grating, a detector and non-cryogenically cooled optical components, comprising an image slit, a telecentric imaging lens, a telecentric collimator and a focusing lens, the image slit c
The invention claimed is: 1. A modular hyperspectral thermal imaging camera comprising a transmissive diffraction grating, a detector and non-cryogenically cooled optical components, comprising an image slit, a telecentric imaging lens, a telecentric collimator and a focusing lens, the image slit comprising a transparent piercing in a highly reflective surround. 2. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the transmissive diffraction grating comprises a linear phase grating and a refractive substrate, characterised in that for a reference radiation of a predetermined reference wavelength an induced diffraction of the linear phase grating compensates an induced refraction of the refractive substrate, such that the reference radiation passes undeviated through the transmissive diffraction grating. 3. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the detector comprises an aperture stop, a cold shield and a photodetector array. 4. A modular hyperspectral thermal imaging camera as claimed in claim 3, wherein the aperture stop comprises an aperture formed within the cold shield. 5. A modular hyperspectral thermal imaging camera as claimed in claim 3 wherein the aperture stop comprises an aperture formed in a convex mirror located externally to the cold shield such that a radius of curvature of the convex mirror matches a distance between the photodetector array and the convex mirror. 6. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the detector comprises a mosaic of photodiodes. 7. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the optical components comprise materials that exhibit very low absorption coefficients. 8. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the transparent piercing leads to air. 9. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the transparent piercing leads to a transmissive material. 10. A modular hyperspectral thermal imaging camera as claimed in claim 9, wherein the entrance slit surround is heated to a temperature just above the atmospheric dew point. 11. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the imaging lens comprises an optical singlet and an air spaced doublet. 12. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the entrance slit is located internally to the imaging lens. 13. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the entrance slit is located externally to the imaging lens. 14. A modular hyperspectral thermal imaging camera as claimed in claim 1, comprising one or more calibration mirrors. 15. A modular hyperspectral thermal imaging camera as claimed in claim 1, comprising a scanning mirror located at the entrance slit, wherein the scanning mirror allows for the field of view of the slit to be scanned through an object field. 16. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the optical components comprise a collimator that is afocal. 17. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the optical components comprise a collimator that comprises a negative aspheric lens, a positive aspheric and a diffractive hybrid lens. 18. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the optical components comprise a focusing lens that provides image rays that are telecentric so forming an image at the detector. 19. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the optical components comprise a focusing lens that comprises a positive lens and a correcting lens. 20. A modular hyperspectral thermal imaging camera as claimed in claim 1, further comprising a cooling jacket for cooling the optical components of the modular hyperspectral thermal imaging camera so enhancing the signal to noise ratio of a detected image. 21. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the components are interchangeable. 22. A modular hyperspectral thermal imaging camera as claimed in claim 1, wherein the a resolution of the hyperspectral thermal imaging camera is altered by changing the transmissive diffraction grating. 23. A modular hyperspectral thermal imaging camera comprising a transmissive diffraction grating, a detector and optical components, wherein the optical components of the modular hyperspectral thermal imaging camera do not require cryogenic cooling, and the transmissive diffraction grating comprises a linear phase grating and a refractive substrate, wherein for a reference radiation of a predetermined reference wavelength an induced diffraction of the linear phase grating compensates an induced refraction of the refractive substrate, such that the reference radiation passes undeviated through the transmissive diffraction grating. 24. A modular hyperspectral thermal imaging camera comprising a transmissive diffraction grating, a detector and optical components, wherein the optical components do not require cryogenic cooling, and wherein the detector comprises an aperture stop, a cold shield and a photodetector array. 25. A modular hyperspectral thermal imaging camera as claimed in claim 24, wherein the aperture stop comprises an aperture formed within the cold shield. 26. A modular hyperspectral thermal imaging camera as claimed in claim 24, wherein the aperture stop comprises an aperture formed in a convex mirror located external to the cold shield such that a radius of curvature of the convex mirror matches a distance between the photodetector array and the convex mirror. 27. A modular hyperspectral thermal imaging camera comprising a transmissive diffraction grating, a detector and optical components, wherein the optical components of the modular hyperspectral thermal imaging camera do not require cryogenic cooling, wherein the detector comprises an aperture stop, a cold shield and a photodetector array, and wherein the aperture stop comprises an aperture formed in a convex mirror located external to the cold shield such that a radius of curvature of the convex mirror matches a distance between the photodetector array and the convex mirror.
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