[미국특허]
Light source assemblies and systems and methods with mode homogenization
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F21V-008/00
G02B-006/44
G02B-006/42
G02B-006/38
출원번호
US-0411183
(2017-01-20)
등록번호
US-10234614
(2019-03-19)
발명자
/ 주소
Bauco, Anthony Sebastian
출원인 / 주소
Corning Research & Development Corporation
대리인 / 주소
Branham, Robert L.
인용정보
피인용 횟수 :
0인용 특허 :
151
초록▼
A method of generating light for use in tracing an end of a cable assembly includes coupling convergent visible light into an input end of a multimode mode-homogenizing optical fiber having low-order and high-order modes and comprising an output end, a fiber angle, a length and a mode-homogenization
A method of generating light for use in tracing an end of a cable assembly includes coupling convergent visible light into an input end of a multimode mode-homogenizing optical fiber having low-order and high-order modes and comprising an output end, a fiber angle, a length and a mode-homogenization length. The inputted light is initially concentrated mainly in the low-order modes. The method also includes conveying the light through the length of the mode-homogenizing optical fiber to form outputted light that is substantially mode-homogenized, substantially spatially uniform and substantially angularly uniform and having a divergence angle that is substantially the same as the fiber angle. Light source assemblies and systems for carrying out the method are also disclosed.
대표청구항▼
1. A light source assembly for use with a multimode delivery waveguide having an input end supported by an input connector, comprising: a housing having an interior and a bulkhead;a light emitter that resides within the interior of the housing and that emits visible light with a wavelength between 5
1. A light source assembly for use with a multimode delivery waveguide having an input end supported by an input connector, comprising: a housing having an interior and a bulkhead;a light emitter that resides within the interior of the housing and that emits visible light with a wavelength between 520 nm and 540 nm and an optical power in a range from 20 milliwatts to 1000 milliwatts;a multimode mode-homogenizing optical fiber that has an input end, an output end, a fiber length, and light-redirecting features to facilitate mode-homogenization by redirecting light from low-order modes to higher-order modes, wherein the input end is optically coupled to the light emitter to receive the visible light, and wherein a mode-homogenization length LMH is a minimum length required for at least 90% mode-homogenization and the fiber length is in a range from (0.8)·LMH to (1.25)·LMH so that the output end emits the light at a substantially maximum divergence angle;an output connector at the output end of the mode-homogenizing optical fiber; anda connector adapter having inner and outer receptacles, with the output connector of the mode-homogenizing optical fiber is configured for engagement with the inner receptacle and wherein the outer receptacle is configured for receiving the input connector of the multimode delivery waveguide. 2. The light source assembly according to claim 1, wherein the connector adapter is located at the bulkhead. 3. The light source assembly according to claim 1, wherein the optical coupling between the light emitter and the input end of the mode-homogenizing optical fiber is performed by a single lens element. 4. The light source assembly according to claim 1, wherein the light emitter comprises a laser. 5. The light source assembly according to claim 1, wherein the mode-homogenizing optical fiber has a radiation length LR over which 90% of the light coupled into the mode-homogenizing optical fiber is directed out of the mode-homogenizing optical fiber via radiation modes and wherein the mode-homogenization length LMH is in a range from (0.2)·LR (0.3)·LR. 6. The light-source assembly according to claim 1, wherein the fiber length is in a range from (0.95)·LMH to (1.05)·LMH. 7. The light-source assembly according to claim 1, further comprising: control circuitry electrically connected to the light emitter;an electrical power source electrically connected to the control circuitry; anda switch electrically connected to the control circuitry to control the operation of the control circuitry. 8. The light-source assembly according to claim 1, wherein the light emitter has an output power of between 20 and 1000 milliwatts. 9. The light-source assembly according to claim 1, wherein the mode-homogenizing optical fiber comprises a light-diffusing or light-scattering optical fiber. 10. The light-source assembly according to claim 1, further comprising the multimode delivery waveguide, wherein the input connector of the multimode delivery waveguide is operably engaged with the outer receptacle of the connector adapter so that the input end of the multimode delivery waveguide is optically coupled to the output end of the mode-homogenizing optical fiber. 11. The light-source assembly according to claim 10, wherein the delivery waveguide has an output connector coupled thereto and further comprising: a traceable cable assembly that comprises a cable that supports at least one data element and at least first and second tracer optical fibers respectively, the traceable cable assembly further comprising first and second connectors that respectively terminate first and second opposite ends of the cable, the first and second connectors respectively having first and second receptacles that respectively terminate first and second input ends of the first and second tracer optical fibers, and wherein first and second output ends of the first and second tracer optical fibers respectively terminate at the second and first connectors; andwherein the output connector of the delivery waveguide is operably engaged with one of the first and second connector receptacles of one of the first and second connectors of the traceable cable assembly. 12. A light source system for use with a traceable cable assembly terminated by first and second connectors, comprising: a light emitter that emits light with a wavelength between 520 nm and 540 nm and an optical power in a range from 20 milliwatts to 1000 milliwatts;a section of multimode mode-homogenizing optical fiber having an input end, an output end, a fiber length, and light-redirecting features to facilitate mode-homogenization by redirecting light from low-order modes to higher-order modes, and a fiber angle θF, wherein a mode-homogenization length LMH is a minimum length required for at least 90% mode-homogenization and the fiber length is in a range from (0.8)·LMH to (1.25)·LMH, and wherein the fiber angle θF is a maximum angle measured to a center axis of the optical fiber over which the optical fiber can receive and emit light;an optical component operably disposed between the light emitter and the input end of the mode-homogenizing optical fiber to couple light into the input end of the mode-homogenizing optical fiber at a convergence angle θC that is less than the fiber angle θF and wherein the output end is supported by an output connector and wherein the output end emits the light at a divergence angle θD in a range (0.9)·θF to (1.0)θF;a connector adapter having first and second receptacles, wherein the output connector is configured for engagement in the first receptacle; anda multimode delivery waveguide having an input end terminated by an input connector, wherein the input connector is configured to be operably engaged and disengaged with the second receptacle of the connector adapter. 13. The light source system according to claim 12, wherein the optical component consists of a single lens element. 14. The light source system according to claim 12, wherein the light emitter comprises a laser that emits light at a visible wavelength. 15. The light source system according to claim 12, wherein the mode-homogenizing optical fiber has a radiation length LR over which 90% of the light coupled into the fiber is directed out of the fiber via radiation modes and wherein the mode-homogenization length LMH is in a range from (0.2)·LR to (0.3)·LR. 16. The light-source system according to claim 12, wherein the fiber length is in a range from (0.95)·LMH to (1.05)·LMH. 17. The light-source system according to claim 12, further comprising: control circuitry electrically connected to the light emitter;an electrical power source electrically connected to the control circuitry; anda switch electrically connected to the control circuitry to control the operation of the control circuitry. 18. The light-source system according to claim 12, wherein the mode-homogenizing optical fiber comprises a light-diffusing optical fiber or a light-scattering optical fiber. 19. The light-source system according to claim 12, wherein the multimode delivery waveguide comprises a multimode optical fiber. 20. The light-source system according to claim 12, further comprising an output connector, wherein the multimode delivery waveguide has an output end terminated by the output connector and wherein the output connector is configured to be engaged and disengaged with respective first and second connector receptacles of the first and second connectors of the traceable cable assembly. 21. A method of generating light for use in tracing an end of a cable assembly, comprising: a) coupling convergent visible light with a wavelength between 520 nm and 540 nm and an optical power in a range from 20 milliwatts to 1000 milliwatts into an input end of a multimode mode-homogenizing optical fiber configured to redirect light from low-order modes to higher order modes and comprising an output end, a fiber angle θF, and a fiber length, and light-redirecting features to facilitate mode-homogenization, wherein the convergent visible light is initially concentrated in the low-order modes, wherein the fiber angle θF is a maximum angle measured to a center axis of the optical fiber over which the optical fiber can receive and emit light; andb) conveying the convergent visible light through the fiber length of the mode-homogenizing optical fiber to form outputted light that is substantially mode-homogenized, substantially spatially uniform, and substantially angularly uniform and having a divergence angle θD in a range from (0.9)·θF to (1.0)θF. 22. The method according to claim 21, wherein a mode-homogenization length LMH is a minimum length required for at least 90% mode-homogenization and the fiber length is in a range from (0.8)·LMH to (1.25)·LMH. 23. The method according to claim 21, further comprising prior to step a): emitting the visible light from a light emitter as divergent visible light; andreceiving the divergent visible light at an optical component that converts the divergent visible light into the convergent visible light. 24. The method according to claim 23, wherein the light emitter comprises a laser and wherein the optical component consists of a single lens element operably disposed between the laser and the input end of the mode-homogenizing optical fiber. 25. The method according to claim 21, wherein the fiber length is in a range from (0.95)·LMH to (1.05)·LMH. 26. The method according to claim 21, wherein the mode-homogenizing optical fiber comprises either a light-diffusing or light-scattering optical fiber. 27. The method according to claim 21, further comprising: delivering the outputted light to an input end of a tracer optical fiber supported by a traceable patch cord. 28. The method according to claim 21, wherein the convergent light does not satisfy an eye safety standard and wherein the outputted light satisfies said eye safety standard.
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