RU97103856A - REVERSE LIGHT DISTRIBUTION DEVICE DEVICE AND METHOD FOR DETECTING TRANSMITTED LIGHT USING THIS DEVICE - Google Patents

Claims (12)

1. The device for blocking the back propagation of light, containing the input optical fiber for transmitting the input optical signal to the output stage, the first optical fiber detection, designed to receive multiple reflected light generated inside the device for blocking the back propagation of light, and for detecting the detection beam of the input stage using repeatedly reflected light, the first clip for rigidly holding the input optical fiber and the first optical detection fiber, the first lens for collimating the input optical signal emerging from the input optical fiber, the first polarizer for decomposing the collimated input optical signal into vertically and horizontally polarized light rays, a polarized light rotator designed to phase shift the rays of the input optical signal split by the first polarizer , the second polarizer for the concentration of the split rays of the input optical signal, phase shifted by the field rotator beam, a second lens for collimating the input optical signal from the output of the second polarizer to the output optical fiber, the output optical fiber for transmitting the output optical signal, the second optical detection fiber for detecting backlight generated by the output optical signal reflected from the output optical fiber introduced into the light cut-back cutoff device, thereby providing light detection the first detection beam in the output stage, and a second clip for rigidly holding the output optical fiber and the second optical detection fiber.  2. The device according to claim 1, characterized in that the first and second optical detection fibers are located in the input and output stages, respectively.  3. The device according to claim 1, characterized in that the first optical detection fiber is used to determine the state of the input optical signal in the input stage, and the second optical detection fiber is used to determine the state of the light reflected from the output stage and directed to the cutoff device for back propagation of light .  4. The device according to claim 1 or 3, characterized in that the first optical detection fiber provides detection of a detection beam of light of the input stage using repeatedly reflected light that is reflected between the input optical fiber and the first lens.  5. The device according to p. 1 or 3, characterized in that the second optical detection fiber provides detection of the detection light beam of the output stage using part of the back-propagating light reflected from the output stage and introduced into the second detection optical fiber, in particular light reflected between output optical fiber and a second lens.  6. A method of detecting transmitted light using the cutoff device for backward propagation of light according to claim 1, comprising the steps of: (A) determining the state of the input optical signal by (a) converting a portion of the input optical signal supplied to the first lens through the input optical fiber, repeatedly reflected light between the input optical fiber and the first lens, (b) repeatedly introducing repeatedly reflected light into the first detection optical fiber and (c) repeatedly reflecting ambient light as a light beam detecting the input stage, (B) determining the state of the output optical signal by (a) collimating the input optical signal supplied from the input optical fiber to the first lens when the first optical signal, the first polarizer, and the polarized light rotator pass through the input optical signal , a second polarizer and a second lens, and converting the collimated input optical signal into an output optical signal, and transmitting the output optical a signal, (b) reflecting the output optical signal in the propagation medium and reintroducing it into the cutoff device for back propagating light through the output optical fiber, (c) partially converting the back propagating light into reflected light between the second lens and the output optical fiber, (d) repeatedly introducing reflected light into the second optical detection fiber; and (e) detecting reflected light as a light detection beam of the output stage.  7. An optical amplifier containing an input optical fiber for transmitting an input optical signal to an output stage, a first detection optical fiber for transmitting a signal displaying a state of an input optical signal as a first output signal of a detection stage to a control circuit, a cutoff unit the back propagation of light of the input stage, designed to cut off the reverse flow of the input optical signal, an excited light source, providing amplification of the input optical signal by attenuating the input optical signal, a wavelength division communication device for dividing the wavelength of the optical signal emitted by the excited light source along with the wavelength of the input optical signal and for modulating the signal with a divided wavelength, amplifying optical fiber, designed to amplify the output signal of a wavelength division communication device, a second optical detection fiber for transmitting a signal from reflecting the amplified optical signal amplification state as the second output signal of the detection stage to the control circuit, the backscatter cutoff unit of the output stage, designed to cut off the backward stream of the amplified optical signal, the output optical fiber, designed to transmit the amplified output optical signal to the output stage, third optical detection fiber for transmitting a signal reflecting the state of light, repeatedly reflected about from the output optical fiber towards the cutoff node of the backward propagation of light of the output stage, as the third output signal of the detection stage, to the control circuit, and a control circuit for detecting the first, second and third output signals of the detection stage, for controlling the excited light source .  8. The optical amplifier according to claim 7, characterized in that the first output signal of the detection stage is branched from the cutoff unit of the back propagation of light of the input stage to the control circuit, and the second and third output signals of the detection stage are branched from the block of the reverse propagation of light of the input stage to the circuit management.  9. The optical amplifier according to claim 1 or 8, characterized in that the control circuit provides electrical control of the excited light source.  10. An optical amplifier containing an input optical fiber for transmitting an input optical signal to an output stage, a first detection optical fiber for transmitting a signal displaying a state of an input optical signal as a first output signal of a detection stage to a control circuit, a cutoff unit back propagation of light, designed to cut off the reverse flow of the input optical signal, the first optical fiber, designed to output the input optical signal passing through the cutoff unit for backward propagation of light, an excited light source designed to amplify the input optical signal when attenuating the input optical signal, a wavelength division communication device designed to divide the wavelength of the optical signal emitted by the excited light source along with the length waves of the input optical signal and for modulating the signal with a divided wavelength, amplifying optical fiber designed to amplify the output the second signal of the wavelength division communication device, a second detection optical fiber for transmitting a signal displaying the state of the amplified optical signal repeatedly reflected from the first output optical fiber as a second output signal of the detection stage to a control circuit, an optical system for amplified optical signal reverse flow cutoff; second optical output fiber for transmitting the amplified optical output signal and in the output stage, and a control circuit for detecting the first and second output signals of the detection stage for controlling an excited light source.  11. The optical amplifier according to claim 10, characterized in that the first and second output signals of the detection stage are branched from the cutoff unit for backward propagation of light to the control circuit.  12. The optical amplifier according to claim 1 or 11, characterized in that the control circuit provides electrical control of the excited light source.