초록 ▼

System for detecting objects protruding from the surface of a body of water in a marine environment under low illumination conditions, the system comprising a gated light source, generating light pulses toward the body of water illuminating substantially an entire field of view, a gated camera, sens

System for detecting objects protruding from the surface of a body of water in a marine environment under low illumination conditions, the system comprising a gated light source, generating light pulses toward the body of water illuminating substantially an entire field of view, a gated camera, sensitive at least to wavelengths of the light generated by the gated light source, the gated camera receiving light reflected from at least one object, within the field of view, protruding from the surface of the body of water and acquiring a gated image of the reflected light, and a processor coupled with the gated light source and with the gated camera, the processor gating the gated camera to be set ‘OFF’ for at least the duration of time it takes the gated light source to produce a light pulse in its substantial entirety in addition to the time it takes the end of the light pulse to complete traversing a determined distance from the system and back to the gated camera, the processor further setting, for each pulse, the gated camera to be ‘ON’ for an ‘ON’ time duration until the light pulse, reflecting back from the object, is received by the gated camera.

대표청구항 ▼

1. A system for detecting objects protruding from the surface of a body of water in a marine environment, said system comprising: a gated light source, generating a beam of light pulses toward said body of water during low illumination conditions, at an oblique angle relative to the surface of said

1. A system for detecting objects protruding from the surface of a body of water in a marine environment, said system comprising: a gated light source, generating a beam of light pulses toward said body of water during low illumination conditions, at an oblique angle relative to the surface of said body of water, said beam of light pulses illuminating substantially an entire field of view;a gated camera, sensitive at least to wavelengths of the light generated by said gated light source, said gated camera acquiring a gated image,when at least one object protrudes from said surface of said body of water, said gated camera receives light reflected from said at least one object within said field of view, and said gated image includes a representation of a protruding portion of said at least one object,when no objects protrude from said surface of said body of water, a first portion of said beam of light pulses reflects off said surface of said body of water away from said gated camera, a second portion of said beam of light pulses is absorbed by said body of water and said gated image is a dark image;a processor, coupled with said gated light source and with said gated camera, said processor gating said gated camera to be set ‘OFF’ for at least the duration of time it takes said gated light source to produce a light pulse in its substantial entirety, in addition to the time it takes the end of said light pulse to complete traversing a determined distance from said system and back to said gated camera, said processor further setting, for each pulse, said gated camera to be ‘ON’ for an ‘ON’ time duration until said light pulse, reflecting back from said object, is received by said gated camera;a visibility and illumination conditions determinator, coupled with said processor, said visibility and illumination conditions determinator determining the visibility conditions between said system and an object in said body of water; anda situation awareness imager coupled with said processor, said situation awareness imager acquiring a situation awareness image of the surroundings of said system;wherein said processor determines the width of said light pulse and said ‘ON’ time duration of said gated camera, according to the determined visibility conditions between said system and said object,wherein said processor shortens said width of said light pulses and said ‘ON’ time duration, when the visibility conditions between said system and said object deteriorate,wherein said processor lengthen said width of said light pulses and said ‘ON’ time duration, when the visibility conditions between said system and said object improve, andwherein said processor superimposes a representation of said object, present in said gated image, on said situation awareness image. 2. The system according to claim 1, wherein said situation awareness imager is a Forward Looking Infrared Imager. 3. The system according to claim 1, wherein said processor registers said gated image and said situation awareness. 4. The system according to claim 3, wherein said processor identifies the horizon line according to said situation awareness image, thereby, said processor determines when said light is reflected from an object above said horizon line. 5. The system according to claim 1 further including: a multi-spectral camera, couple with said processor, said multi-spectral camera acquiring multi-spectral images of said body of water during high illumination conditions; anda background multi-spectral characteristics database, coupled with said processor, said background multi-spectral characteristics database storing spectral characteristics of said body of water,wherein said processor determines the spectral characteristics of each pixel in said multi-spectral image and compares the determined spectral characteristics to the spectral characteristics stored in said background multi-spectral characteristics database, said processor identifies a pixel in said image as corresponding to at least a part of at least one object protruding from said body of water when said processor identifies that the spectral characteristics of said pixel are different from the spectral characteristics of said background, said processor further determining a representation of at least a part of said object according to the identified pixels, andwherein said visibility and illumination conditions detector detects the illumination conditions in the vicinity of said system. 6. The system according to claim 5, wherein said situation awareness imager is a visual camera sensitive to light in the visible spectral band, wherein said processor registers said situation awareness image with said multi-spectral image, andwherein said processor superimposes said representation of said object on said situation awareness image. 7. The system according to claim 5, wherein said spectral characteristics include the spectral signature of the body of water. 8. The system according to claim 5, wherein said spectral characteristics include basis vectors which span the spectrum of said body of water. 9. The system according to claim 5, wherein said processor automatically determines said spectral characteristics according to a reference multi-spectral image of said body of water acquired by said multi-spectral imager. 10. The system according to claim 1, further comprising a visual camera, coupled with said processor, for acquiring visual images in the visible spectral band, said visual camera acquiring a visual image of said body of water said processor registers said visual image with said gated image, wherein said processor identifies segments in said gated image, which do not have corresponding segments in said visual image, thereby determining these segments as corresponding to reflections of light originating from external light sources in the surroundings of said system, andwherein said processor identifies a segment in said visual image as corresponding to reflections of light originating from the external light sources by identifying two segments, in the visual image, that define a line which is perpendicular to said horizon line. 11. The system according to claim 1, wherein said gated camera includes a device selected from the group consisting of: CCD;GICID;GICCD;GIAPS;GCMOS;EBCMOS;APD; andPV. 12. The system according to claim 1, wherein said system operates in an observation mode for detecting objects at large range resolutions, and wherein, when said system operates in said observation mode, said processor increases at least one of said ‘ON’ tune duration of said gated camera and the width of the light pulse. 13. The system according to claim 1, wherein said system operates in a detection mode for detecting objects at small ranges, and wherein, when said system operates in said detection mode, said processor decreases at least one of said ‘ON’ time duration of said gated camera and the width of the light pulse. 14. The system according to claim 1, wherein said processor tracks the motion of the representation of received reflections in a plurality of gated images, wherein said processor determines said received reflections as corresponding to reflections from waves when said received reflections exhibit substantially the same motion pattern between acquired gated images, andwherein said processor determines received reflections as corresponding to objects protruding from the surface of said body of water when the motion of the motion of said representations substantially differs from the motion pattern of the waves. 15. The system according to claim 1, further comprising an additive color light source, coupled with said processor, said additive color light source emitting light at a wavelength different than the wavelength of the light emitted by said light source and at a relative intensity that renders said light emitted by said light source invisible to an observer. 16. The system according to claim 1, wherein all the pulses in light pulses generated during each frame, are transmitted at the same random time period within the gating period. 17. The system according to claim 1, wherein said phases of the transmitted pulses, within each frame, are randomly determined. 18. The system according to claim 1, wherein the polarization state of said light pulses is randomly determined and said gated camera acquires images only of light exhibiting said polarization state. 19. A method for detecting objects protruding from the surface of a body of water in a marine environment, said method comprising the procedures of: detecting visibility and illumination conditions;determining the pulse width of said light pulses according to said visibility and illumination conditions;during low illumination conditions, transmitting a beam of light pulses toward said body of water, at an oblique angle relative to the surface of said body of water, said light pulses exhibiting a determined pulse width, said beam of light pulses illuminating substantially an entire field of view; acquiring a gated image of said transmitted beam of light pulses,when at least one object protrudes from said surface of said body of water, light reflects from said at least one object within said field of view and said gated image includes a representation of said at least one object,when no objects protrude from said surface of said body of water, a first portion of said beam of light pulses reflects off said surface of said body of water away from said gated camera, a second portion is absorbed by said body of water and said gated image is a dark image;detecting objects in said body of water according to said gated image,wherein said pulse width is shortened when said visibility conditions between said system and said object deteriorateacquiring a situation awareness image; andsuperimposing representations of the detected objects on the situation awareness image, andwherein said pulse width lengthened when said visibility conditions between said system and said object improve. 20. The method according to claim 19, wherein said situation awareness image is a Forward Looking Infrared image. 21. The method according to claim 20, further including the sub-procedure of identifying the horizon line according to said situation awareness image, thereby determining when said light is reflected from an object above said horizon line. 22. The method according to claim 19, further including the procedures of: during high illumination conditions, determining multi-spectral characteristics of said body of water;acquiring a multi-spectral image of said body of water;identifying pixels which do not conform with background multi-spectral characteristics; anddetecting objects in said body of water according to the identified pixels in the multi-spectral image which do not conform with background multi-spectral characteristics. 23. The method according to claim 22, wherein said situation awareness image is a visual image, and wherein said method further includes the procedure of: registering said situation awareness image with said multi-spectral image; andsuperimposing representations of the detected objects on said situation awareness image. 24. The method according to claim 22, wherein said spectral characteristics include the spectral signature of said body of water. 25. The method according to claim 22, wherein said spectral characteristics include basis vectors which span the spectrum of said body of water. 26. The method according to claim 22, wherein said spectral characteristics are determined according to a reference multi-spectral image of said body of water. 27. The method according to claim 22, wherein said spectral characteristics database is periodically updated. 28. The method according to claim 19, further including the procedures of alleviating interferences in said gated image, said alleviating interferences at least includes identifying segments in said gated image, which do not have corresponding segments in a visual image, thereby determining these segments as corresponding to reflections of light originating from external light sources, and wherein said alleviating interferences further includes identifying a segment in said visual image as corresponding to reflections of light originating from said external light sources by identifying two segments, in the visual image, that define a line which is perpendicular to said horizon line. 29. The method according to claim 19, wherein the motion of representation of received reflections are tracked in a plurality of gated images, wherein said reflections are determined as corresponding to reflections from waves when said received reflections exhibit substantially the same motion pattern between acquired gated images, and wherein said reflections are determined as corresponding to objects protruding from the surface of said body of water when the motion of said representations substantially differs from the motion pattern of the waves. 30. The method according to claim 19, wherein all the pulses in said light pulses, generated during each frame, are transmitted at the same random time period within the gating period. 31. The method according to claim 19, wherein said phases of the transmitted pulses, within each frame, is randomly determined. 32. The method according to claim 19, wherein the polarization state of said light pulses is randomly determined and said gated camera acquires image only of light exhibiting said polarization state.