The present invention pertains to radiant energy systems and more particularly to systems exhibiting the retroreflection principle wherein the system comprises a focusing means and a surface exhibiting some degree of reflectivity positioned near the focal plane of the device, and wherein incident ra
The present invention pertains to radiant energy systems and more particularly to systems exhibiting the retroreflection principle wherein the system comprises a focusing means and a surface exhibiting some degree of reflectivity positioned near the focal plane of the device, and wherein incident radiation falling within the field-of-view of said system is reflected back in a direction which is parallel to the incident radiation. The present invention has great applicability in military optical system applications for detecting the presence of an enemy employing surveillance equipment and for neutralizing this surveillance capability.
대표청구항▼
1. The method of detecting an uncooperative optical system including a focusing means and a surface exhibiting some degree of reflectivity disposed substantially in the focal plane of said focusing means, said method comprising the step of directing optical energy at said optical system whereby that
1. The method of detecting an uncooperative optical system including a focusing means and a surface exhibiting some degree of reflectivity disposed substantially in the focal plane of said focusing means, said method comprising the step of directing optical energy at said optical system whereby that portion of said energy incident upon said optical system is retroreflected with an optical gain to thereby form a beam of retroreflected optical energy, andthe step of detecting said retroreflected optical energy having a radiant flux density in excess of a preselected value to thereby indicate the presence of said optical system. 2. The method of claim 1, including the step of scanning a predetermined geographical area to detect the presence of an optical system therein. 3. The method of claim 2, including the step of tracking said optical system after the presence thereof has been detected. 4. The method of claim 3, including the step of directing a weapon at the position of said optical system after the detection thereof. 5. The method of claim 1, wherein the radiant energy directed at said optical system is in the nonvisible region. 6. The method of claim 1, wherein the radiant energy directed at said optical system is light energy in the nonvisible region. 7. The method of claim 6, wherein the light energy in the nonvisible region is infrared. 8. The method of claim 4, wherein said weapon is a laser. 9. The method of claim 1, wherein the radiant energy is in the ultraviolet portion of the electromagnetic spectrum. 10. The method of claim 1, wherein the radiant energy is X-ray energy. 11. The method of claim 1, wherein the radiant energy comprises high energy particles related to quantum mechanics. 12. The method of claim 1, wherein the radiant energy is acoustical energy. 13. The method recited in claim 1 wherein said optical system is a telescope. 14. The method recited in claim 1 wherein said optical system is a binocular. 15. The method recited in claim 1 wherein said optical system is a periscope. 16. The method recited in claim 1 wherein said optical system is a human eye. 17. Apparatus for detecting the presence of an uncooperative optical system including a focusing means and a surface exhibiting some degree of reflectivity disposed substantially in the focal plane of said focusing means, said apparatus comprising means for producing radiant energy,means for directing said energy toward said optical system whereby said energy is retroreflected with an optical by said optical system, andmeans for detecting said retroreflected energy having a radiant flux density in excess of a preselected value to thereby indicate the presence of said optical system. 18. Apparatus in accordance with claim 17 wherein said means for producing radiant energy is a radiant energy source operative in the nonvisible region. 19. Apparatus in accordance with claim 17, wherein said means for producing radiant energy is a radiant energy light source. 20. Apparatus in accordance with claim 19, wherein said radiant energy light source is an infrared source. 21. Apparatus in accordance with claim 17, wherein said means for producing radiant energy, said means for directing said energy toward said optical system, and said means for detecting the energy retroreflected by said optical system, form an optical transceiver. 22. Apparatus in accordance with claim 21, wherein said means for producing rays of radiant energy, said means for directing said rays toward said optical instrument, andsaid means for detecting the rays retroreflected by said optical instrument are concentrically disposed with respect to one another. 23. Apparatus in accordance with claim 22, wherein said means for producing radiant energy, said means for directing said energy toward said optical system, and said means for detecting said energy retroreflected by said optical system are concentrically disposed with respect to one another. 24. Apparatus in accordance with claim 22, wherein said means for producing radiant energy comprises a radiant energy sourcesaid means for directing said energy toward said optical system comprises a primary mirror having a substantially parabolic configuration, andsaid means for detecting said retroreflected energy comprising a detectorsaid primary mirror, anda secondary mirror having a substantially planar configurationsaid primary mirror having an aperture concentric with the principal axis thereof,said radiant energy source being positioned adjacent the non-reflecting surface of said secondary mirror,in the focal plane of said primary mirror,said secondary mirror being positioned adjacent said primary mirror, andhaving the reflecting surface of said secondary mirror facing the reflecting surface of said primary mirror, andsaid detector being positioned adjacent the non-reflecting surface of said primary mirror,being in axial alignment with the aperture thereof,being positioned in the focal plane of said detection means. 25. Apparatus in accordance with claim 22, wherein said means for producing radiant energy comprises a radiant energy source,said means for directing said energy toward said optical system comprises a collecting mirror having a substantially elliptical configurationa primary mirror having a substantially parabolic configuration, anda secondary mirror having a substantially planar configuration,said means for detecting said retorreflected energy comprising a detector, andsaid primary mirror,said primary mirror having an aperture concentric with the principal axis thereof,said secondary mirror being positioned with the reflecting surface thereof facing the reflecting surface of said primary mirror,said radiant energy source being positioned between the reflecting surfaces of said primary and secondary mirrors, andin axial alignment with said mirrors,said collecting mirror being positioned adjacent the non-reflecting surface of said primary mirror, in axial alignment with the aperture thereof, and said detector being positioned in the focal plane of said direction means adjacent the non-reflecting surface of said secondary mirror in the focal plane of said primary mirror. 26. Apparatus in accordance with claim 21, wherein said means for producing incident radiant energy is a radiant energy light source operative in the nonvisible region. 27. Apparatus in accordance with claim 23, wherein said radiant energy light source is an infrared source. 28. Apparatus in accordance with claim 17, wherein said means for directing said incident energy towards said optical system having scanning means operatively associated therewith to cause said rays to scan a predetermined geographical area to detect and locate said optical system. 29. Apparatus in accordance with claim 28, including tracking means operatively associated with said scanning means to thereby track the movement of said optical system after detection thereof. 30. Apparatus in accordance with claim 28, including weapon means operatively associated with said tracking means for use against said optical system after detection thereof. 31. Apparatus in accordance with claim 30, wherein said weapon means is high energy source. 32. Apparatus in accordance with claim 31, wherein said high energy source is a laser. 33. The apparatus recited in claim 17 wherein said optical system is a telescope. 34. The apparatus recited in claim 17 wherein said optical system is a binocular. 35. The apparatus recited in claim 17 wherein said optical system is a periscope. 36. The apparatus recited in claim 17 wherein said optical system is a human eye. 37. Apparatus for measuring the retroreflective characteristics of an optical system consisting of at least a focusing means and a surface exhibiting some degree of reflectivity disposed substantially in the focal plane of said focusing means, said apparatus comprising a radiant energy source,detection means,measuring means connected to said detection means, andmeans for directing said radiant energy produced by said source at said optical system,whereby said radiant energy is retroreflected with an optical gain by said optical system and detected by said detecting means and the output thereof is coupled to said measuring means. 38. An optical system accordance with claim 37, including means disposed between said radiant energy source and said optical systemfor transmitting a portion of the radiant energy produced by said radiant energy source toward said optical system, andfor transmitting a portion of said energy retroreflected by said optical system toward said detecting means. 39. An optical system in accordance with claim 38, wherein said directing means and said detecting means are substantially concentric. 40. The method of detecting the presence of devices which exhibit the phenomenon of retroreflection, said method comprising the step of directing radiant energy at said devices whereby said radiant energy is retroreflected with an optical gain by said devices, andthe step of detecting said retroreflected radiant energy which is in excess of a preselected radiant flux density level to thereby indicate the presence of said devices. 41. The method of claim 40, including the step of analyzing said retroreflected radiant energy to thereby determine the spatial and temporal characteristics of said devices. 42. Apparatus for detecting the presence of devices which exhibit the phenomenon of retroreflection, said apparatus comprising means for producing radiant energy,means for directing said energy toward said devices whereby said energy is retroreflected with an optical gain by said devices, andmeans for detecting said retroreflected energy which is in excess of a preselected radiant flux density level to thereby indicate the presence of said devices. 43. apparatus for measuring the retroreflective characteristics of devices which exhibit the phenomenon of retroreflection, said apparatus comprising means for producing radiant energy,means for directing said energy toward said devices whereby said energy is retroreflected with an optical gain by said devices,means for detecting said retroreflected energy which is in excess of a preselected radiant flux density level to thereby indicate the presence of said devices, andmeans for analyzing said detected energy to thereby determine the characteristics of said devices. 44. The method of detecting an uncooperative and non-radiating microwave antenna system consisting of at least a microwave focusing means and a microwave feed horn disposed substantially at the focal point of said focusing means, said method comprising the step of directing swept frequency microwave energy at said antenna system whereby substantially all energy at the operating frequency of said antenna system which is impingent thereon is focused by said focusing means and absorbed by said feed horn and energy of any other frequency is retroreflected by said antenna system with an energy density gain to thereby form a beam of retroreflected microwave energy, andthe step of detecting said retroreflected energy having an energy density in excess of a preselected value to thereby indicate the presence of said antenna system. 45. The method recited in claim 44 further including the step of determining the frequency at which the energy density of said retroreflected energy is of a minimum level to thereby determine the operating frequency of said antenna system. 46. The method recited in claim 44 further including the step of analyzing any temporal characteristics of said energy retroreflected by said antenna system. 47. The method recited in claim 44 further including the step of analyzing any spatial characteristics of said beam of energy retroreflected by said antenna system. 48. A method of directing a laser at an object within an optical system, comprising: transmitting radiant energy at an object included in an optical system having retroreflective characteristics, wherein the optical system includes a lens and the object includes at least a portion exhibiting some degree of reflectivity disposed substantially in a focal plane of the lens;receiving reflected radiant energy after retroreflection of the radiant energy; anddirecting automatically a laser at the object based on a characteristic of the at least a portion of the object determined from the reflected radiant energy. 49. The method of claim 48, comprising causing the laser to alter the object. 50. The method of claim 48, wherein the characteristic of the at least a portion of the object is determined from a characteristic of the reflected radiant energy. 51. The method of claim 50, wherein the characteristic of the reflected radiant energy is at least one of an optical gain, an intensity level, a temporal characteristic, a temporal property, a spectral characteristic, and a spectral property. 52. The method of claim 48, wherein the characteristic of the at least a portion of the object is at least one of a relative position, a mechanical characteristic, and an electrical characteristic. 53. The method of claim 48, wherein the at least a portion of the object is included in at least a portion of a surface included in the object. 54. An apparatus for directing a laser at an object within an optical system, comprising: a radiant energy source configured to transmit radiant energy at an object included in an optical system having retroreflective characteristics, wherein the optical system includes a lens and the object includes at least a portion exhibiting some degree of reflectivity disposed substantially in a focal plane of the lens;a detector configured to detect received reflected radiant energy after retroreflection of the radiant energy; anda utilization system configured to direct automatically a laser at the object based on a characteristic of the at least a portion of the object determined from the reflected radiant energy. 55. The apparatus of claim 54, comprising a power source configured to cause the laser to alter the object. 56. The apparatus of claim 54, wherein the characteristic of the at least a portion of the object is determined from a characteristic of the reflected radiant energy. 57. The apparatus of claim 56, wherein the characteristic of the reflected radiant energy is at least one of an optical gain, an intensity level, a temporal characteristic, a temporal property, a spectral characteristic, and a spectral property. 58. The apparatus of claim 54, wherein the characteristic of the at least a portion of the object is at least one of a relative position, a mechanical characteristic, and an electrical characteristic. 59. The apparatus of claim 54, wherein the at least a portion of the object is included in at least a portion of a surface included in the object. 60. A method of automatically tracking at least a portion of an object within an optical system, comprising: transmitting radiant energy at an object included in an optical system having retroreflective characteristics, wherein the optical system includes a lens and the object includes at least a portion exhibiting some degree of reflectivity disposed substantially in a focal plane of the lens;receiving reflected radiant energy after retroreflection of the radiant energy; andautomatically tracking the at least a portion of the object based on a characteristic of the at least a portion of the object determined from the reflected radiant energy. 61. The method of claim 60, wherein the characteristic of the at least a portion of the object is determined from a characteristic of the reflected radiant energy. 62. The method of claim 61, wherein the characteristic of the reflected radiant energy is at least one of an optical gain, an intensity level, a temporal characteristic, a temporal property, a spectral characteristic, and a spectral property. 63. The method of claim 60, wherein the characteristic of the at least a portion of the object is at least one of a relative position, a mechanical characteristic, and an electrical characteristic. 64. The method of claim 60, wherein the at least a portion of the object is included in at least a portion of a surface included in the object. 65. An apparatus for automatically tracking at least a portion of an object within an optical system, comprising: a radiant energy source configured to transmit radiant energy at an object included in an optical system having retroreflective characteristics, wherein the optical system includes a lens and the object includes at least a portion exhibiting some degree of reflectivity disposed substantially in a focal plane of the lens;a detector configured to detect received reflected radiant energy after retroreflection of the radiant energy; anda utilization system configured to automatically track the at least a portion of the object based on a characteristic of the at least a portion of the object determined from the reflected radiant energy. 66. The apparatus of claim 65, wherein the characteristic of the at least a portion of the object is determined from a characteristic of the reflected radiant energy. 67. The apparatus of claim 66, wherein the characteristic of the reflected radiant energy is at least one of an optical gain, an intensity level, a temporal characteristic, a temporal property, a spectral characteristic, and a spectral property. 68. The apparatus of claim 65, wherein the characteristic of the at least a portion of the object is at least one of a relative position, a mechanical characteristic, and an electrical characteristic. 69. The apparatus of claim 65, wherein the at least a portion of the object is included in at least a portion of a surface included in the object.
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이 특허에 인용된 특허 (4)
Wild, Norman R.; Leavy, Jr., Paul M., Infrared deception countermeasure system.
Smith, Jeffrey Michael; Bender, Gerald Edwin; Whitmer, Roger D.; Toohey, Patrick T., Method for optical detection of surveillance and sniper personnel.
Kowalevicz, Andrew; Birdsong, Jr., Frank Allen, Non-retroreflective optical threat detection system and methods having an imaging detector aligned with a tilted image plane to reconstruct an image from plural image slices.
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