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An electro-optical coherent light beam signal transmission system capable of transmitting signals occupying a wide bandwidth collimated beam for a substantial distance. The system has a coherent light generator modulated at a wide bandwidth and a reflecting mirror system that radiates the modulated coherent light generated in a selected direction and spreads the said coherent light into a collimated beam having a safe energy level distribution. A coherent light receiving module in alignment with the radiated coherent light beam decollimates and focusses the coherent beam on a light sensor. Subsequently the communications signal is distributed to end users through cable systems. The coherent light generator is preferably a semiconductor coherent light generating diode and includes a temperature monitoring and regulating system which maintains coherent light generator at an optimum operating temperature for peak output levels.

InventorsBruno A. Rist, Alberto L. Casanova
Original AssigneeTelescript Industries, Inc.
Primary Examiner: Leslie Van Beek
Current U.S. Classification398/129; 250/239; 250/491.1
International Classification: H04B 900

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Citations

Cited PatentFiling dateIssue dateOriginal AssigneeTitle
US796254Sep 15, 1904Aug 1, 1905PPTOPHONE
US2153709May 6, 1937Apr 11, 1939BOURNISIEN
US4330204Nov 16, 1979May 18, 1982Santa Barbara Research CenterSelf-aligning laser communicator utilizing reciprocal tracking
US4603975Apr 29, 1982Aug 5, 1986Hughes Aircraft CompanyApparatus and method for nighttime and low visibility alignment of communicators
US4665707Aug 26, 1985May 19, 1987Protection system for electronic apparatus
US4729061May 23, 1986Mar 1, 1988Advanced Micro Devices, Inc.Chip on board package for integrated circuit devices using printed circuit boards and means for conveying the heat to the opposite side of the package from the chip mounting side to permit the heat to dissipate therefrom

Referenced by

Citing PatentFiling dateIssue dateOriginal AssigneeTitle
US5367398Apr 7, 1993Nov 22, 1994Sony CorporationOptical atmospheric link system
US5450245Oct 26, 1993Sep 12, 1995Laser Communications, Inc.Laser alignment apparatus
US5812258Nov 20, 1995Sep 22, 1998Sentech Systems, Inc.Optical coupler and alignment apparatus with multiple eccentric adjustments
US5904870May 14, 1998May 18, 1999Midland Manufacturing Corp.Laser lens heater
US6118579Apr 4, 1998Sep 12, 2000Planetary astrographic telescope
US6915582Feb 20, 2004Jul 12, 2005ARINC IncorporatedAlignment structure
US6978092Apr 27, 2004Dec 20, 2005OcuNET Devices LLCApparatus for optical communication using a large-area primary reflector
US7099059Dec 24, 1997Aug 29, 2006International Business Machines CorporationDual mode collimated communications transceiver
US7143520Apr 16, 2004Dec 5, 2006Arinc IncorporatedAlignment structure

Claims

1. A coherent light beam transmission system comprising;

coherent light generating means;
modulating means for modulating said coherent light generating means over a wide bandwidth;
radiating means for radiating said modulated coherent light generated in a selected direction;
said radiating means including means for distributing said coherent light into a collimated beam having a safe energy level distribution;
a focussing lens mounted in the path of coherent light radiating from said coherent light generating means for focussing said coherent light on said radiating means;
means for preventing condensation of moisture on said focussing lens;
said means for preventing condensation of moisture on said focussing lens comprising a cap having a central aperture said focussing lens being mounted in said central aperture, mounting means mounting said cap over said coherent light generating means, said cap enclosing a small volume of air between said coherent light generating means and said focussing lens; and heat sink means acting as a heat sink and warming means to warm said small volume of air to keep the focussing lens at at temperature greater than the outside air so that condensation of moisture on said focussing lens is prevented;
coherent light receiving means in alignment with signal coherent light radiating means;
decollimating means in said receiving means for decollimating said collimated beam, said decollimated means including means for focussing said coherent beam on light sensing means; and
distribution means connected to said light sensing means for distributing the communications signal received.

2. The system according to claim 1 in which said modulating means comprises; a cable television signal; and a cable matching impedance connecting said cable television signal to said coherent light generating means.

3. The system according to claim 2 in which said coherent light generating means is a semiconductor coherent light generating means.

4. The system according to claim 3 including cooling means cooling said semiconductor coherent light generator; and

cooling regulating means for regulating the operation of said cooling means to maintain said semiconductor coherent light generating means at an optimum operating temperature.

5. The system according to claim 4 in which said cooling means comprises;

heat conducting means for mounting said semiconductor coherent light generating means;
heat sink means comprised of a large heat conducting mass in heat transfer relationship to said heat conducting mean; and
thermo-electric heat pump means mechanically connected between said heat conducting means and said heat sink means for pumping heat from said heat conducting means to said heat sink means.

6. The system according to claim 5 including temperature sensing means for sensing the operating temperature of said semiconductor coherent light generator; said temperature sensing means connected to control the operation of said thermo-electric heat pump means to maintain the most efficient operating temperature of said semiconductor coherent light generating means.

7. The system according to claim 6 in which the operating temperature of said semiconductor coherent light generating means is maintained at approximately zero degrees centigrade.

8. The system according to claim 7 in which said heat sink is a massive copper cylindrical slug; said slug constructed to provide a support for mounting said semiconductor coherent light generator.

9. The system according to claim 1 in which said means for warming said small volume of enclosed air comprises mechanically coupling said cap to said heat sink whereby heat is conducted to said cap to heat said small volume of air in said cap.

10. The system according to claim 1 in which said radiating means comprises; a primary concave reflecting mirror, and means mounting said coherent light generating means at the focal point of said primary concave reflecting mirror.

11. The system according to claim 10 in which said primary concave reflective mirror is a concave spherical mirror having a highly reflective coating on the spherical concave surface.

12. The system according to claim 11 in which said means for mounting said coherent light generating means comprises a tubular housing; a spider shaped support having a central socket for securely receiving heat sink means mounting said coherent light generating means; said spider shaped support maximum outer dimension being approximately equal to the interior diameter of said tubular housing; whereby said spider shaped support will tightly fit into said tubular housing and centrally position a coherent light source mounted in said central socket.

13. The system according to claim 10 in which said primary concave reflecting mirror is a concave spherical surface on which a highly reflective coating is plated.

14. The system according to claim 13 in which said coherent light generator radiates coherent light in the mean visible to infrared range.

15. The system according to claim 1 in which said radiating means comprising; a primary reflecting mirror; a secondary reflecting mirror in coaxial registration with said primary reflecting mirror; and mounting means mounting said coherent light generating means at a focal point of said secondary reflecting mirror.

16. The system according to claim 15 in which said primary reflecting mirror, secondary reflecting mirror and coherent light generating means are aligned on a common axis.

17. The system according to claim 16 in which said primary reflecting mirror has a central aperture; said secondary reflecting mirror having a focal point on said axis adjacent said aperture; said coherent light source being mounted in said aperture at the focal point of said secondary reflective mirror.

18. The system according to claim 16 including a correcting lens in the path of said coherent light radiated from said primary reflecting mirror whereby distortions in said light beam are corrected.

19. The system according to claim 18 in which said primary reflecting mirror is a concave spherical surface on which a highly reflective coating is plated.

20. The system according to claim 19 in which said primary reflecting mirror produces a beam having an approximately eight inch diameter.

21. The system according to claim 20 in which said coherent light generator radiates coherent light in the mean visible to infrared range.

Drawings