FR2751746A1 - Multi-core optical fibre connection testing device - Google Patents

Abstract

The device includes a reflectometer (2) with a terminal (3). An optical coupler (4) with a main terminal (6) and four auxiliary terminals receive primary signals injected in to the main terminal. The input signals are split into four signals delivered by the auxiliary terminals. Three optical fibres (10) of different lengths are connected to the auxiliary terminals of the coupler. A light source (12) is connected to the other extremities of the optical fibres. A multi-core optical fibre to be tested is also connected to the light source output.

Description

 The invention relates to methods and devices for checking by reflectometry for connection of optical fibers.

 We know that when an optical fiber has been connected by one end to a transmission network, it is necessary to check the quality of the link. For this verification, it is known to connect the free end of the fiber to a reflectometer. This sends an optical signal into the fiber which is partially and regularly reflected along the fiber and is transmitted back to the reflectometer. The lectometer ref indicates the variations in the intensity of the reflected signal as a function of time, that is to say as a function of the distance traveled by the signal in the two directions of propagation. A reflection also occurs at the connection level. A too sudden drop in the intensity reflected at the distance corresponding to the connection reveals its poor quality.

 In addition, the growing volume of information to be transported in the fibers and the obligation of continuity of flows requires an increase in the number of optical cores per link and possibly the use of multicore fibers. Connecting a multicore fiber involves checking the quality of the connection of each core. However, the known verification devices as mentioned above make it possible to verify the connections on a single core at a time. It follows that to check the connection of a multicore fiber, the operator is forced to check all the cores one by one. This results in long and laborious manipulations. In addition, these repeated manipulations cause premature aging and pollution of the reflectometer connectors.

 An object of the invention is to provide a method and a device allowing a simple and quick way to verify by reflectometry the quality of a connection of multicore fibers, and to preserve the service life and the cleanliness of the connectors of the ref lectometer.

 With a view to achieving this aim, provision is made, according to the invention, for a method of verification by reflectometry for at least one connection of multicore optical fibers, comprising the successive steps consisting in - transmitting a primary signal; - divide the primary signal into at least two secondary signals; - time offset the secondary signals with respect to each other; - send the secondary signals in the respective cores of a multicore optical fiber associated with the connection to be checked, - receive signals reflected in the cores; - summing the reflected signals into a total signal; and - exploit the variations in the intensity of the total signal as a function of time.

 Thus, due to the time offsets of the secondary signals between them, the portion of each reflected signal relating to the connection is distinguished in the summed signal. It is therefore possible to verify the quality of the connection for each core of the fiber, and the verification by reflectometry is simultaneous for the different cores of the fiber. The control is therefore faster and easier to perform. We also preserve the life and cleanliness of the connectors.

 There is also provided according to the invention a device for checking by reflectometry for at least one connection of multicore optical fibers, comprising a reflectometer and an optical coupler having a main terminal connected to the reflectometer and at least two auxiliary terminals, the auxiliary terminals being intended for be connected by means of links of different lengths to each other to the respective cores of a multicore fiber associated with the connection to be checked.

 This device implements the method according to the invention.

 Other characteristics and advantages of the invention will become apparent on reading the following description of two preferred embodiments given by way of non-limiting examples. In the accompanying drawings: - Figure 1 is a schematic view of a first embodiment of the device according to the invention; - Figure 2 is a schematic view of a second embodiment of the device according to the invention; and - Figures 3 to 6 are graphical representations of the variation in the intensity of the signal received on the reflectometer as a function of time, respectively in the case of a fiber with a single unconnected core, of a fiber with a single connected core, an unconnected multi-core fiber, and a connected multi-core fiber.

 FIG. 1 shows a first embodiment of the device according to the invention suitable for verification by reflectometry of one or more series connections of multi-core optical fibers with four cores. This device comprises a reflectometer 2 of a type known per se, having an output / input terminal 3. The device also comprises an optical coupler 4 having a main input / output terminal 6 and four auxiliary output / input terminals 8. This coupler , of the "1 to 4" type, is an optical component of a type known per se. A primary signal injected at the main terminal 6 is divided into four secondary signals emitted by the respective auxiliary terminals 8. Conversely, four signals injected at the auxiliary terminals 8 are summed and the total signal is transmitted to the main terminal 6. The main terminal 6 is connected to the terminal of the reflectometer by means of a single-core optical fiber. For this, a first end of the fiber is connected to the terminal of the ref lectometer, and a second end of the fiber is welded to the main terminal 6 of the coupler.

 The device comprises three intermediate optical fibers 10 with a single core and of different lengths between them. These fibers 10 are connected by welding through a first end to three of the respective auxiliary terminals 8 of the coupler. Each intermediate fiber 10 is configured to occupy a reduced volume. The fibers 10 are here wound. The differences in length of the intermediate fibers 10 are sufficient for the relative time shifts introduced by these fibers as will be seen to exceed the sensitivity threshold of the reflectometer.

 The device comprises a spark gap 12 with four hearts having four auxiliary input / output terminals 14 formed by the disjointed hearts, and a main output / input terminal 16 constituted by the assembled hearts while remaining physically distinct. Three of the auxiliary terminals 14 are connected by welding to a second end of the respective intermediate fibers 10. The spark gap, of the "four-core" type, for example conforms to that described in document FR-A2 717 913. The fourth auxiliary terminal 8 of the coupler is connected by welding directly to the fourth auxiliary terminal 14 of the spark gap . This connection will be called "direct link" in the following. The link produced by the shortest intermediate fiber 10 has a length greater than the direct link.

 A first optical fiber 18 with four cores and for example with a square matrix is detachably connected by a first end to the main terminal 16 of the spark gap. Each core of the fiber is thus connected to a respective core of the terminal 16. A second end of this fiber 18 is connected hearts to hearts to a second optical fiber 20 to four hearts, by means of a connector 22. A function of the device according to the invention is to check the quality, for each of the four cores, of the connection made at the level of the connector 22. Each intermediate fiber 10 has a length less than the length of the second multi-core optical fiber 20 associated with the connection.

 The device makes it possible to implement the method according to the invention which comprises the following successive steps. By means of terminal 3 of the lectometer ref 2, a primary optical signal is emitted in the direction of the main terminal 6 of the coupler 4, this signal having the form of a pulse. The coupler divides the primary signal into four secondary signals which are sent respectively via the auxiliary terminals 8 in the three intermediate fibers 10 and in the direct link. The three secondary signals passing through the three intermediate fibers undergo a delay proportional to the length of the intermediate fiber crossed. These three signals are thus offset in time with each other and with respect to the fourth secondary signal crossing the direct link. These signals arrive at the auxiliary terminals 14 of the spark gap 12, then are sent to the main terminal 16. They are then injected into the respective cores of the first fiber 18, pass through the connection 22 and end up in the second fiber 20.

Each secondary signal is partially reflected along this path in the fibers 18 and 20. It therefore generates a reflected signal which is diffused in the direction opposite to the direction of propagation of the secondary signal. Each reflected signal follows the same path as the associated secondary signal in the opposite direction to the coupler 4. It therefore itself undergoes a delay identical to that undergone by the secondary signal. The reflected signals emerging from the intermediate fibers 10 and from the direct link are received and summed by the coupler 4 into a total reflected signal. This signal is transmitted to terminal 3 of the reflectometer. The reflectometer records the intensity
I of the signal as a function of the travel time, that is to say of the distance traveled on the outward and return journey, and provides the curve of the intensity I as a function of the time t.

The shape of this curve is shown in Figure 6. We then use the variations in the intensity I of the total signal as a function of time. The understanding of the curve of FIG. 6 will here be facilitated by the prior study of the curves of FIGS. 3 to 5.

 FIG. 3 represents the shape of the reflectometry curve for a single-core optical fiber having a first end directly connected to the reflectometer and a second unconnected end. The intensity I of the reflected signal decreases slowly as a function of time t, namely the distance to the lectometer ref, due to the losses. Then the intensity I abruptly cancels out at "b" for the travel time corresponding to the free end of the fiber. Indeed, at this end, the signal escapes from the fiber.

 FIG. 4 represents the shape of the curve associated with an identical fiber whose second end is this time suitably connected by a connection to another fiber of the same type. At the time corresponding to the passage of the connection between the two fibers, at point "a", there is a slight decrease in the reflected intensity. (This drop in intensity can be preceded by a peak corresponding to a significant reflected intensity at the connection.) The rest of the curve, slightly decreasing like the first part, corresponds to the length of the second fiber connected to the first. A fall in intensity I occurs at the free end of the second fiber, at point "b". If the connection is very defective, the curve is identical to that of FIG. 3, in other words the intensity I drops suddenly at point "a" and the second fiber does not appear on the curve.

FIG. 5 represents the shape of the lectometry ref curve obtained in the case of the device of FIG. 1 when the first fiber 18 is not connected to the second fiber 20, its second end being left free. The curve of the intensity I of the total signal results from the sum of the four reflected signals which individually have the appearance of the curve of FIG. 3. The differences in length of the four links between the coupler and the spark gap, doubled by the outward and return paths associated with each core, cause the reflected signals to be time-shifted, namely along the abscissa axis. This makes it possible to distinguish the intensity of these four signals from each other in their most relevant part, namely at points 1b, 2b, 3b and 4b corresponding to the free ends of the respective hearts of the first fiber 18, where the intensity
I fall suddenly. The point lb represents the free end of the core associated with the direct bond.

 FIG. 6 represents the shape of the reflectometry curve obtained in the case of the device of FIG. 1 when the first fiber 18 is connected to the second fiber 20 by means of the connector 22. This time, the curve results from the addition of the four reflected signals which individually have the appearance of the curve of FIG. 4. The abovementioned time offset makes it possible to distinguish on the curve of the intensity I of the total signal the intensity of each signal reflected in the part corresponding to the connection 22. Thus, the points la, 2a, 3a and 4a correspond to the connection of the respective hearts of the two fibers and have a slight drop in intensity. The points 1b, 2b, 3b and 4b correspond to the free ends of the second fiber 20 associated with the same hearts and exhibit a drop in intensity. This part of the curve is identical to the curve in Figure 5.

 The variations in the intensity of the total signal as a function of time are exploited by analyzing the variation in intensity for each core at the level of the connection. If the connection is bad for one of the hearts, for example for the second heart at point 2a, there occurs at this point a greater drop in reflected intensity because the sequence of the reflected signal associated with this heart is then lower intensity. We therefore distinguish on the curve at this point a more important step than for the other hearts.

 On the curve, the points la, 2a, 3a and 4a are grouped and followed by the points 1b, 2b, 3b and 4b also grouped. This arrangement results from the fact that each intermediate fiber 10 has a length less than the length of the second multi-core optical fiber 20 associated with the connection.

 The same curve thus makes it possible to check the quality of the connection for each of the four cores, and this simultaneously. The connection by welding together of the coupler 4, of the three intermediate fibers 10, of the direct connection, of the spark gap 12 and of the first fiber 18 avoids making appear on the curve additional drops in intensity generated by connections by connector. The reading of the curve is thus facilitated.

 The device allows the quality of the connection of the multicore fiber for each of the four cores to be checked in a single manipulation. This verification is therefore simple and quick. The manipulations on the reflectometer connectors are reduced. The life and cleanliness of these connectors are preserved.

 The method and the device according to the invention have just been described for the application to the verification of a single connection 22. However, this method and this device can be used in the same way to simultaneously verify several connections connecting optical fibers. multi-cores arranged in series one after the other. Each connection corresponds to an additional group of points on the curve where the intensity decreases, four additional points in this case, associated with the respective hearts. Thus, the verification of all these connections is carried out without modifying the assembly for each connection, and is simultaneous.

 Figure 2 shows a second embodiment of the device. Fiber 18 this time has a flat ribbon with four hearts. The device here does not have a spark gap. The three intermediate fibers 10 and the fourth auxiliary terminal of the coupler are combined in a ribbon. They are connected to the four cores of the fiber 18 by simultaneous welding or mass splicing in a manner known per se. The operation of the device and the curve obtained are identical to those of the first embodiment.

 Of course, many modifications can be made to the invention without departing from the scope thereof.

 Thus, the device is not limited to the case of fibers with four hearts and can be applied generally for fibers with at least two hearts. In addition, the direct link may be replaced by a link by intermediate optical fiber of different length from the other intermediate optical fiber or fibers.

 Thus, for verification on a fiber with two cores, the device will include an optical coupler with at least two auxiliary terminals. It may further comprise either an intermediate optical fiber and a direct link, or else two intermediate optical fibers of different lengths between them.

 Similarly, for verification on a fiber with n cores with n greater than 2, the device will include an optical coupler with at least n auxiliary terminals. It may further comprise either (n-1) intermediate optical fibers of different lengths between them and a direct link, or else n intermediate optical fibers of different lengths between them.

Claims (10)

Claims  1. Verification method by reflectometry for at least one connection of multicore optical fibers, characterized in that it comprises the successive steps consisting in: - transmitting a primary signal; - divide the primary signal into at least two secondary signals; - time offset the secondary signals with respect to each other; - send the secondary signals in the respective cores of a multicore optical fiber (18) associated with the connection (22) to be checked, - receive signals reflected in the cores; - summing the reflected signals into a total signal; and - exploit the variations in the intensity (I) of the total signal as a function of time.  2. Verification device by reflectometry for at least one connection of multicore optical fibers, comprising a reflectometer (2), characterized in that it further comprises an optical coupler (4) having a main terminal (6) connected to the reflectometer and at least two auxiliary terminals (8), the auxiliary terminals being intended to be connected, by means of links of different lengths to each other, to the respective cores of a multi-core fiber (18) associated with the connection (22) to be checked.  3. Device according to claim 2, characterized in that it further comprises at least one intermediate optical fiber (10) having a first end connected to an auxiliary terminal of the coupler (4) and a second end intended to be connected to a heart of multi-core fiber (18).  4. Device according to claim 3, characterized in that it comprises at least two intermediate optical fibers (10) having one end connected to a respective auxiliary terminal of the coupler (4), the intermediate fibers (10) being of different lengths between they.  5. Device according to claim 3 or 4, characterized in that the number of intermediate optical fibers (10) is less by one unit than the number of auxiliary terminals of the coupler (4).  6. Device according to one of claims 3 to 5, characterized in that it further comprises a spark gap (12) comprising at least two hearts, each intermediate fiber (10) being connected by its second end to a core of the spark gap.  7. Device according to claim 6, characterized in that one of the hearts of the spark gap (12) is directly connected to an auxiliary terminal (8) of the coupler (4).  8. Device according to one of claims 3 to 7, characterized in that each intermediate fiber (10) is configured to occupy a reduced volume.  9. Device according to one of claims 3 to 8, characterized in that each intermediate fiber end (10) is connected by welding.  10. Device according to one of the preceding claims, characterized in that the variations in intensity (I) are used by analyzing the variation in intensity for each core at the connection (22).