NL1036720C2 - METHOD AND SYSTEM FOR TESTING A CABLE TREE WITH AT LEAST TWO OPTICAL FIBERS. - Google Patents

Description

Method and system for testing a cable harness with at least two optical fibers

The present invention relates to a method and a system for testing a cable harness with at least two optical fibers.

Fiber optic cable harnesses are used, for example, in so-called Fiber To The Home projects (FTTH) and Fiber to the Office projects in which individual residential / residential units are provided with a connection to an optical communication network, for example a fiber optic network. With the Fiber to the Home projects, two optical fibers must be laid between a central and the home for each home to be connected. To that end, a central cable with, for example, 96 optical fibers is laid from the central to a branch point. Branch cables with two optical fibers are then laid from the tapping point to each of the homes to be connected. This creates a one-wire cable harness with 96 fibers at the power station and with 48 fiber-optic ends at each of the dwellings to be connected.

When laying the cable harness, different connections between optical fibers must be made, for example, the fibers of each branch cable 25 must be connected to fibers of the central cable.

An incorrect connection only comes to light when a user does not receive a service offered over the communication network for which he has registered. This results in a dissatisfied user.

The present invention has for its object to reduce this drawback.

To achieve this goal, the method according to the present invention comprises the following steps: 1036720 - introducing an optical signal into a first optical fiber at a proximal end of the cable harness; - reflecting at a distal end of the cable harness 5 at least a portion of the optical signal emerging from the first optical fiber into a second optical fiber; and - detecting the reflection of the optical signal at the proximal end of the cable harness at a suspected end of the second optical fiber 10.

These steps make it possible to test whether the fibers of the branch cables are properly connected before connecting the branch cables to a house. In the exchange, for example, simply an optical signal 15 can be introduced into a first optical fiber. This optical signal is then routed through the first optical fiber via the central cable to the end of a branch cable that is not yet connected to a house. There, the optical signal is reflected in the second optical fiber 20 of the branch cable and the optical signal is guided through the second optical fiber again towards the center. By detecting the optical signal in the center at the suspected end of the second optical fiber, it can be determined whether the two optical fibers of one branch cable are properly connected. If the optical signal is not detected, a wrong connection is made in the cable harness. The wrong connection can then be repaired before the optical fibers of the relevant branch cable are connected to a house. This has the advantage that the user is not hindered by a possible wrong connection.

Because the method according to the invention can be carried out during the laying of the cable harness, in addition to the fact that the cable harness is laid underground, the method also has the advantage that the cable harness does not have to be partially dug up to restore the wrong connection, so that subsequent repair costs can be avoided.

The application of the principle of reflection makes it possible, moreover, that the activities that have to be carried out at the end of the cable harness where the reflection takes place in order to carry out the method according to the invention can be small. Cut optical fibers at that end of the cable harness, for example, do not have to be processed and connected to special measuring equipment.

In a favorable embodiment of the method according to the invention, the step of reflecting comprises scattering of the optical signal. This measure makes it possible to increase the chance that a portion of the optical signal is introduced into the second optical fiber. This measure therefore has the advantage that it makes a positive contribution to the reliability of the method according to the invention.

In a further favorable embodiment of the method according to the invention, the optical signal is generated by means of laser light. The optical fibers between the central and each residential home are long, for example two kilometers. This means that when performing the method according to the invention, the optical signal must travel two times two kilometers through the optical fibers. Both during propagation through the optical fibers 30 and at mid-reflection, the optical signal loses power. The use of laser light makes it possible to generate an optical signal that after the propagation through the optical fibers and the reflection 4 is sufficiently powerful to be able to detect this signal at the suspected end of the second optical fiber. The advantage of the use of laser light is therefore that a positive contribution is made to the reliability of the method according to the invention. In a particular embodiment thereof, the laser light has a wavelength in the range of substantially 400 nm to substantially 1600 nm, such as 500, 600, 700, 800, 900, 1000, 1100, 1200, 1300, 1400, 1500, 1600 nm. It has been found that laser light with a wavelength can generate an optical signal in this region that is sufficiently powerful to reliably carry out the method according to the invention under various conditions. In a further particular embodiment thereof, the laser light has a wavelength in the range of substantially 632 nm to substantially 675 nm, such as 632, 635, 638, 640, 645, 650, 658, 670, 675 nm. It has been found that with laser light with a wavelength in this area it is possible to carry out the method according to the invention particularly reliably under various conditions.

The present invention also relates to a system for testing a cable harness with at least two optical fibers, comprising - a testing device comprising: - an optical signal generator that can be connected to a first optical fiber at a proximal end of the cable harness; and - an optical sensor that can be connected to a suspected end of a second optical fiber at the proximal end of the cable harness; and - a reflector that can be arranged at a distal end of the cable harness.

5

With this system according to the invention, it is highly desirable, during the laying of the cable harness, to test before the connection of the branch cables to a residential house whether the fibers of the branch cables are properly connected. For example, a reflector can be provided on each end of a branch cable not connected to a house. The optical signal generator can then be connected to a first optical fiber and the optical sensor can be connected to the presumed end of the second optical fiber which is included in one branch cable together with the first optical fiber. After activation of the test device, it generates an optical signal, inserts it into the first optical cable and detects the optical signal in the suspected end of the second optical fiber. When the optical signal is not detected, the optical fibers of the relevant branch cable are incorrectly connected. The wrong connection can then be restored before the optical fibers of the relevant branch cable are connected to a TOon housing. This has the advantage that the user is not hindered by a possible incorrect connection.

Also with the system according to the invention TSi from the central station the connection of the fibers of each of the branch cables can be tested. This has the advantage that the complete cable harness can be tested quickly and easily from one location.

Moreover, with the system according to the invention it is possible, for example, to temporarily store a branch cable not yet connected to a dwelling house with a reflector 30 thereon underground and to test whether the fibers of the branch cable are still properly connected to the central. The temporary subsurface 0 | b storage of a branch cable not yet connected to a household is used, for example, when not all residents of the residential homes want a connection when laying the cable harness. The branch cable for a dwelling house that is not yet connected is then already stored underground near the dwelling house, so that when a later resident does want a connection, the dwelling concerned can easily be connected. With the system according to the invention it is then possible to determine whether the fibers of the branch cable are (still) well connected before digging up and connecting the branch cable 10 stored underground. This has the advantage, for example, that all the work required to establish the connection, including any repair work, can be determined in advance.

In a favorable embodiment of the system according to the invention, the optical signal generator comprises a laser generator. This measure makes it possible to generate an optical signal that can be guided through the optical fibers with minimal losses and that can be reflected. This measure therefore has the advantage that it makes a positive contribution to the reliability of the system according to the invention.

In a favorable embodiment of the system according to the invention, the optical sensor comprises an Avalanche Photo Diode. This measure makes it possible to reliably detect the optical signal even if it is very attenuated. This measure therefore has the advantage that it makes a positive contribution to the reliability of the system according to the invention. In a special embodiment thereof, the Avalanche Photo Diode is a Single-Photon Avalanche Diode. This measure makes it possible to detect the optical signal when a single photon of the optical signal reaches the optical sensor.

In a favorable embodiment of the system according to the invention, the reflector is in the form of a cap. This measure makes it possible to arrange the reflector in a simple manner at one end of the cable harness. This measure therefore has the advantage that the system is easy to use. In a favorable embodiment thereof, the reflector is at least partially formed from a flexible material. This measure makes it possible to manufacture a cap-shaped reflector which, due to its flexibility, can be simply and firmly clamped on one end of the cable harness and which also closes it off from moisture and dirt from outside.

In a favorable embodiment of the system according to the invention, the reflector is at least partially formed from vinyl. This measure makes it possible to produce a reflective surface in a simple and cost-effective manner that can reflect a sufficient part of an optical signal emerging from one of the optical fibers in the end of a second fiber to enable the reflection of the optical signal. detect the other end of the second optical fiber. In particular in combination with the measure that the reflector is designed as a cap, this measure also makes it possible to manufacture a reflector which due to its flexibility can be simply and firmly clamped on one end of the cable harness. This measure then has the advantage that it contributes to the simplicity and reliability of the system.

In a favorable embodiment of the system according to the invention, the reflector comprises as reflecting surface a surface on which a reflecting material is arranged. This measure makes it possible to realize a reflective surface of a surface that itself has no or insufficient reflective properties. This has the advantage that the freedom of choice of the material from which the basic shape of the reflector is made is greater. In a favorable embodiment thereof, the reflective material is Titanium dioxide. This measure makes it possible to realize a reflector that reflects a particularly large part of an optical signal emerging from one of the optical fibers in the end of a second fiber. This measure has the advantage that it makes a positive contribution to the reliability of the system.

In a favorable embodiment of the system 15 according to the invention, the reflector consists at least partly of semi-transparent material. This measure makes it possible to observe at the end of the cable harness to which the reflector is mounted that the relevant end of the cable harness is being tested. Thus, by means of the system, it can also be determined whether the tested branch cable corresponds to the branch cable that is suspected of being tested.

In a favorable embodiment of the system according to the invention, the reflector consists at least partly of a material shrinking under the influence of heat. This measure makes it possible to mount the reflector securely on an end of the cable harness in a simple manner. This measure has the advantage that it makes a positive contribution to the simplicity and reliability of the system.

In a favorable embodiment of the system according to the invention, the reflector comprises as a reflecting surface a surface that is rough. The measure makes it possible to realize a reflective surface that promotes the scattering of an optical signal falling on that reflective surface.

The invention also relates to a test device and a reflector as described above in the context of the system according to the invention.

The present invention will be further elucidated hereinbelow on the basis of exemplary embodiments which are shown in the accompanying drawing. These concern 10 non-limitative exemplary embodiments. In the views, the same or comparable parts, components and elements are indicated with the same reference numbers. In the drawing: - Fig. 1 schematically shows a Fiber To The Home project 15 (FTTH); Fig. 2 schematically shows the test device according to the invention in components; Fig. 3 schematically shows the operation of the test device of Fig. 2; Fig. 4 shows a detailed sectional view of an end of the cable harness of Fig. 1 with a reflector thereon.

Figure 1 schematically shows a Fiber To The Home project (FTTH), in which individual residential buildings WHx, WH2 and WH3 are provided with a connection to an optical communication network. It has been shown that a so-called patch box 2 with connection points AP is arranged in a central unit 1. Two connection points are reserved for each residential building WHi, WH2 and WH3. APia and APib 30 connection points for the WHi house, AP2a and AP2b connection points for the WH2 house, and AP3a and AP31 connection points, for the WH3 house. An optical fiber must go from each of the connection points AP to one of the dwellings WH1, WH2 and WH3, so that each of the dwellings is connected to the exchange by means of two optical fibers. To this end, a cable harness 3 is laid, 10 shown with a central cable CK laid between the center 1 and a branch point 4, and branch cables AK 1, AK 2 and AK 3, laid between the branch point 4 and the respective dwellings WH 1, WH 2 and WH3. Such a branch point 4 is also referred to as an 'optical distributor'.

The central cable CK contains 96 optical fibers, for example glass fibers. The branch cables AK each contain two optical fibers. Branch cable AKi the optical fibers AKia and AKib, the branch cable AK2 the optical fibers AK2a and AK2b and the branch cable AK3 the optical fibers AK3a and AK3b · It is shown that the connection point APia reserved for the home WHi via the optical fiber CKi of the central cable CK is connected to the optical fiber AKia of the branch cable AKi, and that the other connection point AP3b reserved for home WHi is connected via the optical fibers CK2 of the central cable CK to the second optical fiber AKib of the branch cable AKi. These are good connections. After all, after connecting the branch cable AKi to the house WHi, house WHi is connected to the designated APia and APib connection points.

Figure 1 also shows that the connection point AP2a reserved for house WH2 is connected via the optical fiber CK3 of the central cable CK to the optical fiber AK2a of the branch cable AK2, and that the other connection point AP2b reserved for house WH2 optical fibers CK4 of the central cable CK is connected to the optical fiber AK3a of the branch cable AK3. The connection between the optical fiber CK5 of the central cable CK and the optical fiber AK3a of the branch cable AK3 is an incorrect connection. After all, after connecting the branch cable AK2 30 to the house WH2, house WH2 is only connected to the reserved terminals AP2a and not to the AP2b terminal. This wrong connection arose because when welding the optical fibers of the 11 branch cables AK2, and AK3 to the optical fibers CK3-6 of the central cable CK, the optical fibers AK2b and AK3a were accidentally crossed and on the wrong optical fiber of the central cable CK are welded.

5 The wrong connection has the consequence that a service requested by the residents of house WH2 and delivered via AP2b connection point is not delivered at house WH2 but at house WH3.

Figure 1 also schematically shows that the cable harness 3 can be tested by means of a testing device 5 and reflectors 6, 7 and 8. It has been shown that the test device 5 is connected to the APia connection point reserved for the WHi home. From the center 1, at a proximal end of the cable harness 3, an optical signal can be introduced by means of an optical signal generator from the test device 5 into a first optical fiber which is formed by the optical fiber CKi and the cables connected thereto. optical fiber AKia. The optical signal is preferably generated from laser light with a wavelength in the region of substantially 400 nm to substantially 1600 nm, more preferably from laser light with a wavelength of substantially 650 nm. At the end of the branch cable AKi, located at the house WHi, a distal end of the cable harness 3, a reflector 6 is provided with which a part of the optical signal coming out of the first optical fiber can be introduced into a second optical fiber which is formed by the optical fiber AK1b and the associated optical fiber CK2. The reflection of the optical signal is then guided through the second optical fiber towards the center. In the center 5, at a proximal end of the cable harness 3, an optical sensor of the test device 5 is connected to the suspected end of the second optical fiber, namely the other terminal AP2b reserved for the home WHi 12. The reflection of the optical signal is detected by the test device 5 as soon as it exits the second optical fiber at the connection point APib and falls on the optical sensor of the test device 5. The test device 5 then gives a signal that the connection is good.

Subsequently, when the optical signal generator of the test device 5 is connected to the terminal AP1a reserved for dwelling house WH2, an optical signal can be introduced into a first optical fiber formed by the optical fiber CK2 and the optical fiber AK2a connected thereto. At the end of the branch cable AK2 located at the dwelling house WH2, a reflector 7 is provided with which a part of the optical signal 15 coming out of the first optical fiber can be introduced into a second optical fiber formed by the optical fiber AK2b and the optical fiber CK3 connected thereto. The reflection of the optical signal is then guided through the second optical fiber towards the center 5.

If then in the center 1 the optical sensor of the test device 5 is connected to the suspected end of the second optical fiber, the other connection point AP2b reserved for the house WH1, the reflection of the optical signal is not detected by the test device 5 . After all, the reflection of the optical signal will emerge from the second optical fiber at the connection point AP3a and will therefore not fall on the optical sensor of the test device 5. The test device 5 then gives a visual and / or acoustic signal that the connection 30 is wrong. The test device will give the same signal that the connection is wrong when the test device is connected to the connection points AP3a and AP3b reserved for the house WH3.

13

As shown in Figure 1, the branch cables Mi, AK2 and AK3 are still rolled up in front of the houses WH1, WH2 and WH3 and are not yet connected to them. As a result, the residents of the residential homes are not affected by the wrong connections and can be repaired before the branch cables are connected to the residential homes.

In figure 2 the test device 5 of figure 1 is schematically shown in components. The test device 5 is shown with an optical signal generator 9 which can be connected by means of a connector 10 to an end of a first optical fiber, and with an optical sensor 11 which can be connected by means of a connector 12 to a end of a second optical fiber. The optical signal generator 9 is preferably a laser generator. The optical sensor 11 is preferably an Avalanche Photo Diode and more preferably a Single-Photon Avalanche Diode. The optical signal generator 9 and the optical sensor 11 are connected to a control and processing module 13. This control and processing module 13 controls the optical signal generator 9 so that it generates the desired signal at the desired moment, and processes the output of the optical sensor 11. Furthermore, the test device 5 is shown with a screen 14, LEDs 15 and a sound generator 16 for displaying, for example, the operating state of the test device and, for example, the result of a test carried out by means of the test device, as well as with a number of switches 22 for operating the test device 5. The test device could incidentally also have only one of the screen, the LEDs and the sound generator, or any combination of these separate signaling components. It has also been shown that the various components of the test device 5 are powered by means of a power supply shown with a battery 17 and a power control unit 18.

Figure 3 shows the operation of the test device 5 of Figure 2 over time. It has been shown that the control 5 and processing module 13 is adapted during a test to read out the optical sensor 11 of Fig. 2 during a test and to control the optical signal generator 9 in such a way that it does not generate an optical signal in order to produce a so-called baseline 'v0. After determining the 'baseline' Vo, the control and processing unit 13 on ti will control the optical signal generator 9 such that it generates an optical signal. If the connection is good, the control and processing unit 13 at t2 will detect the reflection of the optical signal vi by means of the optical sensor 11. The control and processing unit 13 then controls the optical signal generator 9 such that an optical signal is no longer generated, so that the control and processing unit 13 at t3 will no longer detect reflection of the optical signal.

Figure 4 shows a distal end of the cable harness 3 in the form of branch cable Α in detail. The AKX branch cable contains two optical fibers AKia and AKib. A reflector 6 designed as a cap is arranged over the end of the branch cable AKi. Because the reflector 6 is formed from vinyl and can therefore stretch considerably, the reflector 6 is firmly clamped on the end of branch cable AKi and even protects the ends of the optical fibers AKia and AKib against dirt and moisture. Alternatively, the reflector 6 consists partly of another flexible (plastic) material or of heat-shrinking material so that the reflector can be shrunk around the end of the branch cable AKi. Another alternative is that a layer of glue is applied between the outer sheath of the branch cable ΑΚχ and the reflector 6.

The reflector 6 is shown with a surface 19 on which a layer of reflective material 20 is applied as a reflective surface. An optical signal emerging from the optical fibers AKia is at least partially reflected in the optical fiber AKib by means of the layer of reflective material 20. A highly suitable reflective material for this purpose is 10 titanium dioxide. However, another reflective material is also applicable, such as mirror chrome, silver, gold, etc. It is also possible that the material from which the reflector is formed has sufficient reflective properties itself, so that the layer of reflective material is not necessary to reflect the surface 19 to make. It has also been shown that the reflector consists of a semi-transparent material, so that a non-reflected portion of the optical signal 21 radiates out through the reflector 6. From the outside it can be seen that the branch cable ΑΚχ is being tested. The reflective surface can be roughened to increase its scattering properties.

The figures show that each house is connected to the central unit by means of two optical fibers. It is also possible for each house with more than two optical fibers to be connected to the central unit.

A Fiber to the Home project is shown in the figures, but the invention can also be used in a Fiber to the Office project or another optical network project in which a cable harness with at least two optical fibers is used.

The figures show that the cable harness consists of a central cable with 96 optical fibers and a number of branch cables with two optical fibers each. The cable harness could also consist of a first central cable with, for example, 192 fibers, a second central cable with 96 fibers connected thereto as the first tap to which a number of tap cables are then connected as a second tap. The cable harness can thus comprise several consecutive branches.

10 1036720

Claims (19)

Method for testing a cable harness with at least two optical fibers, comprising the following steps: - introducing an optical signal into a first optical fiber at a proximal end of the cable harness; 10. reflecting at a distal end of the cable harness at least a portion of the optical signal emerging from the first optical fiber into a second optical fiber; - detecting the reflection of the optical signal at the proximal end of the cable harness at a suspected end of the second optical fiber. 2. Method as claimed in claim 1, wherein the step of reflecting comprises scattering of the optical signal. Method according to claim 1 or 2, wherein the optical signal is generated by means of laser light. 25 The method of claim 3, wherein the laser light has a wavelength in the range of substantially 400 nm to substantially 1600 nm. The method of claim 3, wherein the laser light has a wavelength in the range of from substantially 632 nm to substantially 675 nm. 1036720 A system for testing a cable harness with at least two optical fibers, comprising - a testing device comprising: - an optical signal generator that can be connected to a first optical fiber at a proximal end of the cable harness; and 10. an optical sensor connectable to a suspected end of a second optical fiber at the proximal end of the cable harness; and 15. a reflector that can be arranged at a distal end of the cable harness. The system of claim 6, wherein the optical signal generator comprises a laser generator. 20 The system of claim 6 or 7, wherein the optical sensor comprises an Avalanche Photo Diode. The system of claim 8, wherein the 25 Avalanche Photo Diode is a Single-Photon Avalanche Diode. The system of any one of claims 5 to 9, wherein the reflector is in the form of a cap. The system of claim 10, wherein the reflector is at least partially formed from a flexible material. The system of any one of claims 5 to 11, wherein the reflector is at least partially formed from vinyl. A system according to any of claims 5 to 12, wherein the reflector comprises as a reflecting surface a surface on which a reflecting material is applied. The system of claim 13, wherein the reflective material is Titanium Dioxide. 15. System as claimed in any of the claims 5 to 14, wherein the reflector consists at least partly of a semi-transparent material. 16. System as claimed in any of the claims 5 to 15, wherein the reflector consists at least partially of a heat-shrinking material. The system according to any of claims 5 to 16, wherein the reflector comprises a surface that is rough as a reflecting surface. 25 18. Test device for testing a cable harness with at least two optical fibers, comprising - an optical signal generator that can be connected to a first optical fiber at a proximal end of the cable harness; and - an optical sensor that can be connected to a suspected end of a second optical fiber at the proximal end of the cable harness. 19. Reflector for testing a cable harness with at least two optical fibers, which can be arranged at one end of the cable harness. 10 1036720