RU96122313A - OPTICAL DEVICE (OPTIONS), LASER DIODE MODULE, OPTICAL SIGNAL COMMUNICATION DEVICE AND METHOD FOR PRODUCING AN OPTICAL DEVICE - Google Patents

Claims (17)

1. An optical device containing an optical signal transmission fiber for transmitting an input light signal to an output port, characterized in that it contains an optical fiber absorbing scattered light rays, designed to absorb the multiple reflected light rays generated in this optical device, a tip for the hard hold of this optical fiber signal transmission and optical fiber absorbing scattered light rays, the lens to focus the input light signal a, transmitted through the optical signal transmission fiber, and a sleeve for accurately aligning the tip and lens, thereby preventing the reflected light from returning to the signal transmission optical fiber.  2. An optical device containing an optical signal transmission fiber for transmitting an input light signal to an output port, characterized in that it contains an optical fiber absorbing scattered light rays, designed to absorb the multiple reflected light rays generated in this optical device, a scattered light absorber, made at one end of the absorbing optical fiber, the absorber coated with a material absorbing reflected light to prevent the return passage of and the output of the scattered light rays absorbed by the absorbing optical fiber, a tip for accurately aligning this optical signal transmission fiber and the optical fiber absorbing the scattered light rays, a lens for focusing the input light signal transmitted through the optical signal transmission fiber, and a sleeve 14 designed to precisely align the tip and lens, thereby preventing the signal from being transmitted back into the optical fiber from Agen light rays.  3. The optical device according to claim 2, characterized in that the material that absorbs reflected light is an oil coating that matches the impedance.  4. The optical device according to claim 2, characterized in that the absorbing optical fiber has an end ending at the outer end of the tip to prevent diffused light rays from passing back to the output port.  5. The optical device according to p. 3, characterized in that the end of the absorbing optical fiber is installed at an angle to prevent the backward passage of scattered light rays to the output port.  6. The optical device according to p. 4, characterized in that the end of the absorbing optical fiber is placed in the tip to prevent the return of scattered light rays to the output port.  7. The optical device according to claim 1 or 2, characterized in that the absorbing optical fiber consists of a multimode optical fiber.  8. The optical device according to claim 1 or 2, characterized in that the absorbing optical fiber is made of glass material.  9. The optical device according to claim 1 or 2, characterized in that the surface of the tip is coated with an antireflection coating (AO coating) to reduce optical losses that occur during reflection.  10. The optical device according to claim 1 or 2, characterized in that the absorbing optical fiber serves to transmit the output light signal to the input port.  11. An optical device with 2 x 2 stages, comprising two transmitting parts protected by a housing, characterized in that each transmitting part includes an optical signal transmission fiber for transmitting a light signal, an optical fiber absorbing scattered light rays mounted on a predetermined a distance from the optical signal transmission fiber for absorbing multiply reflected light rays arising in this device, a tip intended for rigidly holding the optical fiber per signal and absorbing optical fiber, a lens mounted in a predetermined position from one end of the tip to focus the transmitted light signal through the optical signal transmission fiber, and a sleeve for precise alignment of the tip and lens, both parts of the signal transmission together with the filter mounted between two lenses for reflecting or transmitting light transmitted through an optical signal transmission fiber by preventing diffused signal transmission back into the optical fiber Vetovo rays.  12. The laser diode module containing a laser diode chip for emitting a laser beam, a control unit for supplying voltage to the laser diode chip, a housing module for containing a laser diode module, an optical device installed along the laser beam, characterized in that the optical device includes an optical signal transmission fiber for transmitting a laser beam, an optical fiber absorbing scattered light beams installed at a predetermined distance from the transmission optical fiber a signal for absorbing repeatedly reflected light rays generated in the module body, a tip for rigidly holding the signal transmission optical fiber and an absorbing optical fiber, a lens mounted in a predetermined position from one end of the tip to focus the laser beam, and a sleeve for accurately aligning the tip and lens, thus preventing backscattering of scattered light rays into the optical fiber.  13. A communication device for optical signals, consisting of two parts, each of which contains an optical signal transmission fiber for transmitting a light signal, characterized in that it contains an absorbing light scattering optical fiber installed at a predetermined distance from the optical signal transmission fiber for absorption repeatedly reflected light rays generated in this communication device, a tip for rigidly holding the optical signal transmission fiber and absorbing optical fiber local, tips containing, respectively, an optical signal transmission fiber, with precise alignment by means of a housing, thereby preventing the scattered light beams from passing back into the optical transmission signal.  14. A method of manufacturing an optical device for preventing scattered light rays from passing back into the signal lenses, in which an optical signal transmission fiber is made for transmitting an input light signal to an output port or an output signal to an input port, characterized in that an optical fiber absorbing scattered light is made rays designed to absorb the repeatedly reflected light rays generated in the device to prevent their return to the optical signal transmission signal; providing the outer end of the absorbing optical fiber with a scattered light absorber coated with a material absorbing reflected radiation, or with a base angled to prevent the diffused light rays from passing back to the output port, a tip is provided for rigidly holding the signal transmission optical fiber and the absorbing optical fiber; fix the optical fiber signal transmission inside the tip; fixing the absorbing optical fiber 16 inside the tip at a distance (d) from the optical signal transmission fiber, this distance (d) being a predetermined value that is a multiple of the wavelength of the signal; grinding the outer end of the surface of the tip, containing the optical signal transmission fiber and absorbing the optical fiber; performing a lens for focusing an input light signal transmitted through an optical signal transmission fiber; perform a sleeve to align the tip and lens with a given period of time and fix the tip and lens in the sleeve.  15. The method according to p. 14, characterized in that the outer diameter (D) of the tip is chosen for coordination with the optical device.  16. The method according to p. 14, characterized in that the distance (d) between the optical signal transmission fiber and the absorbing optical fiber is 0.125 mm.  17. The method according to p. 14, characterized in that the outer end of the absorbing optical fiber is positioned inside the tip.