DE2456293B2 - Method and device for determining the location of faults in optical fibers or optical fiber cables - Google Patents

Description

The present invention relates to a method for determining the location of faults in optical fibers or optical fiber cables, wherein one of a light source, e.g. B. a laser generated light pulse is divided such that it partially coupled into the fiber to be measured and the light component coupled into the fiber at the fault location partially reflected and also passed to a light receiver and the transit time difference to Determination of the fault location is used.

Such a process is already in de * DE-PS 25 33 217 has been proposed. According to this proposed older method is by means of a first Detector, the instantaneous pulse is measured directly and the delayed, in the optical fiber reflected pulse detected with the help of a frequency measurement, including the pulse train of the

is sent impulses is set so that the off The pulse reflected by the optical fiber at the fault location coincides in time with that transmitter pulse. which follows the transmitter pulse causing it, the delay time difference is determined. This is disadvantageous The method is that the two measuring pulses are measured by means of separate detectors and above beyond the detour of a pulse shift by changing the frequency, the transit time difference and so that the fault location can be determined.

Furthermore, from DE-OS 23 18 424 a fault location determination method on electrical cables with the aid of electrical pulses is known in which the fault pulse is detected with the aid of an oscilloscope and the fault location is determined by making a mark pulse visible on the oscilloscope and for so long is shifted until it coincides with the error pulse. The count of a digital encoder that generates the mark pulse is then a measure of the transit time difference. This method is an electrical method, and again, as in the previous earlier patent, the delay time difference and thus the fault location is determined via a detour of a pulse shift by changing the frequency.
Based on the method according to DE-PS 2533 217, the invention is based on the object of improving this method in such a way that the I .aufzeitdiffercnz of the optical start and error pulse is detected directly, a pulse shift by frequency change is not necessary according to the invention achieved in that the two partial pulses are directed to the same light receiver on which the transit time difference is measured directly.
Thus, according to the invention, the start and

w Error pulse passed to the same receiver, there in electrical impulses converted and output for evaluation. Accordingly, according to the invention Difference in transit time between these two pulses measured directly, so that the detour via the t pulse setting on the pulse generator is required.

The way according to the invention is therefore metrological

far simpler than the one as seen in the DE-PS 25 33 217 can be found

In an embodiment of the method according to the invention M) it is advantageous if the light from the laser is perpendicular

to the plane of incidence of one the laser light into the two Partial beams splitting device is polarized. Such a polarization of the light becomes the Reflection of the partial beam on the dividing device * ■> increased so that more light energy is directed into the fiber to be measured, and thus also out of the The light signal emitted from the fiber to be measured is stronger and thus its measurement is facilitated.

To carry out the method according to the invention, a device for determining the location of the fault is used, which consists of a charger serving as a light source, a light separating element arranged in front of this for splitting the light signal into two partial signals, a focusing device between the separating element and the optical fiber, a light receiving arrangement with which the from a Defect in the optical fiber and the partial signal reflected on the separating element is received and an arrangement for determining the transit time difference exists and in which, according to the invention, the light receiving arrangement consists of a single photodiode and the separating element is a partially transparent mirror arranged at an angle of 45 ° to the direction of light propagation, e.g. . B. a plane-parallel glass plate is formed and on the opposite side of the laser's beam splitter in the last-mentioned light beam direction a plane mirror and between the focusing device and the optical fiber to be tested a perfect optical fiber with an end connector zuo. Connection of the optical fiber to be tested is arranged. As can be seen from the structure of this device according to the invention, the light that is reflected on the mirror and the light beam that is coupled into the optical fiber via the connector and reflected at the damaged area falls on the receiving device.

In a further embodiment of the invention, it is advantageous if the mirror has a small reflection factor This measure ensures that the light component reflected on the mirror is weakened so that the difference in light intensity that is called in the amplitude of the light pulses of the two Partial beams, is not too large, which means that a measurement in the receiving device of the two light pulses is facilitated.

It is also advantageous if a mode stripper is arranged at the beginning of the faultless optical fiber is so that only those wave types are coupled into the fiber, in which the leadership through the Fiber core takes place, and thus the coupling of interfering modes is prevented.

So that when measuring the delay time shift of the two partial beams only the position of the eggs to be measured Optical fiber must be taken into account up to the point of failure, it is also useful if the beam path between the glass plate and the mirror and between the glass plate -ad the endsein'g the plug having optical fiber is the same size

The invention is explained in more detail using the exemplary embodiment shown in the drawings It shows

F i g. 1 the schematic / atical structure of an exemplary embodiment a device according to the invention and

FIG. 2 shows the amplitude curve of the two in FIG Receiving device measured TeÜstrahl.

The measuring device shown in the drawing comprises a laser 1, for example a neodymium laser As strong and shorten impulses as possible. That of μ This emitted light is first bundled in a focusing device 2 and falls on one partially transparent mirror, e.g. B. a plane-parallel glass plate 3, which is 45 ° against the incident light beam is inclined. On this glass plate 3, the incident light beam is divided into zv? I partial beams, namely in one that is reflected perpendicular to the direction of incidence and also bundled in a focusing device 4 and from there into an optical fiber 5 with a connector 6 at the end. At the beginning of the optical fiber 5 a mode stripper 7 is provided, which prevents the propagation of interfering modes the faulty optical communication cable to be measured or the individual optical fiber 8 connected. Of the other partial beam emerges with refraction from the plane-parallel glass plate 3 and falls on one of the Laser 1 opposite mirror 9, which should have a small reflection factor. At the mirror 9 is this partial beam reflects and falls in turn on the plane-parallel glass plate 3, on which it is reflected perpendicular to the plane of incidence and on a receiving device 10 This consists in the example shown of a focusing device 11, a Photodiode 12 with connected amplifier 13 and downstream oscilloscope 14; the in the faulty optical fiber β deflected partial beam wildly partially reflected at the fault location and falls behind Passing through the plug 6, the fiber 5, the glass plate 3 also on the receiving device 10. Due to the The delay time difference between the two partial beams registered in the receiving device can easily be the Distance of the flaw in the fiber 8 can be calculated. As can be seen from the following calculation example:

If a refractive index of / 7 = 1.5 is assumed for the glass plate, the reflected intensity Ir is obtained as a percentage of the incident intensity with the help of Fresnel's formulas:

a) The plane of oscillation of the light perpendicular to the plane of incidence:

sin (* + ß)

b) The plane of oscillation of the light parallel to the plane of incidence:

tan (<x

whereby

a - angle of incidence into the glass plate = 45 ° and
β = angle at which the light is refracted in the plate

= aresin (^ U 28.13 °
V "/

mean.

This results in:
Ir ₃ = 0.09 and
/ * p = 0.01.

In the best case (the plane of vibration of the laser generated by the laser 1 is perpendicular to the plane of incidence of the glass plate 3) approx. 9% of the energy is reflected in the direction of the fibers; the losses are 91%.

The following losses occur in the system mentioned:

Place of Vcrluslc

CiriiUe of losses <%) (dh)

Glass plate 91 10.5 lenses
estimated for 3 lenses
passages at optical
compensation 8th 0.4 [■ incoppclvcrluste
into the fiber 70 5.2 Connector l · fiber
For half an amplifier
fcldlängc 40 Reflection on broken 98 17th

16 db

57 db

Under the above conditions, the following light outputs result, if assumed is that 1 W can be coupled into the fiber 8. without it being destroyed:

The above estimate shows that fault location in this way is possible because a Light signal of 2 μW can still be reliably detected.

If the difference in transit time of the two partial beams is determined, then the error distance S ₁ can be determined:

/ c. li-c

• V =

Output power of the laser 1
Coupled power
into the optical fiber 8
At the receiving device
still arriving performance

39 W I VV 2μ \ ν ■ c

In

Mean

/ = Travel time difference between the two partial beams,

C = speed of light,

'"' η - refractive index in the fiber core (effective refractive index),

Δι - pulse expansion of the second partial beam due to the dispersion.

As can be seen from Fig. 2, for example, on the

Oscillographs read off the transit time difference and

also estimate Δ t.
Assuming that the light pulse (length e.g.

I ns) is sufficiently steep and the widening of the in the ; -. Fiber coupled partial beam is approx. ± I ns, then the error location can be found

^{= f IOcm}

do an accurate estimate.

llicr / u 1 sheet of drawings

Claims (6)

Patent claims: 1. Method for determining the location of a fault in optical fibers or optical fiber cables, one of a light source, for example a laser, is divided so that it is partially divided into the fiber to be measured is coupled in and the light component coupled into the fiber is the faulty part partially reflected and also passed to a light receiver and the transit time difference to Determination of the fault location is used, characterized in that the two Partial pulses are directed to the same light receiver on which the transit time difference is measured. 2. The method according to claim 1, characterized in that that the light from the laser is perpendicular to the plane of incidence of the laser light in the two Partial beams splitting device is polarized 3. Device for determining the location of the fault in optical fibers or optical fiber cables, consisting from a laser serving as a light source, a light separating element arranged in front of it for Splitting of the light signal into two partial signals, a focusing device between the separating element and the optical fiber, a light receiving arrangement with which the from a fault location in the Optical fiber and the partial signal reflected on the separating element is received and an arrangement / ur determination of the difference in runtime for execution of the method according to claim 1, characterized in that the light receiving arrangement consists of a single photodiode (* "!) that the Separating element as a partially transparent element arranged at an angle of 45 ° to the direction of light propagation Mirror (3), e.g. B. a plane-parallel glass plate is formed and on which the laser (1) opposite side of the beam splitter in the last-mentioned light beam direction a planar Mirror (9) and between the focusing device (4) and the optical fiber to be tested (8) a « Flawless optical fiber (5) with a plug (6) at the end for connecting the to be tested Optical fiber (8) is arranged 4. Apparatus according to claim 3, characterized in that the mirror (9) has a small one Reflection factor 5. Device according to one or more of claims 3 to 4, characterized in that on A mode stripper (7) is arranged at the beginning of the faultless optical fiber (5) 6. Device according to one or more of claims 3 to 5, characterized in that the Beam path between the glass plate (3) and the mirror (9) and between the glass plate (3) and the end of the plug (6) having optical fiber (5) is the same size