FR2574565A1 - Device for injecting light into a jacketed optical fibre, especially for the local inspection of a connection of two fibres - Google Patents

Abstract

The light to be injected is supplied by an auxiliary fibre FA which is similar to the receiving fibre FR and which, in contact with the latter and in the same plane of curvature, is subjected to alternating bends. The latter enable the light to leave this auxiliary fibre and to enter the core of the receiving fibre in order to be guided therein. Application to telecommunications.

Description

Device for injecting light into a sheathed optical fiber, in particular for the local control of a connection of two fibers
The invention relates to the injection of light into an optical fiber and it is particularly applicable to the quality control of the connection of two fibers of great length when this control must be local, that is to say must be done without access to a free end of these fibers. and without cutting or damaging the fibers. More specifically, a device according to the invention is intended for injecting and directing light into the core (CO) of a "receiving" optical fiber (FR) which must not be cut, this core being continuously surrounded by an optical cladding (GO) with a lower optical index to allow light to be guided and this optical cladding itself being surrounded by a primary cladding (GP) to form a sheathed fiber including the optical cladding is protected by the primary sheath, the material of this primary sheath being transparent and having an optical index not substantially lower than that of this optical sheath.

The reference signs in parentheses above and below refer by way of example to the attached figures which will be described later.

 The problem of injecting light into an optical fiber which should not be cut is part of the more general problem of coupling such a fiber which also includes the problem of deriving light from the fiber.

 It is obvious that any bypass device in principle also allows injection because if, by means of suitable arrangements, a bypass device brings light out of the fiber along certain straight lines, it is sufficient to inject light, send it to the fiber along these same straight lines but in the opposite direction. The problem of injection is nevertheless more difficult in practice than that of bypass because when one derives from the. - light is generally to collect it on a photosensitive detector which accepts light in a very large solid angle, for example five steradians. The yield of the bypass, that is to say the ratio of the light received by the detector to that which was guided by the fiber is then large, since a large proportion of the derived light is actually accepted by the detector. It is not the same for the injection efficiency of an injection device, that is to say the ratio of the light injected and guided in the core of the fiber to the light emitted by the source used. . This yield is generally small because only a small fraction of the light directed towards the fiber propagates along the straight lines which ensure effective injection thanks to said suitable arrangements. This is due, on the one hand, to the fact that these straight lines are generally not not exactly known in advance, and secondly to the fact that there are no light sources allowing in practice to direct the majority of their light along these straight lines.

 The result is not only that the injection yield is small, but also that it is very sensitive to small modifications of the injection device or of the fiber, and therefore difficult to predict.

 Various coupling and therefore injection devices are known which use a curvature of the receiving fiber. For injection, the light to be injected is directed towards the sheathed receiving fiber on the curved area a little upstream of it, in the plane of the curvature, at an angle adjusted experimentally to obtain the best performance. However, this better yield remains unpredictable and low, for example 10-4% in the case of a multimode fiber of which the primary sheath is kept. It is much lower in the case of a single-mode fiber.

 It can be increased if the primary sheath is removed in the injection area, but this has the disadvantage of weakening the receiving fiber sometimes permanently, which is serious if it is a line fiber intended to transmit information over long distances for many years. A situation will be indicated below in which it is necessary to inject light into such a fiber at a distance from its ends.

 The injection yield can of course be further increased if one alters not only the primary sheath (generally made of a resin with low hardness) but also the optical sheath (generally made of much harder silica), and if the light is brought directly to the heart of the receiving fiber by an auxiliary fiber welded to it. But this is then a definite alteration of the receiving fiber, and such an alteration is generally inadmissible, in particular when the injection must be made temporarily for checks on a line fiber.

 A known device for injecting the receiving fiber without alteration comprises the following elements, which are common to this known device and to that according to the present invention at least as regards certain of their functions - two pieces of fiber deformation (2, 4 , 52, 54) respectively comprising two strips of fiber deformation, each of these strips having a length in a longitudinal direction and a width in a transverse direction and comprising a regular longitudinal succession of thrust projections (6) which project in a direction of thrust perpendicular to said longitudinal and transverse direction and separated by recesses, - means for guiding (8) deformation pieces to keep these two deformation bands facing each other, the lengths and widths of these two bands being coextensive, the thrust projections of one band being opposite the hollows of the other band, - clamping means (12, 16) of these deformation pieces to allow in preparatory steps to remove these pieces, to place a straight injection section of said receiving fiber between the two said deformation bands with its length arranged in said longitudinal direction, and to clamp these two pieces l one against the other so that, during a later stage of light injection, said projections elastically flex this injection section by forming a regular succession of alternating curvatures in a plane of curvature containing said longitudinal and thrust directions, - a light source (LA) for providing said light to be injected during said injection step, - and means for directing this light to be injected towards said injection section in directions which allow the injection of this light into the fiber core with the help of said alternating curvatures.

 This known device is for example described in French patent no. 2 399 042 and the corresponding American patent no. 4 253 727 (Jeunhomme et al) which relates more generally to a coupling device.

 Although the presence of numerous curvatures in this injection device makes it possible to improve the injection yield, the latter however remains too weak and unpredictable.

 The present invention also relates to the measurement of losses in an area to be monitored of an optical fiber. The known light injection devices and the injection device according to the present invention are in fact applicable to such a measurement for the local control of a particular area such as that connection between two optical fibers, for example to the control of the quality of a weld produced between the ends of two line fibers which must ensure the transmission of information over distances greater than the maximum length of commercially available optical fibers. It should indeed be ensured that this welding is done properly to prevent the crossing of the connection from creating losses of light harmful to the transmission. In particular, the hearts of the two line fibers must be correctly aligned.

 One known way of carrying out such a check without damaging the fibers consists in injecting light into one of the line fibers in the direction of the connection, so that this light passes through this connection, then in deriving this light from the other fiber. If we know the intensity of the injected light and the bypass efficiency, and if the losses in the fibers are small compared to the losses in the connection, it is enough to measure the intensity of the derived light to know the losses in the connection. The distance between the injection device and the connection must, however, be sufficient for the stray light - which is inevitably injected into the sheath or sheaths of the fiber - to be completely lost before reaching the connection. This condition is easy to fulfill because the losses in the sheaths are much higher than the losses in the core of the fibers used today. Unfortunately, as previously indicated, the efficiency of the injection device can vary over time and is difficult to know, which means that the intensity of the light actually injected into the core of the fiber is only known with a great imprecision.

 This is why a known method of local control comprises the following operations which are common to this known method and to a method according to the invention, at least as regards certain of their functions - injection of a control light into the heart d 'a. section of injection of a receiving fiber (FR) on one side of said zone to be controlled (ZC), the fiber on the other side of this zone being a fiber (FL) connected to the receiving fiber, this light coming a control source (LA), being injected using an injection device (DI) and being directed towards this fiber connected so that it is guided there after passing through the area to be controlled, - derivation of this control light using a control bypass device (DC) from this connected fiber, - measurement of the intensity of the control light thus derived, - injection of a reference light in the heart of the same injection section from a reference source (LA) subjected to the same variations as the injection source, this light being injected using the same injection device (DI) and directed in the opposite direction to that of the control light, - derivation of this reference light (FR) from this fiber e receiver at a distance from its said injection section, using a reference bypass device (DR) having a known bypass yield relative to the yield of the control bypass device (DC), - measurement of the intensity of the reference light thus derived, - and calculation of the ratio of this intensity to that of the derived control light so as to obtain a measurement of the fraction of guided light lost in said zone to be controlled (ZC) independently of the injection efficiency of said injection device.

This known process is described in an article pages 642-646 of the Journal of Lightwave Technology, vol. LT-2, NO 5, October 1984 "A
New Method of Optical Fiber Loss Measurement by the Side-Illumination Technique, Shun Sumida, Hisashi Murata, and Yutaka Katsuyama.

 Its precision remains insufficient because the injection efficiency is low, and especially because the efficiency of the injection of the control light is not exactly equal to that of the injection of the reference light or, more generally, that the relationship between these two yields is not known.

 An object of the present invention is to allow a simple way to locally inject light into a sheathed optical fiber of great length with increased injection efficiency and without interruption or alteration of the fiber.

 Another object of the present invention is to allow a simple way to inject light in two opposite directions in the same section of an optical fiber with two equal injection yields.

 Another object of the present invention is to allow in a simple manner to locally measure with increased precision light losses in an area of a long optical fiber without interruption or alteration of the fiber.

 This is why the subject of the present invention is in particular a device for injecting light into a sheathed optical fiber, in particular for the local control of a connection of two fibers, this device comprising the common elements mentioned above and being characterized by has an auxiliary optical fiber (FA) with an injection section which has a transparent outer sheath (GPA) and has an outer diameter substantially equal to that of said sheathed receiving fiber (FR), this auxiliary fiber receiving said light to be injected at a distance from its injection section and guiding it as far as this section, - and means (20) for lateral support of the fiber arranged on both sides of the gap between the two said deformation bands and delimiting according to said transverse direction, a deformation channel whose width in this direction is substantially equal to the diameter of the two said injection sections, so as to allow re during said preparatory steps of superimposing these two sections in this channel in said direction of thrust, each of these sections being arranged in said longitudinal direction and held by these lateral holding means, and so that, during said injection step , these two sections are bent by substantially the same alternating curvatures in the same plane of curvature so that the light to be injected escapes from this auxiliary fiber (FA) precisely in said directions which allow its injection into the receiving fiber (FR) without interruption of the primary sheath (GP) of the latter.

 This device can advantageously also have the following provisions - Said clamping means (12, 16) are capable of exerting during said injection step a clamping force sufficient to deform the section of the outer sheath (GPA, GP) of said auxiliary fiber (FA) and / or primary sheath of said receiving fiber (FR) so as to create optical contact areas having an extent in said longitudinal and transverse directions and allowing the direct passage of light from one to the other of these sheaths. The passage of light can of course also be facilitated by wetting the two fibers with a transparent liquid with an index close to that of these sheaths.

- In the case where the primary sheath (GP) of the receiving fiber (FR) is substantially less hard than its optical sheath (GO), said auxiliary fiber (FA) is chosen to be substantially identical to said sheathed receiving fiber (GR) to easily obtain an auxiliary fiber such that the light which escapes therefrom in said injection section has said directions allowing its injection into the receiving fiber. It is sufficient then while the thrust projections in one direction on one of the fibers are symmetrical of the thrust projections in the other direction on the other fiber with a longitudinal offset preferably equal to half a step of the regular succession of the projections, so that the optical behavior of the two fibers is the same, which ensures that the light which escapes from one is that which can penetrate into the other to be guided there.

- At least one of said deformation pieces (2, 4, 54) comprises elements (20) for lateral retention of fibers projecting in said direction of thrust on both sides of said deformation band of this piece, so that all of these holding elements of this or these parts constitute said holding means for bilaterally maintaining the two said injection sections not only during said injection step, but also during said preparatory steps when these parts are separated. one of the other. Such lateral holding elements can be carried by each of the two deformation parts, which can then be identical to each other and which each hold one of the two fibers. They can also be carried by only one of these parts which must then hold the two fibers. In this case, the auxiliary fiber is permanently disposed at the bottom of the groove formed between these holding elements, and the receiving fiber is engaged in this groove. on the auxiliary fiber before the injection step. In both cases, after the injection step, the receiving fiber is taken out of its groove to allow the device to be used for another receiving fiber.

- The holding elements form, at least on one side of said deformation band of at least one deformation piece, a longitudinal succession of projections (20) for holding fibers, each of these holding projections being located substantially in the same transverse plane as a said thrust projection (6), such a plane containing said transverse and thrust directions, the height of this holding projection in the thrust direction above this thrust projection being between 0 , 5 and 1 times the diameter of said fibers in each of the two deformation pieces (2, 4) or between 1.5 and 2 times this diameter in a single 54) of these pieces so that the fiber holding elements a deformation piece ensures the bilateral maintenance of one or both of said injection sections, respectively, recesses being formed between the consecutive holding projections to allow projections possibly holding the fiber of the other piece deformation (4, 2, 52) to engage in these recesses during the tightening of these deformation parts and thus allow to bring these two parts sufficiently close to each other. The projections of said other deformation piece constitute fiber retaining projections in the case of two identical deformation pieces. In the case where only one of these two pieces holds the two fibers, the projections of the other may extend transversely over the width of the deformation band, where they constitute said thrust projections, and one or more two sides of this strip.

- The shapes of said recesses between projections (20) for holding consecutive fibers of a deformation piece (?, 4) are complementary to the shapes of said projections of the other deformation piece (4, 2) so that these recesses and protrusions constitute a part of said means for guiding the deformation parts. Such hollows and protrusions then prevent relative longitudinal displacement of the two deformation pieces.

- The fiber deformation band between said retaining elements is constituted by an upper edge of a blade (18), the length of which is arranged in said longitudinal direction and the width in said direction of thrust, this edge being hollowed out with notches to form said thrust projections (6), this blade being disposed in a groove formed in a body (2, 4) of deformation part and deeper than the width of this blade, the upper part of the lateral surfaces of this groove constituting said fiber holding elements (20). This blade is for example made of brass.

This arrangement can facilitate the manufacture of the deformation part because the blade can be cut before being pressed into the groove, while it would be difficult to form the thrust projections at the bottom of a groove which is narrow since its width is substantially equal to the diameter of a sheathed fiber
The present invention also relates to a method of injecting light into a sheathed optical fiber which constitutes a light receiving fiber, this method comprising the following operations - application to an injection section of the receiving fiber (FR) of forces thrust parallel to each other and perpendicular to a longitudinal direction which is the general direction of this section, so as to impose on this section a succession of alternating curvatures in a plane of curvature which is the plane of these forces, - and sending of the light to be injected on this section in directions allowing the injection of this light into the core of this fiber with the help of these alternating curvatures, - this process being characterized by the fact that there is an injection section of an auxiliary optical fiber (FA) along the injection fiber injection section (FR), - said thrust forces are applied to all of these two sections, the plane of these forces being this him of the two sections, so that these have the same alternating curvatures in the same plane of curvature, - and said light to be injected is injected into the core of this auxiliary fiber outside of its injection section so that this light is guided by this fiber to this section, and that these alternating curvatures make it escape from this section in said directions allowing its injection into the receiving fiber.

 The present invention also relates to a process for measuring losses in an area to be checked of an optical fiber, in particular for the local monitoring of a connection of two long line optical fibers, this process comprising the common operations previously mentioned. , and being characterized by the fact that said injection device is a device previously mentioned according to the present invention, said auxiliary fiber (FA) comprising a control strand (BC) and a reference strand. (BR) on both sides 'other of its injection section, said control light being injected into this control strand and said reference light in this reference strand.

 Preferably, said control and reference sources are constituted by the same laser source (LA), the free ends of the two said control (BC) and reference (BR) strands of the auxiliary fiber (FA) being arranged facing each other. of this source so as to guide the light into their core, the number and amplitude of said alternating curvatures being chosen large enough so that the light injected by this source into one of these strands does not return to disturb this source from the 'other strand.

 Using the attached diagrammatic figures, a description will be given below by way of nonlimiting example, how the invention can be implemented. It should be understood that the elements described and shown can, without departing from the scope of the invention, be replaced by other elements ensuring the same technical functions. When the same element is represented in several figures, it is designated therein by the same reference sign.

 FIG. 1 represents a general view of a device for measuring the light losses in an area to be checked of an optical fiber, for the local control of the connection between two line optical fibers, this device comprising a first injection device of light and implementing the measurement method according to the present invention.

 2 shows a view of this injection device in section through a longitudinal plane containing the direction of thrust which is vertical, the two deformation parts of this device being identical.

 FIG. 3 represents a view of this injection device in section through a vertical transverse plane III-III of FIG. 2.

 FIG. 4 shows on an enlarged scale a detail IV of FIG. 2.

 FIG. 5 represents a sectional view along a transverse vertical plane V-V of FIG. 4.

 FIG. 6 represents a partial perspective view of a deformation part of the same injection device.

 FIG. 7 shows a view of a second connection device according to the invention in section through a transverse vertical plane, only one of the deformation parts of this device carrying the auxiliary fiber and the receiving fiber.

 The measuring device of FIG. 1 makes it possible to measure the light losses in a weld which connects two single-mode line fibers of great lengths FR and FL, this in order to control the quality of this weld. Such welding is in fact considered to be good when the light guided in the core of the upstream fiber, for example FR, is found almost entirely in the core of the downstream fiber, for example FL. Allowable losses are reflected, for example, in a power loss of 0.2 decibel. This weld constitutes said zone to be controlled ZC.

 A laser source LA injects substantially the same light power into the free ends of the two extreme strands BC and BR of an auxiliary optical fiber FA. These two strands guide this light into the interior of a DI injection device. The part of this fiber FA which is inside this device constitutes said injection section of this fiber. The FA fiber is of the same type as the FR and FL fibers. It could also be multimode.

The injected light has for example a wavelength of 850 nanometers. The power injected into each strand BC, BR is for example 1 mW.

 The DI injection device is designed so that the light escapes from the core of the auxiliary fiber and passes into the primary sheath GPA thereof, then into the primary sheath GP of the receiving fiber FR, then into the CO core thereof through its optical sheath. It is thus injected into the receiving fiber FR as well towards the fiber connected FL through the weld ZC as in the opposite direction. It thus constitutes a control light and a reference light, which are extracted in DC and DR bypass devices, respectively, located at the same distance from the injection device DI. The distances between this latter device and the ZC solder and between this solder and the DC bypass device are sufficient so that only the light guided in the core of the fiber reaches the solder or the bypass devices, this due to the weakening much stronger linearity of guided light in the ducts. These distances are for example about one meter if the fibers are single-mode. In these fibers, for example, the CO core and the GO optical sheath consist of silica.

The heart has a diameter of 8 micrometers. The outside diameter of the glass fiber is 125 micrometers. The difference in refractive index between the core and the optical cladding is 5.10-3-
The GP or GPA primary sheath is made of epoxy resin.

It has a thickness of 50 micrometers and an optical index of 1.57.

 These hearts and these sheaths are represented in FIGS. 4 and 5.

 These DC and DR bypass devices are identical. They each comprise, for example, two transparent deformation pieces PA and PB which impose on the fiber a succession of alternating curvatures, by elastic deformation. The light which then escapes into the block PA, the index of which is sufficiently high for this, for example 1.59, is received by a photosensitive receiver RL electrically powered by a device RE and connected to a measuring device RMC or RMR which gives a measure of the intensity of the light which traversed the fiber. The comparison of the measurements provided by the RMC and RMR devices provides, after calibration, a measurement of the losses in the ZC weld.

 The injection device DI is shown in FIGS. 2 to 5 and includes the arrangements previously described according to the invention, in the case where the two deformation pieces are identical at least as regards their parts in contact with the fibers. This means that a part 2 receives and maintains the receiving fiber FR during said preparatory steps, the other part receiving and maintaining the auxiliary fiber FA. Each of these parts is constituted by a body which may or may not be transparent and on which act said guide and clamping means. In the case of the DI device shown in FIG. 3, these means for guiding a part with respect to to the other are essentially constituted by an articulation around an axis 8 extending in the longitudinal direction at the rear of the device, and incidentally by the holding projections 20. This articulation makes it possible to open the device according to the arrow 10 to insert the FR receiving fiber.

 Said clamping means consist of a threaded rod 12 articulated around an also longitudinal axis 14 on the lower part 4 and provided with a knurled nut 16 which tightens the upper part 2. The unscrewing of this nut and the rotation of this rod upstream open the device. Other types of clamping means could be used, for example an elastic snap system.

 Two said blades such as 18 made for example of brass and comprising the thrust projections 6 come to bear on the fibers such as FR. Their thrust creates not only said deformations of the fibers which take a wavy shape, but also, by deformation of the primary sheaths GP and GPA, said contact areas which allow the passage of light from one fiber to another and whose transverse extent is visible in figure 5.

 As for said lateral holding means, they can be produced in various ways but preferably appear to have to be integral with one or both of the deformation pieces.

 In the case of the DI device, each of these parts includes such means for holding a fiber. These means are for example constituted by holding projections 20 whose shape is for example identical to that of the thrust projections 6. All of these projections are prismatic or cylindrical with transverse generators and are heard over the entire width of the faces on which they are formed. These retaining projections of a deformation part are longitudinally offset by half a wavy pitch with respect to those of the other deformation part. They allow both easy insertion of the fibers into the grooves of the bodies of these parts, good bilateral support, and interpenetration of the thrust projections 6 sufficient to ensure proper deformation of the fibers.

 The number of undulations of the fibers, that is to say the number of the thrust protrusions of each of the deformation pieces is for example 5. The radius of curvature at the top of these protrusions is for example 2mm so as not to damage the fibers. The distance between two successive projections of the same part, that is to say the pitch of the corrugation is for example 2mm. The amplitude of the ripple is for example 50 micrometers.

 The injection yield in a single mode fiber is for example 10-3%. It is 0.3% in a multimode fiber.

The injection device of FIG. 7 is similar to the device DI described above and comprises two deformation parts, one upper mobile 52, the other lower fixed 54. It differs therefrom in the following points
The movable part moves vertically under the action of a screw 56. Its guidance is essentially ensured by a thick vertical fixed guide blade 58 which penetrates into a wide groove of this movable part and which is also mounted in a groove even wider of the fixed part next to a thinner thrust blade 60 similar to the blades 18 of the previous device. This allows machining of these wide grooves easier than that of the narrow grooves which contained these blades 18.

 The two fibers FA and FR are superimposed in this order above the upper notched edge of the push blade 60, in the transverse gap left free between the guide blade 58 and a lateral surface of the wide groove dug in the fixed part. .

The upper part of this surface intersects holding projections 62 which are similar to the holding projections 20 and which provide lateral support on one side of the FR fiber.

 The underside of the upper deformation piece 52 has prismatic projections of similar shape, which over a small part of their length in the transverse direction, act as thrust projections and which, for the rest of their length, contribute to guiding of this part by preventing a longitudinal shift.

 It appears that, in this second light injection device, the lateral support of the two fibers is ensured by only one of the two deformation parts, part 54.

Claims (12)

1 / Device for injecting light into a sheathed optical fiber, in particular for the local control of a connection of two fibers, this device being intended to inject and guide a light into the core (CO) of an optical fiber receiver (FR) which must not be cut, this core being continuously surrounded by an optical sheath (GO) with a lower optical index to allow light to be guided and this optical sheath being itself surrounded by a primary sheath ( GP) to constitute a sheathed fiber whose optical sheath is protected by the primary sheath, the material of this primary sheath being transparent and having an optical index not substantially lower than that of this optical sheath, - this device comprising two deformation pieces of fibers (2, 4, 52, 54) respectively comprising two strips of fiber deformation, each of these strips having a length in a longitudinal direction and a width in a transverse direction the and comprising a regular longitudinal succession of thrust projections (6) which project in a thrust direction perpendicular to said longitudinal and transverse direction and separated by recesses, - means for guiding (8) deformation pieces to hold these two deformation bands facing each other, the lengths and width of these two bands being coextensive, the thrust projections of one band being opposite the hollows of the other band, - clamping means (12 , 16) of these deformation pieces to allow in preparatory steps to remove these pieces, to place a rectilinear injection section of said receiving fiber between the two said deformation bands with its length disposed in said longitudinal direction, and clamp these two parts against each other so that, during a later stage of light injection, said projections elastically bend this injection section by forming a a regular succession of alternating curvatures in a plane of curvature containing said longitudinal and thrust directions, - a light source (LA) for providing said light to be injected during said injection step, - and means for directing this light to be injected towards said injection section in directions which allow the injection of this light into the core of the fiber with the help of said alternating curvatures, - this device being characterized by the fact that it comprises - an auxiliary optical fiber (FA ) with an injection section which comprises a transparent outer sheath (GPA) and has an external diameter substantially equal to that of said sheathed receiving fiber (FR), this auxiliary fiber receiving said light to be injected at a distance from its injection section and guiding it as far as this section, - and means (20) for lateral holding of fibers arranged on both sides of the gap between the two said deformation bands and delimiting in said transverse direction a deformation channel whose width in this direction is substantially equal to the diameter of the two said injection sections, so as to allow during said preparatory steps to superimpose these two sections in this channel in said direction of thrust, each of these sections being arranged in said longitudinal direction and maintained by these lateral holding means, and in such a way that, during said injection step, these two sections are bent according to substantially the same alternating curvatures in the same plane of curvature so that the light to be injected escapes from this auxiliary fiber (FA) precisely in said directions which allow its injection into the receiving fiber (FR) without interrupting the primary sheath (GP) of the latter. 2 / Device according to claim 1, characterized in that said clamping means (12, 16) are capable of exerting during said injection step a clamping force sufficient to deform the section of the outer sheath (GPA, GP) of said auxiliary fiber (FA) and / or of the primary sheath of said receiving fiber (FR) so as to create optical contact areas having an extent in said longitudinal and transverse directions and allowing the direct passage of light from one to the other of these sheaths. 3 / Device according to claim 2, applicable in the case where the primary sheath (GP) of the receiving fiber (FR) is substantially less hard than its optical sheath (GO), this device being characterized in that said auxiliary fiber (FA ) is chosen to be substantially identical to said sheathed receiving fiber (FR) so as to easily obtain an auxiliary fiber such that the light which escapes therefrom in said precisely injection section has said directions allowing its injection into the receiving fiber. 4 / Device according to claim 1, characterized in that at least one of said deformation parts (2, 4, 54) comprises elements (20) for lateral support of fibers forming projections in said direction of pushing on both sides of said deformation band of this part, so that all of these holding elements of this or these parts constitute said holding means for bilaterally maintaining the two said injection sections not only during said injection step, but also during said preparatory steps when these parts are spaced from one another. 5 / Device according to claim 4, characterized in that said holding elements form, at least on one side of said deformation band of at least one deformation piece, a longitudinal succession of projections (20) for holding fibers, each of these retaining projections being located substantially in the same transverse plane as a said thrust projection (6), such a plane containing said transverse and thrust directions, the height of this retaining projection in the direction of thrust above this thrust projection being between 0.5 and 1 times the diameter of said fibers in each of the two deformation pieces (2, 4) or between 1.5 and 2 times this diameter in a single (54) of these parts so that the fiber holding elements of a deformation part ensure the bilateral maintenance of one or two said injection sections, respectively, hollows being formed between the consecutive holding projections to allow be at protrusions possibly holding the fiber of the other deformation part (4, 2, 52) to engage in these recesses during the tightening of these deformation parts and so as to allow these two parts to be brought together sufficiently one of the other. 6 / Device according to claim 5, characterized in that the shapes of said recesses between projections (20) for holding consecutive fibers of a deformation piece (2, 4) are complementary to the shapes of said projections of the other piece of deformation (4, 2) so that these recesses and projections form a part of said means for guiding the deformation parts. 7 / Device according to claim 4, characterized in that said fiber deformation band between said retaining elements is constituted by an upper edge of a blade (18) whose length is arranged in said longitudinal direction and the width along said thrust direction, this edge being hollowed out with notches to form said thrust projections (6), this blade being arranged in a groove formed in a body (2, 4) of deformation part and deeper than the width of this blade, the upper part of the lateral surfaces of this groove constituting said fiber holding elements (20). 8 / Method for injecting light into a sheathed optical fiber which constitutes a light receiving fiber (FR), this method comprising the following operations - application to a section of injection of the receiving fiber of parallel thrust forces between them and perpendicular to a longitudinal direction which is the general direction of this section, so as to impose on this section a succession of alternating curvatures in a plane of curvature which is the plane of these forces, - and sending of the light to be injected on this section in directions allowing the injection of this light into the core of this fiber with the help of these alternating curvatures, - this process being characterized by the fact that there is an injection section of an auxiliary optical fiber (FA ) along the receiving fiber injection section (FR) - said thrust forces are applied to all of these two sections, the plane of these forces being that of the two sections, so that these c i have the same alternating curvatures in the same plane of curvature, - and said light to be injected is injected into the core of this auxiliary fiber outside of its injection section so that this light is guided by this fiber up to the section, and that these alternating curvatures make it escape from this section in said directions allowing its injection into the receiving fiber. 9 / A method according to claim 8, applicable in the case where the receiving fiber comprises a transparent primary sheath (GP) substantially less hard than its optical sheath (GO), - this process being characterized in that the auxiliary fiber (FA) is chosen substantially identical to the receiving fiber (FR) so that the application of said thrust forces deforms the section of the primary sheaths (GP, GPA) of the two said injection sections by creating optical contact areas which facilitate the passage of light from one to the other of these sheaths. 10 / Method for measuring losses in an area to be checked (ZC) of an optical fiber (FR, - FL), in particular for local monitoring of a connection of two line optical fibers (FR, FL) of great length, this process comprising the following operations: injection of a control light into the heart of an injection section of a receiving fiber (FR) on one side of said zone to be controlled (ZC), the fiber of the other side of this zone being a fiber (FL) connected to the receiving fiber, this light coming from a control source (LA), being injected using an injection device and being directed towards this fiber connected so that it is guided there after passing through the area to be controlled, - derivation of this control light using a control bypass device (DC) from this connected fiber, - measurement of the intensity of the control light thus derived, - injection of a reference light into the heart of the same injection section ion from a reference source (LA) subjected to the same variations as the injection source, this light being injected using the same injection device (DI) and directed in the opposite direction to that of the control light, - bypass of this reference light (FR) from this receiving fiber at a distance from its said injection section, using a reference bypass device (DR) having a bypass efficiency known with respect to the efficiency of the control bypass device (DC), - measurement of the intensity of the reference light thus derived, - and calculation of the ratio of this intensity to that of the derived control light so as to obtain a measurement of the fraction of guided light lost in said zone to be controlled (ZC) independently of the injection efficiency of said injection device, - this method being characterized in that said injection device (DI) is a device according to claim 1, - said f auxiliary ibre (FA) comprising a control strand (BC) and a reference strand (BR) on either side of its injection section, - said control light being injected into this control strand and said reference in this reference strand. 11 / A method according to claim 10, characterized in that said control and reference sources are constituted by the same laser source (LA), the free ends of the two said control (BC) and reference (BR) strands of the auxiliary fiber (FA) being arranged opposite this source so as to guide the light in their heart, the number had the amplitude of said alternating curvatures being chosen large enough for the light injected by this source into one of these strands do not come back to disturb this source from the other strand. 12 / Device for injecting light in two opposite directions into a receiving optical fiber (FR), characterized in that it is constituted by an injection device according to claim 1, said auxiliary fiber (FA) receiving and guiding the light towards its injection section in two strands (BC, BR) of this fiber located on either side of this section.