A SAL beacon emulates the signature (e.g. spectral band, size and shape, power level and designation code) of a SAL designator beam reflected off a target. The SAL beacon is field-portable, capable of extended continuous operation and eye-safe. The SAL beacon enables “captive” flight tests of muniti
A SAL beacon emulates the signature (e.g. spectral band, size and shape, power level and designation code) of a SAL designator beam reflected off a target. The SAL beacon is field-portable, capable of extended continuous operation and eye-safe. The SAL beacon enables “captive” flight tests of munitions and SAL receivers without the logistical complications of using an operational SAL designator.
대표청구항▼
1. A semi-active laser (SAL) beacon for flight testing a missile having a SAL receiver with a field-of-view (FOV), said SAL beacon comprising: a laser assembly including a laser that emits a coherent beam in the infrared (IR) spectrum and a modulator that modulates the coherent beam to produce a pul
1. A semi-active laser (SAL) beacon for flight testing a missile having a SAL receiver with a field-of-view (FOV), said SAL beacon comprising: a laser assembly including a laser that emits a coherent beam in the infrared (IR) spectrum and a modulator that modulates the coherent beam to produce a pulsed coherent beam;a diffuser that scatters the pulsed coherent beam to produce a pulsed non-coherent beam;an optical assembly comprising a primary Fresnel lens and a secondary Fresnel lens at first and second distances from the diffuser that collect and shape the pulsed non-coherent beam to form and project a spot into the receiver FOV that emulates the signature of a SAL designator beam reflected off a target; andan environmental assembly comprising a heat sink on which the laser assembly is mounted, an insulated enclosure around the laser assembly and heat sink, and a cooling unit that removes heat from inside the enclosure. 2. The SAL Beacon of claim 1, wherein the laser is a diode-pumped Yttrium laser. 3. The SAL beacon of claim 1, wherein the modulator modulates the coherent beam with a SAL designation code for handshaking with a SAL receiver. 4. The SAL beacon of claim 3, wherein the spot mimics a signature of a SAL laser designator reflected off of a target in IR spectrum. 5. The SAL beacon of claim 4, wherein the pulsed non-coherent beam and formed spot are eye-safe, whereas the SAL laser designator and the reflected signature are not eye-safe. 6. The SAL beacon of claim 1, wherein the optical assembly further comprises: an adjustment mechanism for adjusting the positions of said primary and secondary Fresnel lenses to change a focal length at which the spot is formed. 7. The SAL beacon of claim 1, further comprising: a mount for supporting the SAL beacon on a three-dimensional gimbal; anda pointing mechanism for rotating the SAL beacon on the gimbal to form the spot in a given direction. 8. The SAL beacon of claim 7, wherein the pointing mechanism is slaved to a SAL receiver on an airborne missile to keep the spot within a field-of-view of the SAL receiver. 9. The SAL beacon of claim 1, wherein said environmental assembly stabilizes an internal temperature of the laser to sustain continuous run times of at least 10 minutes during which the laser emission of the coherent beam remains stable. 10. The SAL beacon of claim 1, wherein said heat sink comprises: a primary heat sink on which the laser assembly is mounted; anda secondary heat sink on which said primary heat sink is mounted. 11. The SAL beacon of claim 10, wherein said environmental assembly stabilizes an internal temperature of the laser to sustain continuous run times of at least 8 hours during which the laser emission of the coherent beam remains stable. 12. The SAL beacon of claim 10, wherein said cooling unit removes heat from inside the enclosure to stabilize the temperature of the secondary heat sink. 13. The SAL beacon of claim 10, wherein said primary heat sink is a finned heat sink comprising a fin base and a plurality of spaced fins extending from said fin base and said secondary heat sink comprises a plate, said laser assembly mounted on said fin base and said plurality of spaced fins mounted on said plate, said plate having a larger surface area than said fin base. 14. The SAL beacon of claim 1, wherein the cooling unit comprises a peltier cooler. 15. A system for captive testing of a SAL receiver, comprising: a missile outfitted with the SAL receiver, said SAL receiver having a FOV for detecting an IR signature reflected off a target, said IR signature modulated with a SAL designation code;an air vehicle on which the missile is mounted to fly the captive missile in a simulated mission to test the SAL receiver; anda semi-active laser (SAL) beacon that projects an IR spot that emulates the IR signature reflected off a target, said IR spot modulated with the SAL designation code, said SAL beacon comprising, a laser assembly including a laser that emits a coherent beam in the infrared (IR) spectrum and a modulator that modulates the coherent beam to produce a pulsed coherent beam encoded with the SAL designation code;a diffuser that scatters the pulsed coherent beam to produce a pulsed non-coherent beam;an optical assembly comprising a primary Fresnel lens and a secondary Fresnel lens at first and second distances from the diffuser that collect and shape the pulsed non-coherent beam to form the IR spot in the FOV of the SAL receiver; andan environmental assembly comprising a heat sink on which the laser assembly is mounted, an insulated enclosure around the laser assembly and said heat sink, and a cooling unit that removes heat from inside the enclosure to maintain a stable temperature of the laser. 16. The SAL beacon of claim 15, wherein said heat sink comprises: a primary heat sink on which the laser assembly is mounted; anda secondary heat sink on which said primary heat sink is mounted. 17. The SAL beacon of claim 16, wherein said environmental assembly stabilizes an internal temperature of the laser to sustain continuous run times of at least 8 hours during which the laser emission of the coherent beam remains stable. 18. The SAL beacon of claim 15, wherein said primary heat sink is a finned heat sink comprising a fin base and a plurality of spaced fins extending from said fin base and said secondary heat sink comprises a plate, said laser assembly mounted on said fin base and said plurality of spaced fins mounted on said plate, said plate having a larger surface area than said fin base. 19. A method for captive testing of a SAL receiver, said method comprising: outfitting a missile with the SAL receiver, said SAL receiver having a FOV for detecting an IR signature reflected off a target, said IR signature modulated with a SAL designation code;mounting the missile on an air vehicle and flying the air vehicle and captive missile in a simulated mission to test the SAL receiver;projecting from a semi-active laser (SAL) beacon an IR spot that emulates the IR signature reflected off a target, said IR spot modulated with the SAL designation code, said SAL beacon emitting a pulsed coherent beam in the infrared (IR) spectrum encoded with the SAL designation code, scattering the beam to produce a pulsed non-coherent beam, and collecting and shaping the pulsed non-coherent beam with a primary Fresnel lens and a secondary Fresnel lens to form the IR spot in the FOV of the SAL receiver; andenclosing the laser and a heat sink on which the laser is mounted within an insulated enclosure and removing heat from inside the enclosure to maintain a stable temperature of the laser. 20. The method of claim 19, wherein the heat sink comprises a finned heat sink having a fin base and a plurality of spaced fins extending from said fin base and a plate, said laser mounted on said fin base and said plurality of spaced fins mounted on said plate, said plate having a larger surface area than said fin base.
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이 특허에 인용된 특허 (3)
Minor Lewis G., Dual mode semi-active laser/laser radar seeker.
Streuber, Casey T.; Pflibsen, Kent P.; Easton, Michael P., Dual-mode electro-optic sensor and method of using target designation as a guide star for wavefront error estimation.
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