SU1177785A1 - Meter of losses of connector of fibre light guides - Google Patents

Abstract

LOSS OF CONNECTOR OF FIBER LIGHTING CONNECTOR, containing a master generator of electrical pulses, a source of optical pulses, the first Y-splitter of optical fibers, the first segment of the optical fiber with a measurable connector, a photodetector with a logarithmic amplifier and a storage device the output of which is optically connected to the first branch of the first branch, the second branch of which is connected to the photodetector, and the trunk of the first branch is connected to the first a fiber section with a measurable connector, characterized in that, in order to increase the measurement accuracy, a second and third y-fibers of the optical fibers, a second segment of the optical fiber, identical in parameters to the first segment, optical line, delay, are introduced. fiber, two optical attenuators, a cell with an immersion liquid, an electric pulse extender, a two-output electric signal demultiplier, an electric delay line, and an electric signal subtraction device The output of the source of optical pulses is connected to the trunk of the second Y-branch, one branch of which is connected to the input of the optical delay line through the corresponding attenuators and the other branch to the first branch of the first V branch, the output of the optical delay line is connected to the first branch of the third Y RP of a branch, the second (L ra branch of which is connected to the photodetector, the trunk of the third H-coupler is connected to the second segment of the optical fiber, the output end of which and the end of the first segment are placed in a cell, the output of the photodetector The nickname is connected to the information input of the demultiplexer, an output is connected to the control input of the demultiplexer and expand the sl l impu, the input whose input is connected to the generator and the demultiplexer outputs, one through the electrical delay line and the other directly to the device outputs subtraction, with the duration of the delays in the optical and electrical lines for & rccc and the magnitude of the expansion of the pulses equal to the same value equal to half the pulse repetition period of the master oscillator ra, and the lengths of the first and second segments of the fiber are equal to half the length of the third segment of the fiber.

Description

The invention relates to a light guide and can be used to measure the loss of light energy in detachable and one-piece connectors of fiber optical fibers and cables based on them. . . but . . "" -. Rel Isoir | Twead || - The elevation is exactly sd and izMreny. I 1a, fig.) FenCTa ffiAa structural gs f i schema; s1 1rit SINTER4 fiber connector CB.eT, paQjpoB; Wah FIG. 2 temporary agr .aI 4ths pb removing the work of “yayo ytel. The meter (figure 1) contains a source of optical pulses, the master oscillator 2 electric them. pulses, expander 3 pulses, photo receiver 4 with a logarithmic amplifier and drive, demultiplexer 5 electrical signals, optical delay line in the form of a fiber 6, Y-splitters 7-9 optical fibers, cutting the reference fiber 10, the segment of the optical fiber 1 1 with measure connector 12, optical attenuators 13, an immersion cuvette 14, an electrical delay line 15, an electrical signal subtraction device 16. In addition, the device contains a source 17 of the reference voltage, a calibrated attenuator 18, and a comparison device 19 with an indicator. . The meter works as follows. A sequence of optical pulses with a duration G and a period T (and moreover) is inserted into the optical fibers 10 and 11 with the help of τ-branching 7-9. The optical fiber 10 is a standard optical fiber, the optical fiber 11 contains a connector at a fixed distance from the input measure Both fibers 10 and 11 have the same parameters (numerical aperture, core and cladding diameters, eccentricity, attenuation and distribution of the refractive index along the radius). Both fibers also have the same length. At sufficient power The radiations of a pulse (20-100 mW) in fibers 10 and 11 produce a noticeable backscatter radiation, which is determined by the losses in them and in connector 12. In order for the backscatter signals corresponding to the reference AND measured fiber, divided in time, radiation is fed into the reference fiber through a segment of optical fiber 6, the length of which is 2f. This segment plays the delay line for time 0.5T. Optical fluxes of the same power should be introduced into optical fibers 10 and 11. At the same time, losses occur in the segment of the light guide 6, and the splitter 7 divides the flows into two equal parts. In order to ensure that light fluxes of the same power are inputted into the optical fibers 10 and 11, optical pulses are introduced into the nick through optical attenuators 13. To eliminate reflections from the ends of the optical fibers, they are immersed in the cell 14 with the immersion liquid. The backscattered radiation from the optical fibers 10 and 11 is transmitted by splitters 8 and 9 to a photodetector 4 having a photodetector a broadband amplifier with a logarithmic characteristic and a storage device. From the output of the photo-receiver 4, the signal is fed to the information input of the demultiplexer 5. Switching pulses from expander 3 are fed to its control input. The duration of these pulses is 0.5T. From one of the outputs of the demultiplexer 5, a signal corresponding to the radiation from the backward scattering of the measured optical fiber 11 with the connector 12 is fed to the subtractor 16 via the delay line 15. The delay time is chosen to be 0.5T. From the second output of the demultiplexer 5, a signal corresponding to the radiation of the backscattered light guide 10 is fed to the input of the device 16 without delay. The assignment of the electric delay line 15 to displace in time the signals corresponding to the backscattered radiation in the optical fibers 10 and 11. The differential signal in the device 16, corresponding to the magnitude of the losses in the connector 12, is rectified and fed to. one of the inputs of the device 19 comparison. At its second input, through a calibrated attenuator 18, a reference voltage is supplied from source 17. The measurements are made in the following order. The outputs of the splitters B and 9 are alternately connected to a power meter and using the attenuator 13 to set the same power. After that, the optical fibers 10 and 11 are connected to the splitters 8 and 9. Both the splitters and the input ends of the optical fibers 10 q 11 are provided with identical connectors. The equality of the power introduced into the optical fibers 10 and 11 can be verified by the equality of the leading edges of the signals when observed on an oscilloscope. In this case, the indicator in the comparison device 19 is set to zero using an attenuator 18. The indicator is also set to zero before being connected to the taps 8 and 9 of the optical fibers 10 and 11. When optical fibers 10 and 11 are connected to them, the balance is disturbed. With the help of an attenuator 13, the indicator reads zero again. By difference

the indications of the attenuator limbs 13 determine the attenuation in the connector.

In figure 2 are marked: a) - a sequence of optical pulses; b) —the backscattering curves alternating with period T, corresponding to the pulses in the fiber with a connector and in the reference fiber ;. c) a signal corresponding to the backscattering curve in a fiber with a connector; (d) a signal corresponding to the backscattering curve from a reference fiber; e, the signal corresponding to the backscattering curve in the fiber with the connector, delayed by time -j-Ti e) is the differential signal between the guide corresponding to the loss in the connector generated by the subtractor 16.

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Claims (1)

FIBER LIGHT CONNECTOR LOSS MEASURER, comprising a driving pulse generator, an optical pulse source, a first U-fiber splitter, a first segment of a fiber with a measurable connector, a photodetector with a logarithmic amplifier and a drive, the generator being connected to an optical pulse source, the output of which connected to the first branch of the first Y ~ splitter, the second branch of which is connected to the photodetector, and the trunk of the first The U-splitter is connected to the first segment of the fiber with the measuring connector, characterized in that, in order to increase the accuracy of measurements, the second and third U-splitters of the optical fibers are inserted into it, the second segment of the fiber, identical in parameters to the first segment, an optical line. delays .... in the form of a third segment of the fiber, two optical attenuators, a cell with immersion liquid, an electric pulse expander, an electric signal demultiplexer for two outputs, an electric delay line and an electrical signal subtractor, while the output of the optical pulse source is connected to the barrel of the second Y-raz.vetvitelya one branch which via respective attenuators connected to the input of an optical delay line, and the other - with a first branch of the first Y -razvetvitelya, optical output · _'l l the delay line is connected to the first <S branch of the third Y-splitter, the second branch of which is connected to the photodetector, the trunk of the third Y-splitter is connected to the second segment of the fiber, the output end of which and the end of the first segment are placed in the cuvette, the output of the photodetector is connected to the information input of the demultiplexer, the output of the pulse expander is connected to the control input of the demultiplexer, the input of which is connected to the generator, and the outputs of the demultiplexer, one through the electrical delay line and the other directly, are connected to the outputs of the subtraction device, and the duration of the delays in the optical and electrical delay lines and the magnitude of the expansion of the pulses are the same value equal to half the pulse repetition period of the master oscillator, and the lengths of the first and second lengths of the fiber are half the length of the third length of the fiber. SU „„ 1177785 1 1177785 2