EP4367538A1

EP4367538A1 - Coupling device for coupling hollow-core optical fibres comprising a coupling element

Info

Publication number: EP4367538A1
Application number: EP22737506.0A
Authority: EP
Inventors: Abdelfatah BENABID; Benoît DEBORD; Benoît BEAUDOU; Gilles Feugnet; Bertrand Morbieu
Original assignee: Glophotonics; Centre National de la Recherche Scientifique CNRS; Thales SA; Universite de Limoges
Current assignee: Glophotonics; Centre National de la Recherche Scientifique CNRS; Thales SA; Universite de Limoges
Priority date: 2021-07-08
Filing date: 2022-07-07
Publication date: 2024-05-15
Also published as: WO2023281010A1; FR3125137A1; CN117813533A

Abstract

The invention relates to a coupling device (D) for coupling optical fibres, comprising: - a first hollow-core optical fibre (FO1) with inhibited coupling comprising a first micro-structured sheath (SCF1) comprising a plurality of confinement tubular first patterns (MCF1), distributed in an annulus and at least partially surrounding a first core (C1) so as to confine at least radiation at a first wavelength λ _ορ <i />in the first core, - a second hollow-core optical fibre (FO2) with inhibited coupling comprising a second micro-structured sheath (SCF2) comprising a plurality of confinement tubular second patterns (MCF2), distributed in an annulus and at least partially surrounding a second core (C2) so as to confine the light radiation within the second core, - a coupling element (SCP) arranged between the first and the second core, said coupling element comprising at least a coupling tubular pattern (MCP, MCP1, MCP2, MTa) comprised at least partially within the first micro-structured sheath and/or the second micro-structured sheath and having a wall thickness tcp referred to as the coupling thickness and a material index n _cp known as the coupling index, an arrangement of the coupling element, the coupling thickness t _cp <i />and the coupling index ncp being contrived in such a way as to create a leakage path for the wavelength λ _ορ so as to allow coupling of the radiation guided by the first optical fibre towards the second optical fibre and/or from the second optical fibre towards the first optical fibre.

Description

Title of the invention: Coupling device for hollow-core optical fibers comprising a coupling element

Technical area :

The invention relates to the field of hollow-core microstructured optical fibers with inhibited coupling and more particularly that of hollow-core optical fiber couplers.

Previous technique:

[0002] The purpose of a fiber optic coupler is to transfer, with a minimum of optical losses, radiation guided in the core of one fiber to that of another fiber. It is known to produce a coupler by juxtaposing two optical fibers and bringing the cores of the two fibers closer by various techniques (polishing for example). Thus, the optical claddings of the two fibers overlap and part of the light propagated in a first optical fiber propagates in a second optical fiber. The most common method of making a coupler is to fuse together a polished side section of each fiber.

[0003] Hollow-core microstructured fibers can be separated into two main categories: bandgap guided fibers (HC-PCF-PBG for Hollow-Core; Photonic-Cristal-Fiber; Photonic BandGap in English) and fibers with inhibited coupling (HC-PCF-IC for Hollow-Core; Photonic-Cristal-Fiber; Inhibited Coupling in English). These types of fiber have many advantages for use in gyrometers, in particular: they have low losses, it is theoretically possible to transfer light from the core of the fiber to a resonant element of the micro-structured sheath, or vice versa, from the resonant element has a guiding heart. Similarly, this type of fiber shows light leakage from its core with an azimuthal distribution and a very particular polarization dependence. However, there is currently no coupler whose performance is comparable to that of couplers using conventional solid fibers. [0004] HC-PCF-PBG bandgap fiber couplers are under study (see Xu, Z. et al., Design of single-polarization coupler based on dual-core photonic band-gap fiber implied in resonant fiber optic gyro Optics Communications, 380, 302-309, (2016)). However, their production is extremely complex due to the guiding principle itself. In fact, guiding in PCF-PBG fibers is caused by the existence of photonic forbidden bands created by the periodicity of the structure of the microstructured sheath. Here, the guidance is carried out in a periodicity defect (the core) which has an index ni lower than that of the sheath. FIC-PCF-PBG fibers have hollow cores (air cross-section, index n ₁₌ 1). This guidance is therefore different from that of conventional optical fibers or with PCF microstructured sheaths with a solid core where the guiding and confinement of the light in the core is caused by the total internal reflection between the core of index ni and the microstructured sheath having an average index n _2eff less than n- _| .

[0005] Thus, making a coupler using PCF-PBG fibers presupposes working the microstructured sheath so as to remove a section without altering the physical integrity of the sheath or its optical properties. The goal is to bring the cores closer to a distance of the order of the wavelength of interest (~1 micron) to cover the evanescent field of the two modes of the core of the two hollow fibers to be coupled. Concretely, it is very difficult to modify the structure of the microstructured cladding in such a way as to bring the two cores sufficiently close together, without having too much impact on the quality of the fiber and the confinement by PBG.

Alternatively, IC fibers are optical fibers that have negative curvature core walls, offering low attenuation, ability to retain polarization, relatively large core modes, very low spatial overlap between the core mode and the core silica wall and a coupling efficiency exceeding 90% (see Debord, B. et al. Flollow-Core Fiber Technology: The Rising of “Gas Photonics”. Fibers 2019, 7, 16. ). In an IC-type FIC-PCF hollow-core fiber, the core mode and the cladding mode have the same effective index, so light propagating in the core could theoretically propagate in the cladding. However, the confinement and guidance of the core mode in these fibers is based on the inhibition between the coupling of the core mode and the cladding mode, this inhibition being obtained by the structure of the microstructured sheath and that of the contour of the heart. In other words, the scalar product between the electric field of the core mode |f _¥qiii· ) and that of the cladding mode |f _93ίhq > is very low. The coupling term between these two modes can be reduced by having a weak spatial intersection between the fields |f _¥qiii ) and |f _93ίhb > or by a strong shift between the transverse spatial phase of the core mode and that of the sheath. This confinement existing only for certain ranges of wavelengths, discontinuities are then observed in the index dispersion curve and therefore in the transmission curve.

[0007] FIG. 1 A presents a curve of the propagation losses as a function of the wavelength of a typical HC-PCF fiber of the IC type known from the prior art and illustrated in FIG. 1 B. The structure of this fiber is called HC-PCF-IC-SR-TL because the GMS microstructured sheath comprises a plurality of tubular patterns ("Tubular Lattice" or TL in English) -typically in silica- arranged around the hollow core C in a single ring (" Single Ring” or SR in English). In the example shown, the wall thickness of the tubular patterns is 2 mpi. As explained above, discontinuities in the propagation loss curve are observed in FIG. 1A. It is observed that the wavelengths included in the Zcf range present very low losses because there is a weak spatial intersection between the fields |f _¥qiii ) and |f _93ίhb > or a strong shift between the transverse spatial phase of the mode core and that of the sheath mode. The wavelengths included in this range Zcf can therefore be guided within the core C over long distances. The curve in FIG. 1 A illustrates an example of a wavelength l ₀ that can be guided by the fiber in FIG. 1 B. Conversely, wavelengths in the Zcp range have much higher losses. because there is a significant coupling between cladding modes and the core mode and therefore cannot be effectively guided.

[0008] It is known that fibers having a microstructured sheath of this type have particular leakage fields which depend on the structure of the microstructured sheath. Coupling two fibers of the FIC-PCF type of the IC type requires bringing them sufficiently close together and adjusting their respective azimuthal orientation so that there is an overlap of the leakage fields of the fibers in the coupler. More precisely, the coupling mechanism is based on leakage from one fiber "to" the other fiber and vice versa. In order to produce a coupler, the choice of an operating wavelength results from a compromise between the intensity of the leakage fields (therefore the coupling efficiency) and the losses by propagation.

[0009] It is known from document CN108549128A to produce a coupler based on two hollow-core optical fibers with inhibited coupling, the two cores being separated by an empty section. This void section is obtained by polishing the outer sheath and the microstructured sheath. It constitutes the main leakage channel allowing the coupling of radiation guided by one fiber to the other fiber when there is an overlap between the respective leakage channel of each fiber. However, critically, this embodiment requires a core approach distance (or interstitial distance) less than the wavelength in order to ensure sufficient overlap between the main leakage channel of the two fibers and thus allow coupling. efficient. If the distance between the two cores is too large, the maximum overlap between the leakage fields that can be obtained by adjusting the azimuthal orientations of the two fibers will be greatly reduced, as will the coupling efficiency. On the other hand, obtaining the shortest possible approach distance requires polishing a large section of the microstructured sheath of the two fibers, which can greatly degrade the performance of the optical fibers in the coupler. In addition, the approach distance is also limited by the outer sheath which surrounds the microstructured sheath. In practice, it is therefore not possible to decrease the interstitial distance beyond a certain value. The coupling efficiency of this device is therefore limited by these constraints.

The invention aims to overcome some of the aforementioned problems of the prior art with the aid of a coupler for hollow-core optical fibers with inhibited coupling having a coupling element arranged between the core of each fiber, the element coupling comprising the position, the materials and the geometry of which are adapted to create a leakage channel allowing a coupling of the radiation guided by a fiber towards the other fiber.

Summary of the invention:

To this end, an object of the invention is a coupling device for optical fibers comprising: - a first hollow-core optical fiber with inhibited coupling comprising a first microstructured sheath comprising a plurality of first confining tubular patterns, distributed in a ring and surrounding, at least partially, a first core so as to confine at least one radiation to a length d wave _gold in said first heart,

- a second hollow-core optical fiber with inhibited coupling, comprising a second microstructured sheath comprising a plurality of second confining tubular patterns, distributed in a ring and surrounding, at least partially, a second core so as to confine said light radiation in said second core ,

- a coupling element arranged between the first and the second core, said coupling element comprising at least one coupling tubular pattern included at least partially in said first microstructured sheath and/or said second microstructured sheath and having a wall thickness t _cp called thickness of coupling and a material index n _cp called coupling index, an arrangement of the coupling element, the coupling thickness t _cp and the coupling index n _cp being adapted so as to create a leakage channel for said length d wave l _or allowing coupling of the radiation guided by the first optical fiber to the second optical fiber and / or the second optical fiber to the first optical fiber.

According to one embodiment of the invention, each coupling tubular pattern ie [1, N] has a coupling thickness t _cp and a coupling index n _{cp i} such that

According to one embodiment of the invention, the coupling tubular patterns are arranged so that a distance D ₁₂ between the center of a coupling tubular pattern and an adjacent coupling tubular pattern is less than said wavelength the _gold .

According to one embodiment of the invention, the coupling element comprises at least a first and a second coupling tubular pattern. Preferably, in this embodiment, the plurality of first and second confining tubular patterns partially surrounds respectively said first and second core, said first coupling tubular pattern being arranged within the first optical fiber, facing a portion of the first core not surrounded by the plurality of first confining tubular patterns, said second coupling tubular pattern being arranged within the second optical fiber opposite a portion of the second core not surrounded by the plurality of second confining tubular patterns, the first and the second coupling tubular pattern being arranged facing each other.

According to another embodiment of the invention, the plurality of first and second tubular patterns completely confining respectively the first and the second core, said first and said second coupling tubular pattern being nested respectively in one of said first and second pattern tubular confining pattern, the first and the second coupling tubular pattern being arranged facing each other.

According to another embodiment of the invention, the first coupling tubular pattern is arranged within the first optical fiber, opposite a portion of the first core not surrounded by the plurality of first confining tubular patterns, and wherein the plurality of second confining tubular patterns completely surrounds the second core, said second coupling tubular pattern being nested in one of said second confining tubular patterns and arranged facing said first coupling tubular pattern.

According to one embodiment of the invention, the coupling element comprises at least one additional tubular pattern forming one of the coupling tubular patterns, arranged between the first and the second coupling tubular pattern.

According to another embodiment of the invention, the coupling element comprises a single coupling tubular pattern. Preferably, in this embodiment, the coupling tubular pattern is arranged facing a portion of the first core not surrounded by the plurality of first confining tubular patterns and facing a portion of the second core not surrounded by the plurality of first confining tubular patterns, said tubular pattern being disposed substantially between said portions. Alternatively, the plurality of first confining tubular patterns completely surrounds the first core and the plurality of second confining tubular patterns partially surrounds the second core, said coupling tubular pattern being arranged within the second fiber optical, opposite a portion of the second core not surrounded by the plurality of second confining tubular patterns, an azimuthal orientation of the first and of the second optical fiber within the device is adapted to maximize covering of said leakage channel with a leakage profile of said first microstructured sheath.

According to one embodiment of the invention, the coupling thickness(es) t _cp and the coupling index(es) n _cp are adapted so that said radiation is guided from the first optical fiber to the second optical fiber by exciting a spatial mode different from a spatial mode of said radiation guided by said first optical fiber

Brief description of figures:

Other characteristics, details and advantages of the invention will become apparent on reading the description made with reference to the appended drawings given by way of example and which represent, respectively:

[0021] [Fig.1 A], a propagation loss curve as a function of the wavelength of a typical HC-PCF fiber of the IC type known from the prior art, illustrated in [Fig.1 B]

[0022] [Fig.2], a coupling device for hollow-core optical fiber with inhibited coupling according to the invention,

[0023] [Fig.3], an embodiment of a first variant of the invention,

[0024] [Fig.4A], a graphic representation which makes it possible to better illustrate the effect of the SCP coupling element and more precisely of the confining tubular patterns within the fibers of the invention,

[0025] [Fig.4B], the radial field of the Poynting vector of the fiber of the embodiment of Fig. 3

[0026] [Fig.5A], [Fig.5B], respectively, a transverse and top view of the device D according to an embodiment of the first variant of the invention,

[0027] [Fig.6], an embodiment of the invention in which confining patterns respectively surround the first and the second heart,

[0028] [Fig.7], a device according to one embodiment of the invention, [0029] [Fig.8], a device according to one embodiment of the invention.

The references to the figures, when they are identical, correspond to the same elements.

[0031] In the figures, unless otherwise indicated, the elements are not to scale.

Detailed description :

Figure 2 schematically illustrates a coupling device D for hollow-core optical fiber with inhibited coupling according to the invention. This device D comprises a first hollow-core optical fiber FOI with inhibited coupling. This first optical fiber FOI has a first microstructured sheath SCF1 comprising a plurality of first confining tubular pattern MCF1 (not shown in FIG. 2 but visible in FIG. 3 for example). The first MCF pattern 1 is distributed in a ring surrounding, at least partially, the core of the FOI fiber called the first core C1, so as to confine at least one radiation at a wavelength l _or in the first core. It is understood that the pattern can be divided into a single ring or a plurality of concentric rings without departing from the scope of the invention.

Similarly, the device comprises a second F02 hollow-core optical fiber with inhibited coupling, comprising a second microstructured sheath SCF2. This second microstructured sheath comprises a plurality of second tubular pattern confining MCF2, distributed in a ring and surrounding, at least partially, the core C2 of the fiber F02, said second core, so as to confine the light radiation in the second core to the length wave

^op-

The fibers FOI, F02 respectively comprise a first and a second outer sheath GE1, GE2 which surround and protect the microstructured sheaths SCF1, SCF2.

In a manner known per se, in order to achieve the confinement of the _gold radiation in the first and second hearts C1, C2, the first and the second confining tubular patterns MCF1, MCF2 respectively have a first and a second thickness, called confining t _cfl , t _cf2 and a first and a second so-called confining index n _cfl and n _cf2 such that: with me N ^* . Preferably, the first confining patterns have an identical first wall thickness t _{cf l} in order to limit transmission losses as much as possible. Similarly, the second confining patterns have an identical wall thickness t _{cf 2} in order to limit transmission losses as much as possible. By way of non-limiting example, for confining patterns in silica, for radiation at _gold = 1550 nm, we have t _C f G [843 nm, 1181 nm], or t _C f G [1610 nm, 1968 nm] or even t _C f G [2362nm, 2725nm]

[0036] The tubular patterns confining MCF1, MCF2 can for example be circular cylindrical tubes or even “nested” structural patterns, that is to say an interweaving of different concentric tubes with increasingly smaller diameters. Alternatively, these tubular patterns can be tubes of elliptical shapes, the major axis of the ellipses being oriented radially, towards the center of the fiber or even any shape known to those skilled in the art. It is understood that the structure of the first and the structure of the second microstructured sheath may or may not be identical without departing from the scope of the invention.

As mentioned above, it is known to produce a coupler with hollow-core optical fibers with inhibited coupling by polishing the outer sheaths of the two fibers, thus obtaining a polished face for each fiber. The coupler is then made by bringing the two fibers together so that the interstitial distance is less than the wavelength and then by welding the two polished faces of the two fibers, the azimuthal orientations of the two fibers in the coupler being adjusted in such a way so that the overlapping of the leakage profiles of the two fibers is maximized. In this case, in order to ensure optimal guidance of the radiation, the tubular patterns of the microstructured sheaths have an identical wall thickness. The overlapping of the leak profiles ensures good coupling efficiency, however limited by the interstitial distance.

The invention differs from the prior art in that the coupling between the two fibers is achieved by means of an SCP coupling element resonant with the guided mode at the wavelength l _gold in the first core C1 and/or with the guided mode at the wavelength l _gold in the second core C2. As will be explained below, this coupling element makes it possible to create a leak channel from the first core C1 to the second core C2 and/or from the second core C2 to the first core C1. This coupling element makes it possible to obtain high coupling efficiency, without introducing excessive transmission losses. Indeed, the use of such a coupling element makes it possible to ensure high coupling and guiding efficiency, while avoiding the need to polish a large section of the microstructured sheath of the two fibers in order to bring the cores closer together. and maximizing the recovery of leak profiles as in the prior art, a step that can greatly degrade the performance of the optical fibers.

This SCP coupling element is arranged between the first and the second core and comprises at least one MCP coupling tubular pattern. By way of non-limiting example, the device D illustrated in FIG. 2 comprises a single tubular pattern coupling MCP. Alternatively, according to another embodiment, the coupling element SCP comprises a plurality of coupling tubular patterns, these being preferentially aligned on an axis connecting the cores C1, C2. The alignment of the patterns makes it possible to have the shortest possible distance in order to optimize the coupling (see FIG. 3 or 5A for example). At least one of the coupling tubular units is included at least partially in the first microstructured sheath SCF1 and/or in the second microstructured sheath SCF2. More specifically, according to a first alternative, at least one coupling tubular pattern MCP is included at least partially in the first sheath SCF1 in order to create a leak channel from the first core C1 to the second core C2. A coupler is then made from the fiber F01 to F02. According to a second alternative, at least one tubular pattern MCP is included at least partially in the second sheath SCF2 in order to create a leak channel from the second core C2 to the first core C1. A coupler is then produced from the fiber F02 to F01. According to a third alternative, at least one MCP tubular pattern is included at least partially in the first and in the second sheath SCF1, SCF2 in order to create a leak channel from the first core C1 to the second core C2 and from the second core C2 to the first core C1. A coupler is then produced from the fiber F02 to F01 and from the fiber F01 to F02. Indeed, by simulations and experimental tests, the inventors have realized that the use of tubular patterns coupling MCP having a wall thickness t _cp called coupling thickness, a material index n _tcp called coupling index, and an arrangement of the coupling element specifically adapted, made it possible to create a leakage channel for the wavelength l _or through this coupling element, thus allowing a coupling of the radiation guided by the first optical fiber towards the second optical fiber and /or from the second optical fiber to the first optical fiber. More precisely, the tubular patterns coupling MCP have a coupling thickness t _cp different from the confining thickness t _cfl , t _cf2 of the first and of the second confining tubular pattern in order to create a break in symmetry in the first and/or in the second microstructured sheath SCF1, SCF2. This symmetry break induces a radiation leakage channel through the coupling tubular patterns and therefore allows a coupling between a mode of the core C1, C2 with the sheath SCF1, SCF2. This leakage channel thus allows the coupling between the two fibers F01, F02 of the device.

The inventors have determined that, to create this leakage channel, it is necessary that each coupling tubular pattern ie [1, N] has a coupling thickness t _cp and a coupling index n _cp such that with m(0 e N ^* This condition allows the effective index n _{eff p} of the coupling element to be substantially equal to an effective index n _{eff cl} of the first core and/or an effective index of the second core at the wavelength l _or and as well as the coupling element is resonant with the first and/or the second core. Advantageously, the leakage of the guided radiation into the core C1 and/or C2 takes place very mainly through the coupling tubular pattern. This thus allows good coupling efficiency while having low propagation losses. FIG. 4A illustrates more precisely the effect of the coupling element SCP and of the tubular patterns coupling MCP on the curve of losses by propagation of the fibers F01, F02 (see below). The shape of the section of the tubular patterns coupling MCP can be circular or even elliptical, the major axis of the ellipses being oriented radially, towards the center of the fiber or even any pattern known for the HC-PCF-IC fibers of the skilled in the art. The tubular patterns coupling MCP can be of a shape identical to that of the confining tubular patterns or of different shape without departing from the scope of the invention.

As mentioned previously, in order to obtain good coupling efficiency, it is not necessary to have a distance between the cores C1 and C2 that is less than the wavelength. However, when the coupling element comprises a plurality of coupling tubular patterns MCP it is then necessary that a distance D ₁₂ between two adjacent coupling tubular patterns be less than 100 times said wavelength l _or , preferably less than 10 Å _op , still preferentially lower than _gold in order to ensure that the coupling efficiency is sufficiently high. This distance D ₁₂ is illustrated in FIG. 3 for example. It is defined as the minimum distance between the outer wall of two adjacent coupling tubular patterns. By adjacent MCP patterns is meant here two tubular patterns whose center is closest compared to other tubular patterns. Critically, this condition can be verified without polishing a section of the microstructured sheaths SCF1, SCF2 and therefore without degrading the performance of the optical fibers F01, F02 in the coupler (see for example FIG. 3 or 5A).

As mentioned previously, it is known that fibers of the FIC-PCF-IC type such as fibers F01, F02 have leakage fields with a particular radial distribution which depend on the precise structure of the microstructured sheaths SCF1, SCF2. Thus, within the device D, the fibers F01, F02 have a respective azimuthal orientation adapted so that there is a maximum overlap of the leakage fields of the fibers in order to maximize the coupling efficiency.

Until now, the device D of the invention was described with two fibers F01, F02 of the FIC-PCF-IC type without precisely describing the arrangement between the structure of the microstructured sheaths SCF1, SCF2 and that of the tubular patterns of the coupling element. Figures 3 to 9 show different embodiments in which these structures are described more precisely. In a first variant of the invention, illustrated in Figures 3 to 7, the coupling element SCP of the device D comprises at least a first and a second tubular pattern coupling MCP1, MCP2.

[0047] Figure 3 illustrates an embodiment of this first variant of the invention, in which the first and second microstructured sheath MCF1, MCF2 respectively comprise a plurality of first and second tubular patterns confining MCF1, MCF2 distributed in a single ring and partially surrounding the first and the second heart C1, C2. In the embodiment of FIG. 3, the first coupling tubular pattern MCP1 is arranged within the first optical fiber F01, opposite a portion of the first core C1 not surrounded by confining patterns MCF1 of the first microstructured sheath SCF1 . Similarly, the second coupling tubular pattern MCP2 is arranged within the second optical fiber F02 opposite a portion of the second core not surrounded by confining patterns MCF2 of the second microstructured sheath. As explained above, the first and second tubular patterns confining MCF1, MCF2 respectively have a first and a second confining thickness t _cfl , t _cf2 and a first and a second confining index n, C/l and n _cf2 such that with m EN ^* in order to confine the radiation to the wavelength l _or . Furthermore, the first and second coupling tubular patterns have a first and a second coupling thickness t _{cp l} , t _{cp 2} and a first and a second coupling index n _cpl , n _cp2 such that t _{cpl 2} e , with m EN ^* in order to create a leakage channel.

In order to maximize the coupling efficiency, the first and the second coupling tubular pattern are arranged facing each other and so that a distance D- ₁₂ between the outer wall of two adjacent coupling tubular patterns MCP1, MCP2 is less than 100 times the _gold wavelength, preferably less than 10 _gold , even more preferably less than _gold .

In the device of the invention, the fibers FOI, F02 can be maintained at a fixed distance by means of a casing in order to form a coupler. Alternatively, the fibers are welded together by their outer sheath GE1, GE2 surrounding the microstructured sheaths SCF1, SCF2.

FIG. 4A is a graphical representation which makes it possible to better illustrate the effect of the coupling element SCP and more precisely of the confining tubular patterns MCF1, MCF2 within the fibers F01, F02. FIG. 4A represents the propagation losses as a function of the wavelength of two different fibres. A fiber called conventional fiber similar to that represented in FIG. 1B, that is to say of the FIC-PCF-IC-SR-TL type with only a confining tubular pattern completely surrounding the hollow core of the fiber. The tubular patterns of the microstructured sheath of the conventional fiber are made of silica with a wall thickness of 2mpi. The curve of losses by propagation of this conventional fiber is the curve C _Cf of FIG. 4A. The propagation loss curve C _cp of FIG. 4A corresponds to that of the fibers F01, F02 of the embodiment of FIG. 3. These fibers are identical to the conventional fiber except for the fact that in the fibers F01, F02 , one of the tubular confining patterns of confining thickness t _cfl , t _cf2 and of confining index n _cfl , n _{cf 2} is replaced by one of the tubular patterns coupling MCP1 , MCP2 of coupling thickness t _{cp l} , t _{cp 2} and of coupling index n _gl , n _g2 .

By observing FIG. 4A, it is noted that, over the wavelength range Z1, the losses are substantially greater for the fibers F01, F02 than for the conventional fiber. This is explained by the introduction of the coupling tubular pattern MCP1 MCP2, which creates a break in symmetry in the microstructured sheath of the fibers F01, F02 and therefore slightly deteriorates the confinement of these wavelengths in the Z1 range. It is further noted that the introduction of the coupling tubular pattern MCP1 MCP2 in the fibers F01, F02 does not modify the fact that the wavelengths of the Z2 range are not confined in the heart. In the F01, F02 fibers and in the conventional fiber, these wavelengths of the Z2 range are not confined in the core and “escape” through the microstructured sheath. Finally, on the Z3 wavelength range, it can be seen that the coupling element creates a leakage channel LP for the fibers F01, F02 centered at approximately X _LP =1.55mpi which is not present on curve C _See for conventional fiber. Concerning the radial distribution of the leakage field, the leakage takes place via the coupling element SCP through the first and second tubular pattern coupling MCP1, MCP2. The radial field of the Poynting vector of the fiber of the embodiment of FIG. 3 is represented in FIG. 4B and makes it possible to observe the radial distribution of the leakage field. In Figure 4B, the brighter a region, the higher the electric field in that region. Although the most intense field is that confined in the core of the fiber, it is observed that there is a non-negligible leakage field through the coupling pattern MCP1. The presence of this tubular pattern coupling MCP1, MCP2 therefore allows the creation of a directional and controlled leak. The arrangement of the first and second coupling tubular pattern within the microstructured sheath being symmetrical in the fiber F01 and in the fiber F02 in the embodiment of FIGS. 3 and 4, the coupling element creates a leakage channel in the first fiber F01 and in the second fiber F02. It is the spatial overlap between the respective leakage channel LP of the fibers F01, F02 which allows good coupling efficiency from the fiber F01 to the fiber F02 and the reverse in the device of the embodiment of FIG. 3. C This is why the first and the second tubular pattern coupling MCP1, MCP2 are opposite each other. Thus, unlike the HC-PCF-IC-SR-TL fiber couplers of the prior art in which it was necessary to degrade the performance of the optical fibers, the invention allows effective coupling without introducing propagation losses. high.

As mentioned above, there is a compromise between the intensity of the leakage channel LP and (thus the coupling efficiency) and the losses by propagation. In FIG. 4A, a cross illustrates an example of length l _or adapted to allow effective coupling while maintaining low propagation losses. In concrete terms, the wavelength l _or must be sufficiently close to the wavelength À _LP of the LP channel to allow leakage of the guided radiation into the cores C1, C2 through the coupling element SCP, but not too much. close in order to avoid too high propagation losses. This optimum is to be determined by the user according to the desired applications.

Similarly, by adjusting the thickness of the tubular patterns coupling MCP1, MPC2, it is possible to adjust the intensity of the leakage channel at the wavelength l _or . More specifically, within the G1 range specified above, more the thickness of the coupling tubular patterns is close to the central value of the m(i) range G1 (i.e. t _cp

2 ^lor ), the greater the propagation losses within the ncp ^-1 fiber and the intensity of the leakage channel. Conversely, the closer the thickness of the coupling tubular patterns is to the limits of the range G1 (i.e. t _cp = ), the greater the losses by propagation and the intensity of the coupling leakage channel are small. There is therefore a compromise to be found between sufficient coupling and a correct level of losses at the wavelength

^op-

Figures 5A and 5B respectively illustrate a transverse and top view of the device D according to an embodiment of the first variant of the invention. In the device of FIGS. 5A and 5B, the fibers F01 and F02 are identical to those of the embodiment of FIG. 4A except for the fact that the coupling element SCP comprises an additional coupling pattern MTa forming one of the tubular coupling patterns . This MTa pattern is arranged between the first and the second coupling tubular pattern. Like all tubular coupling units, the additional coupling unit MTa has a coupling thickness t _{cp a} and a coupling index n _cp such that Afin to obtain good coupling efficiency, the additional coupling pattern MTa is arranged so that the additional coupling pattern MTa is at a distance from the first and from the second pattern MCP1, MCP2 of less than 100l _or and so that the patterns coupling MCP1, MCP2, MTa are aligned on an axis connecting the cores C1, C2. The additional coupling pattern MTa makes it possible to facilitate the coupling between the fibers F01, F02, this being achieved without the need to weld the outer sheath of the fibers (not shown in FIGS. 5A and 5B). Indeed, according to one embodiment, the fibers F01, F02 are held in a fixed position by means of a box so as to be joined or juxtaposed to the additional coupling pattern MTa thus forming a simple and effective coupler as illustrated in Figure 5B.

By way of non-limiting example, the embodiment illustrated in FIGS. 5A and 5B comprises a single additional coupling unit MTA. Alternatively, depending on In another embodiment, the coupling element SCP comprises a plurality of additional coupling tubular patterns MTa arranged so that a distance between the center of two adjacent additional coupling tubular patterns is less than 100l _or .

FIG. 6 illustrates an embodiment of the invention in which confining patterns MCF1, MCF2 completely surround the first and second cores C1, C2 respectively. The first and the second tubular pattern coupling MCP1, MCP2 are then nested in one of the first and second tubular patterns confining MCF1, MCF2, as in microstructured sheaths comprising “nested” structure patterns. In order to maximize the coupling efficiency, the first and the second tubular pattern coupling MCP1, MCP2 are arranged opposite each other. Device D of this embodiment has the advantage of comprising F01, F02 fibers with microstructured sheaths with tubular patterns confining MCF1, MCF2 which completely surround the heart. Thus, the break in symmetry introduced by the tubular patterns coupling MCP1, MCP2 is less significant than in the embodiments of FIGS. 3 and 5A, 5B and the propagation losses are lower.

It is understood that the coupling element SCP of this embodiment may comprise one or more additional tubular patterns MTa between the first and the second tubular coupling pattern MCP1, MCP2, as in the embodiment of FIGS. 5A, 5B .

FIG. 7 schematically illustrates a device D according to one embodiment of the invention in which the structure of the fiber F01 is identical to the fiber F01 of the embodiment illustrated in FIG. 3 and 5A and in which the structure of the fiber F02 is identical to the structure of the fiber F02 of the embodiment illustrated in FIG. 6. More specifically, the first coupling tubular pattern MCP1 is arranged within the first optical fiber, opposite a portion of the first core not surrounded by the plurality of first tubular patterns confining MCF1. In addition, the plurality of second confining tubular patterns MCF2 entirely surrounds the second core and the second coupling tubular pattern MCP2 is nested in one of the second confining tubular patterns. In order to maximize the coupling efficiency, the first and the second tubular pattern coupling MCP1, MCP2 are arranged facing each other. The mode of embodiment of FIG. 7 illustrates the modularity of the coupling element SCP.

Note that the embodiment of Figures 3 to 7 belongs to the third alternative of the invention. That is to say, the coupling element of these embodiments allows the creation of a leakage channel for the radiation guided in the first core C1 towards the second core C2 and for the radiation guided in the second core C2 to the first core C1. It is the symmetrical configuration of the distribution of the coupling tubular patterns within the SCP element that allows bidirectional coupling with an equivalent leakage intensity from the F01 fiber to the F02 fiber and from the F02 fiber to the F01 fiber.

In a second variant of the invention, illustrated in FIGS. 8 and 9, the coupling element SCP of the device D comprises a single tubular coupling pattern MCP.

[0062] FIG. 8 illustrates a device according to one embodiment of the invention in which the coupling tubular pattern MCP is arranged opposite a portion of the first core C1 not surrounded by the plurality of first tubular patterns confining MCF1 and in view of a portion of the second core C2 not surrounded by the plurality of second tubular patterns confining MCF2. The presence of a defect or symmetry break (unsurrounded portion of the core and SCP coupling element) in the microstructured sheath of the fibers F01, F02 implies that the escape of the guided radiation in the core C1, C2 is done very mainly by this defect and therefore through the coupling element MCP. Thus, the coupling efficiency of this embodiment is particularly high because it allows a rapprochement of the two cores C1, C2.

In order to allow the coupling of the first core to the second core and of the second core to the first core through the coupling tubular pattern MCP, the tubular pattern is arranged substantially between the portions not surrounded by the microstructured sheaths SCF1, SCF2, halfway between cores C1, C2. In addition, it is necessary for a distance between the first core and the coupling tubular pattern and between the second core and the coupling tubular pattern to be typically less than 100l _or , otherwise the maximum coverage of the leakage fields will be too low. FIG. 9 illustrates a device according to one embodiment of the invention in which the plurality of first tubular patterns confining MCF1 completely surrounds the first core and the plurality of second tubular patterns confining MCF2 partially surrounds the second core. In this embodiment, the coupling tubular pattern MCP is arranged within the second optical fiber F02, opposite a portion of the second core C1 not surrounded by the plurality of second tubular patterns confining MCF1. In addition, an azimuthal orientation of the first and of the second optical fiber FOI, F02 within the device is adapted to maximize coverage of the leakage channel with the leakage profile of said first microstructured sheath and adapted to optimize the space between the tubular patterns of the two fibers.

In the embodiment illustrated in Figure 9, the coupling tubular pattern is arranged between the face of a "gap" or spacing between two tubular patterns confining MCF1 of the first microstructured sheath because, in the FOI fiber, the leak is made mainly by the space between two tubular patterns confining MCF1. This is due to the fact that the spacing between the tubular motifs confining MCF1 is greater than a critical value. This critical value is determined by simulation. The arrangement of the coupling element and the azimuthal orientation of the fibers F01, F02 therefore allows effective coupling of the second fiber to the first fiber because the coupling element creates a leak channel for the radiation guided in the second heart C2 to the first core C1. It also creates a leak channel for the radiation guided in the first core C1 towards the second core C2. Alternatively, according to another embodiment, the arrangement of the fibers F01, F02 in the coupler is reversed.

According to another embodiment of Figure 9, the structure of the first microstructured sheath is different, so that the radial distribution of the leakage field of the fiber F01 is different from that of Figure 8. For example, the fiber F01, may comprise closer tubular patterns (and lower than the critical value), so that the leak occurs mainly through the sections of the confining tubular patterns touching the outer sheath GE1. Alternatively, the sheath may include a break in azimuthal symmetry on the number of tubes confining the sheath (as in FIG. 8) so that the leak occurs mainly through this defect. The relationship between the distribution radial of the leakage field and of the microstructured sheath structure (without coupling tubular pattern) of fibers of the HC-PCF-IC-SR-TL type is known to those skilled in the art. Application FR 1904610 describes various microstructured sheath structures of fiber of the FIC-PCF-IC-SR-TL type -and their associated leakage profile- which can be used in the fiber F01 of the embodiment of FIG. 9. Although the radial distribution of the leakage field may be different depending on the structure of the MCF1 sheath, in the embodiment of FIG. 9, the azimuthal orientation of the first and of the second optical fiber within the device is always adapted to maximize a covering the leak channel with the leak profile of the first microstructured sheath.

According to one embodiment, the coupling thickness(es) t _cp and the coupling index(es) n _cp are adapted so that the radiation is guided from the first optical fiber to the second optical fiber by exciting a different spatial mode. (called M2) of a spatial mode (M1) of the radiation guided by said first optical fiber. For this, it is essential that there is an equality of the effective index of the M1 mode of the C1 core with the effective index of the M2 mode of the C2 core, at the wavelength l _or . Moreover, as specified previously, these effective indices must also be equal to that of the coupling element SCP. In order to control the effective index of the coupling element, in a manner known per se, it is possible to adjust the size of the cores C1, C2 and/or the shape of the cores C1, C2 and/or the index of the claddings microstructured SCF1, SCF2. It is also possible to modify the index of the cores C1, C2, for example by filling it with a particular gas and finely adjusting the pressure of the latter within the cores C1, C2.

Claims

1. Coupling device (D) for optical fibers comprising:

- a first hollow-core optical fiber (F01) with inhibited coupling comprising a first microstructured sheath (SCF1) comprising a plurality of first confining tubular pattern (MCF1) a first thickness, called confining t _cfl , distributed in a ring and surrounding, at least partially, a first core (C1) so as to confine at least one radiation at a wavelength l _or in said first core,

- a second hollow-core optical fiber (F02) with inhibited coupling, comprising a second microstructured sheath (SCF2) comprising a plurality of second confining tubular pattern (MCF2) having a second thickness, called confining t _cf2 , distributed in a ring and surrounding, at least partially, a second core (C2) so as to confine said light radiation in said second core,

- a coupling element (SCP) arranged between the first and the second core, said coupling element comprising at least one tubular coupling pattern (MCP, MCP1, MCP2, MTa) comprised at least partially in said first microstructured sheath and/or said second sheath microstructured and having a wall thickness t _cp called coupling thickness and a material index n _cp called coupling index, said coupling thickness t _cp being different from said first and second confining thickness t _cfl , t _cf2 an arrangement of the coupling element, the coupling thickness t _c and the coupling index n _cp being adapted as a function of the said wavelength l _or so as to create a leakage channel for the said wavelength l _or allowing a coupling radiation guided by the first optical fiber to the second optical fiber and/or from the second optical fiber to the first optical fiber.

2. Device according to claim 1, in which each coupling tubular pattern ie [1, N] has a coupling thickness t _cp and a coupling index n _{cp i}

3. Device according to any one of the preceding claims, in which the coupling tubular patterns are arranged such that a distance (D12) between the center of a coupling tubular pattern and an adjacent coupling tubular pattern is less than said length d _gold wave.

4. Device according to any one of the preceding claims, in which the said coupling element comprises at least a first (MCP1) and a second (MCP2) coupling tubular pattern.

5. Device according to the preceding claim, in which the plurality of first and second confining tubular patterns partially surrounds respectively said first and second core, said first coupling tubular pattern (MCP1) being arranged within the first optical fiber, facing a portion of the first core not surrounded by the plurality of first confining tubular patterns, said second coupling tubular pattern (MCP2) being arranged within the second optical fiber facing a portion of the second core not surrounded by the plurality of second patterns tubular confining pattern, the first and the second coupling tubular pattern being arranged facing each other.

6. Device according to claim 4, in the plurality of first and second tubular patterns completely confining respectively the first and the second core, said first and said second coupling tubular pattern (MCP1, MCP2) being nested respectively in one of said first and second pattern tubular confining pattern, the first and the second coupling tubular pattern being arranged facing each other.

7. Device according to claim 4, in which said first coupling tubular pattern (MCP1) is arranged within the first optical fiber, facing a portion of the first core not surrounded by the plurality of first patterns. confining tubular patterns, and in which the plurality of second confining tubular patterns completely surrounds the second core, said second coupling tubular pattern (MCP2) being nested in one of said second confining tubular patterns and arranged facing said first coupling tubular pattern.

8. Device according to any one of claims 4 to 7, wherein the coupling element comprises at least one additional tubular pattern (MTa) forming one of the coupling tubular patterns, arranged between the first and the second coupling tubular pattern.

9. Device according to any one of claims 1 to 3, wherein said coupling element comprises a single coupling tubular pattern (MCP).

10. Device according to the preceding claim, in which the coupling tubular pattern (MCP) is arranged facing a portion of the first core not surrounded by the plurality of first confining tubular patterns and facing a portion of the second core not surrounded by the plurality of first confining tubular patterns, said tubular pattern being disposed substantially between said portions.

11. Device according to claim 9, in which the plurality of first confining tubular patterns completely surrounds the first core and the plurality of second confining tubular patterns partially surrounds the second core, said coupling tubular pattern (MCP) being arranged within the second optical fiber, facing a portion of the second core not surrounded by the plurality of second confining tubular patterns, an azimuthal orientation of the first and of the second optical fiber within the device is adapted to maximize covering of said leakage channel with a leak profile of said first microstructured sheath.

12. Device according to any one of the preceding claims, in which the coupling thickness(es) t _cp and the coupling index(es) n _cp are adapted so that said radiation is guided from the first optical fiber towards the second optical fiber by exciting a spatial mode different from a spatial mode of said radiation guided by said first optical fiber.