Infrared holographic projector for thermal masking and decoys
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G03H-001/22
F41H-003/00
F41H-011/00
G03H-001/00
G03H-001/02
출원번호
US-0903513
(2013-05-28)
등록번호
US-9025226
(2015-05-05)
발명자
/ 주소
Woida-O'Brien, Rigel Quinn
Barnes, Stephanie
출원인 / 주소
Raytheon Company
대리인 / 주소
Gifford, Eric A.
인용정보
피인용 횟수 :
0인용 특허 :
6
초록▼
A holographic structure, system and method project a grey-scale image in a narrow IR spectral band that is related to a broadband thermal signature of an object. The projected grey-scale image, when integrated over the broadband, forms either a decoy that approximates the thermal signature of the ob
A holographic structure, system and method project a grey-scale image in a narrow IR spectral band that is related to a broadband thermal signature of an object. The projected grey-scale image, when integrated over the broadband, forms either a decoy that approximates the thermal signature of the object or a mask that obscures the thermal signature of the object. The projected image is a tuned phase recording of a desired far field projection. In different embodiments, the projected image is a “positive” or a “negative” image of the object's thermal signature, a difference image between the thermal signatures of a false object and the object or a camouflage image of random features having approximately the same spatial frequency as the object's thermal signature. The goal being to confuse or fool, even for a short period of time, the warfighting or surveillance system or human observer that uses a broadband IR sensor to acquire and view thermal images of the scene.
대표청구항▼
1. An infrared holographic projector comprising: a grey-scale input image related to a thermal signature of an object, said grey-scale input image having at least three intensity levels;a laser source configured to generate a laser beam in a narrowband including a source wavelength in an infrared sp
1. An infrared holographic projector comprising: a grey-scale input image related to a thermal signature of an object, said grey-scale input image having at least three intensity levels;a laser source configured to generate a laser beam in a narrowband including a source wavelength in an infrared spectral range; andan infrared transmissive material having a surface arranged to provide differing amounts of phase-delay to the first laser beam as the beam passes through the material, said surface comprising at least four phase delay layers that correspond to an integer multiple of quarter-wavelengths of total phase delay at a center wavelength, each layer providing a predetermined phase delay at the center wavelength, said surface configured to encode the grey-scale input image, said surface configured to diffract the laser beam at the source wavelength at or near the center wavelength to construct a projected image in the infrared spectrum that forms a decoy that approximates the thermal signature of the object or a mask that obscures the thermal signature of the object. 2. The infrared holographic projector of claim 1, wherein the grey-scale input image and projected image are asymmetric about all axes of symmetry. 3. The infrared holographic projector of claim 1, wherein the spatial resolutions of the thermal signature of the object, the grey-scale input image and the surface of the infrared transmissive material are the same. 4. The infrared holographic projector of claim 1, wherein the grey-scale input image is a positive image of the thermal signature of the object, wherein said projected image forms the decoy that approximate the thermal signature of the object. 5. The infrared holographic projector of claim 1, wherein the grey-scale input image is a negative image of the thermal signature of the object, wherein said projected image forms the mask that adds to the thermal signature of the object to obscure the object. 6. The infrared holographic projector of claim 1, wherein the grey-scale input image is a difference image between a thermal signature of a different false object and thermal signature of the object, wherein said projected image forms the decoy that approximates the thermal signature of the different false object. 7. The infrared holographic projector of claim 1, wherein the grey-scale input image is a camouflage image with random features whose spatial frequency approximates that of the thermal signature of the object, wherein said projected image forms the mask that adds to the thermal signature of the object to camouflage the object. 8. The infrared holographic projector of claim 1, wherein the integrated power of the projected image over the narrowband of the first laser beam approximates the integrated power of the thermal signal of the object over an infrared sensor broadband. 9. The infrared holographic projector of claim 1, wherein the projected image is a tuned phase recording of a desired far field projection of the grey-scale input image. 10. The infrared holographic projector of claim 1, wherein the infrared spectral range spans approximately 800 nm to approximately 13 microns. 11. The infrared holographic projector of claim 1, wherein the center and source wavelengths lie between approximately 800 nm to approximately 2400 nm, said infrared transmissive material selected from Borofloat, Calcium Fluoride, Fused Silica, Magnesium Fluoride (MgF2), Potassium Bromide (KBr), Sapphire, Sodium Chloride (NaCl) and Zinc Sulfide. 12. The infrared holographic projector of claim 1, wherein the center and source wavelengths lie between approximately 3 microns to approximately 5 microns, said infrared transmissive material selected from Calcium Fluoride, Germanium, Magnesium Fluoride (MgF2), Potassium Bromide (KBr), Sapphire, Silicon, Sodium Chloride (NaCl), Zinc Selenide (ZnSe) and Zinc Sulfide. 13. The infrared holographic projector of claim 1, wherein the center and source wavelengths lie between approximately 7 microns to approximately 13 microns, said infrared transmissive material selected from Germanium, Potassium Bromide (KBr), Sodium Chloride (NaCl), Zinc Selenide (ZnSe) and Zinc Sulfide. 14. A grey-scale infrared holographic structure comprising: an infrared transmissive material having a surface comprising at least four phase delay layers that correspond to an integer multiple of quarter-wavelengths of total phase delay at a center wavelength in the infrared (IR) spectrum, each layer providing a predetermined phase delay at the center wavelength,wherein the at least four layers of the surface are configured to encode a grey-scale input image related to a broadband thermal signature of an object that spans a first band in the IR spectrum, said grey-scale input image having at least three intensity levels,wherein the surface is arranged to provide differing amounts of phase-delay to a narrowband laser beam as the beam passes through the material, said narrowband laser beam having a source wavelength in a second band that lies within said first band and at or near the center wavelength. 15. The infrared holographic projector of claim 14, wherein the infrared transmissive material is transmissive at the center and source wavelengths that lie between approximately 800 nm to approximately 2400 nm, said infrared transmissive material selected from Borofloat, Calcium Fluoride, Fused Silica, Magnesium Fluoride (MgF2), Potassium Bromide (KBr), Sapphire, Sodium Chloride (NaCl) and Zinc Sulfide. 16. The infrared holographic projector of claim 14, wherein the infrared transmissive material is transmissive at the center wavelength lies between approximately 3 microns to approximately 5 microns, said infrared transmissive material selected from Calcium Fluoride, Germanium, Magnesium Fluoride (MgF2), Potassium Bromide (KBr), Sapphire, Silicon, Sodium Chloride (NaCl), Zinc Selenide (ZnSe) and Zinc Sulfide. 17. The infrared holographic projector of claim 14, wherein the infrared transmissive material is transmissive at the center wavelength lies between approximately 7 microns to approximately 13 microns, said infrared transmissive material selected from Germanium, Potassium Bromide (KBr), Sodium Chloride (NaCl), Zinc Selenide (ZnSe) and Zinc Sulfide. 18. A method of holographic projection of an infrared image comprising: providing a grey-scale input image related to a broadband thermal signature of an object that spans a first band in an infrared (IR) spectrum from approximately 800 nm and approximately 13 microns, said grey-scale input image having at least three intensity levels;providing a grey-scale holographic structure comprising an infrared transmissive material having a surface comprising at least four phase delay layers that correspond to an integer multiple of quarter-wavelengths of total phase delay at a center wavelength, each layer providing a predetermined phase delay at the center wavelength, said surface configured to encode the grey-scale input image;generating a narrowband laser beam having a source wavelength in a second band within said first band, said source wavelength at or near the center wavelength;illuminating the surface of the infrared transmissive material with the laser beam;diffracting the laser beam to construct a narrowband infrared image, the infrared image being a reconstruction of the input image in the second band of the IR spectrum; andprojecting the infrared image into a scene to form a narrowband projected image that when integrated over the first band either forms a decoy that approximates the broadband thermal signature of the object or a mask that obscures the broadband thermal signature of the object. 19. The method of claim 18, wherein the grey-scale input image and the projected image are asymmetric about all axes of symmetry. 20. The method of claim 18, wherein the integrated power of the projected image over the narrowband of the first laser beam approximates the integrated power of the thermal signal of the object over an infrared sensor broadband.
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