DE10342339A1 - Test system and test method for fiber optic fiber optic cables - Google Patents

Abstract

The The invention relates to a test system for fiber optic Optical waveguide (10), which at a front end fiber end (12) designed for coupling or decoupling of radiation to be transmitted are, with a test transmitter (14) for irradiating the fiber end (12) with test radiation (30). To go through a simple non-spatially resolved Measurement of the surface quality of the fiber end (12) to be able to vote are a radiation detector according to the invention (16) for detecting diffuse and / or thermal reverberation (34, 38) of the fiber end (12) and an evaluation unit (18) for Processing of an output signal of the radiation detector (16) is provided.

Description

The The invention relates to a test system for fiber optic Optical waveguides, which are connected to a front-side fiber end or decoupling from to be transferred Radiation are preferably formed as a plug end face, with a test transmitter for irradiation of the fiber end with test radiation. The invention relates further a corresponding test method.

A optical connector usually consists of two pins, the above a clutch merged so be that their forehead against each other. For as possible lossless connection must the fiber cores are exactly opposite each other and damage or Contamination of the connector end faces are avoided. contaminated or damaged optical connectors are a major problem of the fiber-bonded optical transmission technology. Across from an intact connector they cause increased damping and / or Reflections that worsen the system properties up can lead to failure. Work the systems In addition, even at high powers, so cause contamination so-called "hot Spots ", the one thermal destruction of the Plug can result. Such high powers are typical of high-channel DWDM systems, for Raman-enhanced long-haul systems also for Fiber-coupled processing and High power analysis laser.

to exam Such connectors are transmissive measurements of insertion loss and reflection loss known. However, such measurements require an isolatable test object, and it must be measured against a second plug. alternative become visual inspections of the test light illuminated fiber end performed under a microscope, for the Although no reference plug required is not, however, does not capture certain absorption effects in any case are eye safe and due to the subjective evaluation too Lead to misjudgments can. To at least partially circumvent these problems, there are also imaging systems known to be an interpretation of a digital connector image via a Provide image processing software, but very expensive are.

outgoing This is the object of the invention, which in the state of Technology to avoid the disadvantages and also in the handling simple and reliable System or method for quality analysis specify optical connector.

to solution This object is achieved in the claim 1 or 21 specified combination of features proposed.

The Invention is based on the idea, the connector impairments attributed to elementary physical causes and then directly to eat. Accordingly, a radiation detector according to the invention for not spatially resolved Detection of the diffusely scattered and / or thermal reflection from the fiber end and an evaluation unit for processing a Output signal of the radiation detector proposed. damage the surface effect changed Impact angle of the test radiation and thus a scatter outside of the regular Reflection angle. This diffuse portion is thus a measure of the damage to the Plug surface. For deposits on the test surface occurs an absorbent component and causes a local temperature increase, which over a Detection of the thermal reflection, i.e. the radiated into the half space of the transmitter or detector Radiation is detected. This makes it possible in a simple way, a objective test result to deliver, with the measurement even with one-sided access to only a plug end and eyesafe is feasible. In addition, the leaves thermal measurement a direct inference to the usability at high transmission rates to.

advantageous Refinements and developments of the invention will become apparent the dependent Claims.

in the The following is the invention with reference to the in the drawing in FIG simplified illustrated embodiments explained in more detail. It demonstrate

1 an optical connector for coupling the fiber ends of two fiber optic cables in a broken axial section;

2 a test system for inspecting a fiber end in a side view;

3 a further embodiment of a test system in the plan view of the fiber end; and

4 a block diagram of the test system.

The test system for optical fiber optic cables shown in the drawing 10 enables a surface inspection of the fiber ends intended for connectors 12 , It essentially consists of a test transmitter 14 for loading the fiber end 12 with electromagnetic test radiation or test light and a radiation detector 16 for the detection of stray radiation and ther mixer re-radiation from the fiber end 12 and an evaluation unit 18 for Signalver processing and arithmetic evaluation of the integrity of the fiber end.

At the in 1 shown optical connector are two fiber cables 10 via end-to-end connector pins 20 in a coupling sleeve 22 so interconnected that through the connector end faces 24 formed fiber ends 12 for butt lossless signal or radiation transfer butt against each other. It should be through a coat 26 enveloped light-conducting fiber cores 28 be aligned exactly with each other, without any damage or deposits on the connector end face 24 cause unwanted high attenuation and / or reflections.

To test this, be in accordance with 2 the effects of plug interference on the free fiber ends 12 or connector end faces 24 by measuring the irregular scattering and / or absorption of electromagnetic test radiation 30 detected. For this purpose, the radiation detector 16 at least one sensor 32 for detecting diffuse reflection 34 and / or at least one sensor 36 for the detection of thermal reflection 38 on. This arrangement is based on the consideration that surface damage to the connector end face 24 changed angles of incidence and thus diffuse reflections of the test radiation 30 to cause solid angles other than just the normal angle of reflection, while deposits on the face 24 in addition to the described scattering effect, an additional absorption and conversion of the incident radiation 30 in detectable heat radiation 38 cause.

The test transmitter 14 is designed to the optical test radiation 30 bundled on the test surface 24 to throw. In order to obtain a sufficient power density for the thermal measurement, a semiconductor laser is preferably used as the light source 40 used, for cost reasons, for example, laser diodes in the visible or near infrared range. Optionally, a focusing optics, not shown, can be used, in particular the relevant area of the light-guiding fiber core 28 to irradiate.

According to 4 is to capture the optical scattered light via a focusing optics 42 on the fiber end 12 aligned photosensor 32 provided while the thermal radiation via a focusing unit 44 and a pyroelectric sensor 36 is detected.

The control of the light source 40 via a driver stage 46 the test transmitter 14 , The sensor output signals are via amplifier units 48 . 50 into the evaluation unit 18 fed. In order to improve the signal-to-noise ratio and to suppress ambient light, the driver stage 46 for modulating the light source 40 be trained while the amplifier 48 . 50 be turned on synchronously, for example via a lock-in stage. A reference value memory 52 contains calibration or limit values for a signal comparison in the evaluation unit 18 , Alternatively or additionally, in the evaluation unit 18 a program routine for computational determination of a quality criterion to be loaded. The evaluation result is via an advertisement 54 for example, as a good / bad evaluation of the fiber end 12 represented. The entire measuring arrangement can be in a device housing 56 be installed, with the plug end 20 in a receiving socket 58 is positionable in the desired orientation.

According to the in 3 shown embodiment, multiple photosensors 32 over a solid angle range, for example, annularly distributed at a distance from the connector end face 24 be arranged. The scope of the photosensors should be 32 outside the regularly reflected proportion 60 the test radiation 30 lie. It is also possible, the directly reflected radiation 60 to suppress by not shown polarization filter. Due to the multiple detection in different sectors, distortions of the measurement due to stray light beams, such as scratches or polishing marks on the surface 24 be broadcast in certain preferred directions, rather avoided. Spatially integrating detection or direction-independent measurement of the scattering can also be achieved in that the hemispherically scattered radiation 34 directed via optical reflections on a radiation detector. Parabolic mirrors, ellipsoids or integrating spheres can be used for this purpose. In order not to falsify the measurement result, the regularly reflected radiation component for the measurement should also be hidden here.

In reversal of the beam path described above, it is conceivable that the test area 24 to illuminate with a plurality of, for example, annularly arranged light sources and to detect the return radiation with an axially aligned central radiation receiver. Such an arrangement offers the additional possibility of using the system as an optical power meter. In addition, higher illumination powers are possible by adding a plurality of light sources, so that a higher measurement sensitivity can be achieved in the thermal measurement.

In a development of the sector-oriented detection, the free-jet coupling of the test light can be replaced by an irradiation via optical fibers. This will be either one central illumination fiber arranged a plurality of receiving fibers, or vice versa about a central detection fiber a plurality of illumination fibers. The coupling to the plug or fiber end to be examined 12 Then done via an applied micro-optics with a central focusing lens and an annular beam deflection. Such an arrangement has the advantage that even within plug sockets 22 can be measured.

The quality criterion is the scattering factor of the surface 24 of importance, which by definition results from the ratio of the diffuse fraction to the total fraction of the reflection as a value between 0 and 1. If the power of the incident light beam is measured and multiplied by a reflection factor, which depends in a known manner on the refractive index difference and the angle of incidence, then the total reflection component. The scattering factor can then be determined by computation using the amount of scattered material detected by the measurement. Alternatively, a calibration can be performed by a reference measurement on a reference plug, which has, for example, a perfectly flat or a perfectly diffuse end face.

The thermal measurement is based on the fact that deposits on the connector end face 24 absorb part of the test light and convert it into heat. The determination of the absorption is thus attributed to a measurement of the temperature increase during irradiation. The temperature increase can be either over the wavelength maximum of the thermal radiation 38 be determined according to Wien's displacement law or determined via a (broadband) power measurement in accordance with the Planck radiation law. Since the temperature radiation is always non-directional, can be measured with a detector in any arrangement. In order to increase the measuring sensitivity, however, it makes sense to record the largest possible solid angle range, which is in favor of the sensor 36 either as close as possible to the fiber end 12 to bring and / or to choose a short focal length picture. The determined temperature increase and derived therefrom the absorption factor is then the measure of the surface contamination or the decreasing with the increase in temperature surface quality.

In summary, the following should be noted: The invention relates to a test system for fiber optic optical fibers 10 , which at a front end fiber end 12 are designed for coupling or decoupling of radiation to be transmitted, with a test transmitter 14 for irradiation of the fiber end 12 with test radiation. By a simple non-spatially resolved measurement, the surface quality of the fiber end 12 to be able to determine, according to the invention, a radiation detector 16 for detecting diffuse and / or thermal reflection from the fiber end 12 and an evaluation unit 18 for processing an output signal of the radiation detector 16 intended.

Claims (21)

Test system for fiber optic fiber optic cables ( 10 ), which at a front end fiber end ( 12 ) for coupling or decoupling radiation to be transmitted preferably as a plug end face ( 24 ), with a test transmitter ( 14 ) for irradiation of the fiber end ( 12 ) with test radiation ( 30 ), characterized by a radiation detector ( 16 ) for detecting diffuse and / or thermal reflection ( 34 . 38 ) from the fiber end ( 12 ) and an evaluation unit ( 18 ) for processing an output signal of the radiation detector ( 16 ) as a measure of the surface quality of the fiber end ( 12 ). Test system according to claim 1, characterized in that the radiation detector ( 16 ) for detecting the diffuse scattered reflection ( 34 ) in the wavelength range of the test transmitter ( 14 ) and for detecting the thermal reflection ( 38 ) in a longer wavelength range than the test transmitter ( 14 ) is working. Test system according to claim 1 or 2, characterized in that the radiation detector ( 16 ) at least one optical sensor ( 32 ) for detecting diffuse reflection ( 34 ) in the wavelength range of 0.2 to 2 microns, preferably in the visible wavelength range. Test system according to one of claims 1 to 3, characterized in that the radiation detector ( 16 ) at least one preferably via a focusing optics ( 42 ) on the fiber end ( 12 ) aligned optical sensor ( 32 ) having. Test system according to one of claims 1 to 4, characterized in that a plurality of optical sensors ( 32 ) are distributed over a solid angle range. Test system according to one of claims 1 to 5, characterized in that the radiation detector ( 16 ) a formed in particular as Ulbricht sphere or parabolic mirror collective reflector for the diffuse optical reflection ( 34 ) having. Test system according to one of claims 1 to 6, characterized in that the radiation detector ( 16 ) at least one thermal sensor ( 36 ) for detecting thermal reflection ( 38 ) in the wavelength range of 2 to 20 microns. Test system according to one of claims 1 to 7, characterized in that the radiation detector ( 16 ) one on an imaging optics and / or a short distance to the fiber end ( 12 ) oriented thermal sensor ( 36 ), in particular a pyroelectric sensor element. Test system according to one of claims 1 to 8, characterized in that the test transmitter ( 14 ) as a point light source ( 40 ), preferably formed as a semiconductor laser or light emitting diode. Test system according to one of claims 1 to 9, characterized in that the test transmitter ( 14 ) via focusing agent on the fiber end ( 12 ), preferably on its core ( 28 ) is focused. Test system according to one of claims 1 to 10, characterized in that the test transmitter ( 14 ) in which of the optical waveguide ( 10 ) remote half-space area over a free jet distance at a distance from the fiber end ( 12 ) is arranged. Test system according to one of claims 1 to 11, characterized in that the test transmitter ( 14 ) and / or the radiation detector ( 16 ) via associated coupling fibers to the fiber end to be examined ( 12 ) are coupled. Test system according to one of claims 1 to 12, characterized in that the test transmitter ( 14 ) a plurality of test-light sources, in particular annularly distributed over a solid angle range ( 40 ) for irradiation of the fiber end ( 12 ) having. Test system according to one of claims 1 to 13, characterized in that the radiation detector ( 16 ) a filter designed in particular as a polarization filter or blocking filter for suppressing the regularly reflected component (US Pat. 60 ) of the test radiation ( 30 ) and / or upstream of the separation of the optical and thermal reflection component. Test system according to one of claims 1 to 14, characterized in that the radiation detector ( 16 ) outside the reverberation range of the regularly reflected portion of the test radiation ( 30 ) is arranged. Test system according to one of claims 1 to 15, characterized in that the test transmitter ( 14 ) a modulation stage ( 46 ) for time-varying radiation generation. Test system according to one of claims 1 to 16, characterized in that the radiation detector ( 16 ) one with a modulation of the test transmitter ( 14 ) synchronized amplifier stage ( 48 . 50 ) having. Test system according to one of claims 1 to 17, characterized in that the evaluation unit ( 18 ) a reference value memory ( 52 ) and a comparator for signal comparison with a reference value determined preferably at a reference plug. Test system according to one of claims 1 to 18, characterized in that the evaluation unit ( 18 ) a program routine for the computational determination of the scattering factor and / or the absorption factor of the fiber end ( 12 ) having. Test system according to one of claims 1 to 19, characterized in that the evaluation unit ( 18 ) an ad ( 54 ) for the evaluation result preferably as a qualitative good / bad rating. Test method for fiber optic fiber optic cables ( 10 ), which at a front end fiber end ( 12 ) are formed for coupling or decoupling of radiation to be transmitted, wherein the fiber end ( 12 ) with test radiation ( 30 ) is acted upon, characterized in that diffuse and / or thermal reflection ( 34 . 38 ) from the fiber end ( 12 ) by a radiation detector ( 16 ) is detected, and that an output signal of the radiation detector ( 16 ) as a measure of the surface quality of the fiber end ( 12 ) is evaluated.