SE444731B - DEVICE FOR DETERMINATION OF THE DIMENSION OF LIGHT FIBER FIBERS - Google Patents

Description

? 9Û? 'W * ¿f-6 z 10 15 20 25 30 35 4ó_ - HQV is switched on in a fiber, and the returned light is returned via a beam splitter to a multiplier photodiode. After broadband amplification improves the signal-to-noise ratio of the return signal in a pulse extension integrator. In the case of an interconnected logarithm formatter can on an XY printer, whose ordinate is expressed in dB and whose abscissa is expressed in km, a curve is recorded, the slope of which directly, indicates the quadruple fiber attenuation in dB / km. Signal the action by means of the pulse extension integrator is necessary to due to the poor signal-to-noise ratio of the return signal.

For a compact and not too expensive measuring device, however the use of a pulse extension integrator is inappropriate due to of the high manufacturing cost. In addition, they have on the market existing pulse extension integrators a relatively strong initial operation, which at low signal levels of 10 mV results in a impermissible distortion of the measurement results. Instead of a pulse extension integrator, a sampling oscillator has also been used. cup with slow deflection. However, such an oscilloscope has the disadvantage that the available sampling heads only allows relatively short gate times and that a change of gate time requires head replacement. Y The present invention aims at starting from from a reflectometer of the type initially indicated will be a device that is characterized by simple and affordable building and thereby allows very high measurement accuracies, so that in particular, a local resolution of 1 m is obtained in the event of a measurement error of a maximum of 0.2 dB / km and a minimum measurement time. In doing so, the necessary The average measurement time is kept within certain limits to enable an E fast fault location out in the field and an accurate measurement of fiber laboratories.

According to the invention, this object is achieved by signal processing the vlar consists of a sample-and-hold circuit, by means of which it passes through a trigger pulse periodically triggered return signal is sensed. Thereby preferably the control signal for the sample-and-hold circuit is recovered with the aid of two ramp generators, the ramp for one, whose length corresponds to the selected time window, corresponds to resp. trigger pulse and the ramp for the other, the length of which corresponds to the set measurement length of time, is started by a button. At each intersection between the ramps, a sampling control is generated by means of a comparator. signal, which is slowly shifted relative to the trigger pulse and whose output triggers a square pulse with adjustable width. The output signal _ _. .v ism.,. ~ »-¿.fiswaaqw_ ~ ew« ww ~ éáa ~ e <æszsïïv ~ 10 15 20 25 30 35 40 ".....» ... @ ~ .- varann ~ 79071í55 * 6 -....> ...... l ~ ..,. . ,, .... v, «" '<\' ^ "" '' vw 3 equalized by averaging by means of an RC circuit to achieve of an improved signal-to-noise ratio. As a light source was used preferably a laser module. Furthermore, it is appropriate, if the trigger pulses for the laser module and the ramp generators are generated by a pulse generator, which enables a temporal displacement of the pulses relative each other. thus providing a reflectometer ,, a sample-and-hold circuit can be produced and suitable for the treatment of variable resolution (gate width). According to According to the invention as through the use of very simple and cheap very weak signals with According to the invention, the gate time is variable, which is made possible by simple switching, whereby the gate time control is achieved by pulse width ~ changing a control pulse for the sample-and-hold circuit. Further an advantage of the invention consists in that further control pulses can be obtained by means of the internal pulse generator, for example for regulation, so the reflectometer can be extended for higher accuracies. _ The invention is explained in more detail below with reference to attached drawings. I _ Fig. 1 shows a block diagram of a reflectometer ~ according to the invention; V V ut Fig. 2 shows a block diagram of the one according to the invention .use signal processing electronics; Fig. 3 illustrates the displacement of the sampling control pulses; and Figs. 4 a and b show a wiring diagram of the signal processing the electronics and the pulse generator according to the invention.

Fig. 1 shows a block diagram of the apparatus according to the finding. In this case, light pulses are generated by one of a pulse generator 1 triggered laser module 3, which light pulses have a short duration and high intensity. These pulses are introduced into a fiber optic fiber 6, and the light returned by scattering is supplied via a beam splitter 7 a photodiode 8, preferably a multiplier-i photodiode. A light guide branch was used as the beam splitter. One more connected amplifier 9 has a large bandwidth at low self-noise. For signal processing is applied to the amplified, the signal a sample and-hold circuit 10 with an averaging image ll connected thereto.

The function of the device, in particular as regards the control unit 2, shall: is now explained with reference to Figs. 2 and 3. It is triggered by a pulse periodically triggered return signal is sensed by sample and-hold circuit lO. At slow sweep speed enables one -Wp www ~~.-R 7907153-6 lo 15 '20 25 Aso 355 40 formation in the RC circuit 11, which corresponds to the averaging _flanker triggered monostable rocker IC3 generates the actual trigger Å denotes a high-ohmic operational amplifier, whose output voltage '"“ "" "" W' "" '' WW WW '.-- ~ W, _, m w "w v _ P ~« m4 multiple sensing of each curve point a signal average c ll in the coupling in Fig. 1. An improvement of the sgnal-noise ratio. The control unit 2 for the sample-and-hold circuit i consists of two ramp generators 14 and 15, one ramp, whose length corresponds to the selected time window, i.e. at least the return signal is triggered by resp. trigger pulse, while the other the ramp, the length of which corresponds to the set measurement time, is triggered by means of a push button. For each intersection between the ramps, 3, the comparator 16 emits a sampling control signal which is slowly in relation to the trigger pulse, as shown of Fig. 3. The gate time of the coupling is determined by its length of the sampling control signal triggered, generated in the pulse generator 13 see fig. shot pulses.

Fig. 4 shows a circuit diagram of the pulse generator 1 and the signal processing electronics in detail. One such as needle pulse generator connected monostable rocker ICla triggers with its negative flank a monostable flip-flop IClb, at the output of which a square pulse ( available), the repetition rate of which is determined by C1, R1, R2 and whose pulse width is determined by C2, R3, R4. Drivers_7 ' IC2a and IC2b ensure a low output resistance and necessary g separation of the pre-trigger and internal outputs. One of the negative ¿ the pulse, the width of which can be set by means of C3, R7 and R8. For adaptive to SOSÄ electronics serves an open-collector gate ICZC together with a subsequent transistor stage.

The pulse generator emits square pulses with a repetition frequency at 2 - 10 kHz, a width of 100 - 500 ns and an amplitude of 0 - 6V at 501ï¿ The delay between the front flank and the trigger and the pre-trigger pulse is adjustable at 0.5 - 2_ps, whereby the jump time is less than the lens, so that a time shift between the triggers the pulses for the laser module and the signal processing electronics are Possible. Oh To generate the ADR ramp voltage, a capacitor is charged, C11 via an adjustable constant current source from T2, T3 and R17. JJ5 compared to IC6 with a fixed voltage of 5 V. If the ramp voltage is reaches this value, the comparator output jumps to high potential and brings via the flip-flop IC7 made up of four NAND gates field power transistor T4 to conduct, discharging capacitor1C11. 10 15 20 25 30 .connects the constant current source from capacitor C18. This process The control signal.-This ~ triggers both a circuit with the properties kr.-. 5 7901153-6 H \ ívw V 'iv E? \ For controlling the transistor T4 with voltages of -10 V resp. -2V at the latter voltage is not selected higher for the avoidance of strong oscillations) is arranged a circuit consisting of IC4, D1, R13 and Rl4. D2, R55 and R16 have protection function Blocking of T4 and thus the start of a new ramp is triggered by a positive trigger pulse on the recovery the input input of the flip-flop IC7. The sweep ramp generator consists of one constant current source (TS, T6, R24), capacitor Cl8 and operational amplifier IC11. When a ramp voltage is reached 5 V connects the comparator IC12 via an OR gate ICQ to a flip-flop (IC8a, IC8b) and a drive circuit (IC10a) a reed relay B, the contact b can also be triggered by an nLedl stop button at any ramp voltage. If the ramp voltage is less than 5 V, the start button allows the contact b closes and thus the capacitor voltage rises further.

The charging of capacitor C18 takes place by means of a reset button "resetP. R22 and C17 serve to suppress high frequency interference pulses on the output of the comparator IC 12. Reed relay A provides a switch-on delay for the supply of the ADR constant current source voltage. The scanning process is indicated by means of an LED.

The comparator IC13 emits for each point of intersection between them both ramps a voltage jump, which constitutes the actual sampling corresponding to a monostable rocker according to Schottky technology IC15 (gate time 10 ns) as well as a conventional monostable rocker IC16 (gate times 50, 100, 500 ns) 1 Depending on the gates tide is connected either the output of one or the output of the other mono- stable flip-flop through a multiplexer IC17 via a 50-nings cable drive circuit IC18 at the control input of the sample-and-hold circuit IC14.

The equalization of the gate output takes place by means of a line drive circuit IC19.

The output signal from the sample-and-hold circuit IC14 is output after averaging in R32, C26 via the operational amplifier IC20V to the output either_directly or via a logarithm circuit IC21. \

Claims (6)

PATENT REQUIREMENTS Apparatus for determining the attenuation of fiber optic fibers by measuring reflected light radiation, comprising a light source (1), a beam splitter (7), a detector (8), an amplifier (9), one of a sample and holding circuit (10) consisting of a signal processor and an indicating apparatus and associated control units, characterized in that the signal processor (10) is arranged to sense a return signal which originates from radiation returned by scattering and which is periodically triggered by a trigger pulse, that the signal processor (10 ) is controlled by a control signal obtained by means of two ramp generators (14,15), the ramp for one (14), the length of which corresponds to a selected time window, being started by resp. trigger pulse, while the ramp for the second (15), the length of which corresponds to the length of the set measuring time, is started by means of a button, and for each intersection point between the ramps a sampling control signal (13) is generated by means of a comparator (16), which slowly shifts relative to the trigger pulse and whose output signal: F triggers a square pulse with adjustable width. in Device according to claim 1, characterized in that said output signal is equalized by means of a queuing circuit (11), Device according to Claim 2, characterized in that the smoothed output signal is applied to a logarithmic generator (12). Device according to one of Claims 1 to 3, characterized in that the light source designed as a laser module (3) and the ramp generators (14, 15) are controlled jointly by a pulse generator (1). Device according to Claim 4, characterized in that the pulse generator (1) enables a temporal displacement of the trigger pulses for the laser module (3) and the control unit (2). Device according to one of Claims 1 to 5, characterized in that the beam splitter (7) consists of a light guide branch.