BRPI0701814B1 - “OPTICAL TRANSMISSION FIBER, OPTICAL MODULE, STORAGE BOX, AND FIBER TO HOME OR FIBER OPTICAL SYSTEM” - Google Patents

Abstract

single mode optical fiber. an optical transmission fiber comprising a central core, a first intermediate sheath having a dn ~ 2 ~ index difference with the outer sheath, a first recessed sheath having a dn ~ 3 ~ index difference with the outer sheath which is greater than or equal to -5.10 ^ -3 ^, second intermediate coating having a coating having an index difference of dn ~ 4 ~ with the outer coating and the second recessed coating having an index difference of dn ~ 5 ~ with the external coating. the optical fiber has, at a wavelength of 1625 nm, bending losses of less than or equal to 0,1 db / l0 turns for a bending radius of 15 mm and bending losses of less than or equal to 0,5 db / revolution. for a radius of curvature of 7,5 mm. Optical fiber has reduced curvature and micro-curvature losses while presenting the optical performance of a standard step index (ssmf) transmission fiber.

Description

(54) Title: OPTICAL TRANSMISSION FIBER, OPTICAL MODULE, STORAGE BOX, AND FIBER OPTICAL SYSTEM TO THE HOUSE OR FIBER TO THE SIDEWALK (51) Int.CI .: G02B 6/028; G02B 6/036 (30) Unionist Priority: 10/04/2006 NL 06 03128 (73) Holder (s): DRAKA COMTEQ B.V.

(72) Inventor (s): LOUIS-ANNE DE MONTMORILLON; DENIS MOLIN; EMMANUEL PETITFRERE; YVES LUMINEAU; FRANCISCUS JOHANNES ACHTEN; MARIANNE BIGOT-ASTRUC; PIERRE SILLARD; PASCALE NOUCHI; PIETER MATTHIJSSE; FRANS GOOIJER

OPTICAL TRANSMISSION FIBER, OPTICAL MODULE, STORAGE BOX, AND FIBER OPTICAL SYSTEM TO THE HOUSE OR FIBER TO THE SIDEWALK

The present invention relates to the field of transmissions through optical fiber, and, more specifically, to a yarn fiber having reduced losses due to curvatures and microcurves.

In optical fibers, the index profile is generally described as the appearance of the graph of the function that associates the refractive index to the fiber radius. In conventional terms, the distance r to the center of the fiber is represented on the abscissa and the difference between the refractive index and the refractive index of the fiber coating (shell) is represented on the ordinate. The index profile is therefore referred to as a step, trapezoid or triangle in the graphs that respectively have the shape of a step, a trapezoid or a triangle. These curves are generally representative of the theoretical or defined profile of the fiber; limitations in fiber manufacture may result in a substantially different profile.

An optical fiber conventionally consists of an optical nucleus, which has the function of transmitting and possibly amplifying an optical signal, and an external optical coating, which has the function of confining the optical signal in the nucleus. To this end, the refractive indices of the core nc and the external optical coating ng are such that nc> ng. As is well known, the proportion of an optical signal in a single-mode optical fiber is broken down into a fundamental guided mode in the core and in the secondary modes guided by a certain distance in the core - coating (shell) assembly, called coating modes ( shell).

In conventional terms, step-type index fibers also called single-mode fibers (SMF) are used as a yarn fiber in optical fiber transmission systems. These fibers exhibit a chromatic dispersion and a chromatic dispersion slope that meet specific telecommunications standards.

In the compatibility requirements between optical systems from different manufacturers, the International Telecommunication Union, whose acronym is ITU, defined a standard with a specification referred to as ITUPetition 870180004344, of 17/01/2018, p. 5/12 • * · · · · · * · * · · · · · ♦ ····· ·· * · * · · * ··· ·· * ·· »

T G.652, which an optical fiber for a standard transmission must meet, called SSMF for a standard single-mode fiber.

This G.652 specification recommends, among other things, for a transmission fiber, the [8.6; 9.5 pm] for the modal field diameter (MFD) value, at a wavelength of 1310 nm; a maximum of 1260 nm for the cable cut-off wavelength value; the range of [1300; 1324 nm] for the zero dispersion wavelength, noted as λ ₀ ; a maximum of 0.092 ps / nm ² -km for the chromatic dispersion slope value. The cable cut-off wavelength is conventionally measured as the wavelength at which the optical signal is no longer a single mode after propagation by twenty-two meters of fiber, as, for example, defined by sub-committee 86A International Electrotechnical Commission in the standard (EC 60793-1-44.

Also for a given fiber, a value called MAC is defined as the ratio of the modal field diameter of the fiber at 1550 nm and the effective cutting wavelength Àceff θ defined. The cable cut-off wavelength is conventionally measured as the wavelength at which the optical signal is no longer a single mode after propagation by two meters of fiber, as defined by the 86A sub-committee of the Inter20 National Electrotechnical Commission in the standard IEC 60793-1-44. The MAC value is a parameter to assess the fiber's performance, in particular, to find a compromise between the modal field diameter, the effective cutting wavelength and the curvature losses.

Figure 1 illustrates the applicant's experimental results and illustrates the curvature losses at the wavelength of 1625 nm with a radius of curvature of 15 mm in a step-index SSMF fiber versus the MAC value at the wavelength of 1550 nm . It is observed that the MAC value influences the losses of curvature of the fiber and that these losses of curvature can be reduced by reducing the MAC value.

Now, a reduction in the MAC value, by reducing the modal field diameter and / or by increasing the effective cutting wavelength, can result in a situation outside the G.652 standard and make the fiber eat ·· »· · ·· ♦ · ·· · ·· · · * ·· · * · · »·» · · ···· * * · * ··· »·« · # · * ··· ·· · · · · »·· ·« 1 · Ι · cially incompatible with certain transmission systems.

In effect, the value of the effective cutting wavelength X _C etf cannot be increased beyond a limit value in order to observe the maximum value of 1260 nm for the cable cutting frequency λ <χ · Also, the value of modal field diameter for a given wavelength is strictly imposed in order to minimize coupling losses between fibers.

The reduction of the MAC value criterion to limit the curvature losses must therefore be combined with a limitation of the effective cutting wavelength value. _Ce ff in order to limit the propagation of higher order modes in the fiber, while maintaining a modal field diameter sufficient to provide a coupling without too much optical loss.

In particular, meeting the G.652 standard and reducing curvature losses are a real challenge for fiber applications intended for both optical fiber and even individual systems, so-called fibers to the home (FTTH) or optical systems to the sidewalk or to the building - so-called fibers to the sidewalk (FTTC).

In fact, an optical fiber transmission system comprises storage boxes in which excessive lengths of fiber are provided in the case of future interventions; these excessive lengths are rolled into the boxes. In view of the intention of miniaturizing these boxes for FTTH or FTTC fiber applications, it is desired that the fibers in a unique way in this context are rolled up or that they are of increasingly smaller diameters (in order to reach small radii of curvature such as 15 mm). Also, within the scope of FTTH or FTTC fiber applications, there is a risk that the fibers will be subject to more severe installation limitations than in applications of greater distances, that is, the presence of accidental curvatures related to the low cost of installation and to the environment. Provision must be made for the presence of accidental bending radii equal to 7.5 mm or even 5 mm. It is, therefore, absolutely necessary, in order to meet the limitations related to storage boxes and installation limitations, that fibers

j co used for FTTH or FTTC fiber applications have limited curvature losses. However, it should be understood that this reduction in curvature losses should not be achieved at the expense of a loss of the signal's unique mode character, which would strongly deteriorate the signal, or at the expense of the introduction of significant optical junction losses.

USN 4 852 968 relates to a single mode optical fiber having an index profile consisting of a core region, a first coating region, a trench region, and a second coating region and optionally a second trench region.

This document refers to the optimization of dispersion characteristics.

In order to obtain optical fibers that meet the requirement to reduce curvature losses, three types of solutions have been proposed in the prior art.

A first solution found in the prior art is to produce conventional step index fibers with a reduced modal field diameter. The curvature losses are in fact reduced by decreasing the MAC value due to the reduction in the modal field diameter, and the unique mode character is limited to a cable cut-off wavelength that remains less than 1260 nm. However, these fibers have significant coupling losses and do not adapt to the FTTH fiber applications described above.

The publication of the l. Sakabe et al ,, Enhanced Bending Loss Insensitive Fíber and New Cables for CWDM Access Networks,

IWCS Procedure 53 °, pages 112-118 (2004), suggests reducing the modal field diameter of the fiber in order to reduce curvature losses. This reduction in the modal field diameter, however, is outside the G.652 standard.

The publication of the document by T. Yokokawa et al., Ultra-Iow

Loss and Bend insensitive Pure-silica-core Fiber Complying with G.652 C / D and its Applications to a Loose Tube Cable, IWCS Procedure 53 °, pages 150-155 (2004), proposes a pure silica core fiber (PSCF ) having reduced transmission and curvature losses, but with a reduced field diameter), which is outside the G.652 standard.

A second solution found in the prior art is to produce step index fibers with a lowered section; that is, a central core, an intermediate coating (shell) and a lowered coating (shell). With such a structure, it becomes possible in fact to reduce curvature losses with a constant MAC value for small radii of V 'curvature, typically 10 mm.

The publications of S. Matsuo et al., Low-bending-loss and low10 splice-loss single-mode fibers employing a trench index profile, Journal of Lightwave Technology, Volume 23 N. 11, pages 3494-3499 (2005) and of K. Himero et al., Low-bending-loss single mode fibers for ftber-to-the home,

Journal of Lightware Technology, volume 23, proposes such low-section fiber structures to reduce curvature losses.

Now, the analyzes conducted by the applicant have shown that if the curvature losses can be substantially improved with a fiber profile with recessed sections, such profile also causes an increase in the effective cutting wavelength by the occurrence of resistant leakage modes that mainly are propagate in the intermediate coating (shell) and in the lowered section.

This observation, therefore, requires that fibers having a

MAC less than 7.9 at 1550 nm is selected to compensate for the fact that the effective cutting wavelength is much longer than expected, while ensuring curvature losses at 1625 nm less than 0.1 dB / turn for a winding with a radius of 15 mm; while for an SSMF fiber, it is sufficient to select fibers with a MAC value less than 8.1 at 1550 nm in order to guarantee losses less than 0.1 dB / turn at 1625 nm for a radius of curvature of 15 mm (from results of figure 1). The manufacturing yield for such step index fibers with a recessed section is therefore reduced.

A third solution found in the prior art is the production of step-indexed fibers assisted with a hole.

• «· 4» * »» «» · * ♦ · »· t« «· · · · * · · * * · · · · · · * *» * * · »·» · «· ·» »» · ««

The publication by K. Bandou et ak, Development of Premise Opticaí Wiring Components Using Hole-Assisted Fiber, IWCS Procedure 53, pages 119-122 (2004), proposes a fiber with holes, whose fiber has the optical characteristics of an SSMF fiber of step index with reduced loss of curvature.

Such step index fibers aided with holes to reduce curvature losses have also been described in the publications of T. Hasegawa et ak, Bend-insensitive single-mode holey fiber with SMFcompatibility for optical wiring applications, in Proceedings ECOC'03, document We2.7.3, Rimini, Italy (2003), by D. Nishioka et ak, Development of holey fiber supporting extra-small diameter bending, SEI Technical Review, N. 58, pages 42-47, (2004); by K. Miyake et ak, Bend resistant photonic crystal fiber compatible with conventional single mode fiber, in Proceedings ECOCO4, document MO3.3.4, Stockholm, Sweden, (2004); by Y. Tsuchida et ak, Design and characterization of single-mode holey fibers with low bending losses, Optics Express, Volume 13, N. 12, pages 4470-4479, (2005), by K. Ohsono et ak, High performance optical fibers for next generation transmission systems, Hitachi Cable Review, N. 22, pages 1-5, (2003); by K. Nakajima et ak, Hole-assisted fiber design for small bending and splice loss, IEEE Photonics Technology Letters, Volume 15, N. 12, pages 1737-1739, (2003); by K. leda et ak, Transmission characteristcs of a hole-assisted fiber cord for flexible optical wiring, Proceedings 54 ^th IWCS, pages 63-68 (2005); by N. Guan et ak, Hole-assisted single mode fibers for low bending loss, in Proceedings ECOC'04, document Mo3.3.5., Stockholm, Sweden (2004), and by K. Himeno et ak, Low-bending-loss single-mode fibers for fiber-to-the-home, Journal of Lightwave Technology, Volume 23, N. 11, pages 3494-3499, (2005).

The cost of manufacturing such a fiber and the currently high attenuation levels (> 0.25 dB / km) make it difficult to use commercially in FTTH or FTTC fiber systems. Furthermore, with these fibers, it is simply impossible to obtain the optical characteristics recommended by the G.652 standard, especially in terms of dispersion

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· * ♦ · * *> »*« · · · · · · * · · · · · · «» »• * · · · · · · * * ♦ · * * · ··· · · · ·· ··· 9 chromatic.

Therefore, there is a need for a transmission fiber with which it is possible to meet the criteria of the G.652 standard, that is, that is commercially usable in FTTH or FTTC type fiber transmission systems, and that has reduced losses of curvature and microcurvature. In particular, there is a need for a fiber that has reduced losses for a radius of curvature of 15 mm and also for a radius of curvature as small as 7.5 mm. In fact, in FTTH fiber applications, excessive lengths of fibers are generally rolled up in storage boxes each time miniaturized; in addition, the fiber will be subject to significant bending stresses related to the environment of your installation.

To this end, the present invention proposes an optical fiber having a particular step index profile, with a first section that is highly recessed and a second section that is slightly recessed.

With such a structure, it is possible to effectively reduce curvature losses to a constant MAC value, while minimizing the leakage modes of a larger order. In this way, unlike the prior art fibers that have a step index structure with a recessed section, the fiber of the present invention has a cable cut-off wavelength that remains less than 1260 mm. The fiber of the present invention, therefore, meets the G.652 standard.

More particularly, the present invention proposes an optical transmission fiber comprising:

- a central core having a Dni index difference with an external optical coating;

- a first internal intermediate coating having a difference of Dn2 index with the external optical coating;

- a first recessed inner coating having a difference of index Dn ₃ with the external optical coating less than or equal to 5.10 '³;

- a second internal intermediate coating having a difference

· * « 4 1 · «» · »4 C • · · • · · • · 4 * » «4 * * * » 4 · 4 * t V * 4 4 4 « • · * ·· V · • · · • 4 * * * 4 « • · » • 4 »4» é · · 4

Dn ₄ index difference with the external optical coating;

- a second recessed coating having a difference of index Dn ₅ with the external optical inner coating which is lower, in absolute value, than the difference of index Dn ₃ of the first internal coating re5 lowered with the external optical coating;

- optical fiber having a wavelength of 1625 nm, curvature losses less than or equal to 0.1 dB / 10 turns for a curvature radius of 15 mm and curvature losses less than or equal to 0.5 dB / back to a radius of curvature of 7.5 mm.

According to the modalities, the fiber of the present invention can comprise one or more of the following characteristics;

- an index difference between the second recessed inner cladding and the external optical cladding is between -0.3.10 ' ³ and -3.10'³;

- an index difference between the central core and the first internal intermediate coat is between 4.5.10 ' ³ and 6.0.10'³;

- the central core has a radius between 3.5 pm and 4.5 pm for an index difference with the inner layer lowered and the outer optical coating is between -5.0.10 ' ³ and 5.6.10'³;

- the first internal intermediate coating has a radius between 20 9 pme12pm;

- the first recessed inner lining has a radius between 14 pm and 16 pm;

- the second internal intermediate coating having a substantially zero index difference with the external optical coating;

- the second internal intermediate coating has a radius between pm and 20 pm;

- the second lowered inner lining has a radius between 25 pm and 40 pm;

- curvature losses less than or equal to 0.1 dB / 100 turns 30 for a radius of curvature of 20 mm, at a wavelength of 1625 nm;

- curvature losses less than or equal to 1 dB / turn for a 5 mm curvature mouse, at a wavelength of 1625 nm;

···· ** ··· ·· * ··· «« a * ·· * · «··· * a • ·· · · - · (.

·· ·· «·· * ··· • •« ••••••• a · «·· * a * ·« ··· a * aaa ·

- - microcurvature losses, according to the so-called fixed diameter drum method (touret à diamètre fixe in French) less than or equal to 0.8 dB / Km up to a wavelength of 1625 nm;

- a cable cut-off wavelength less than or equal to 1260 nm;

- a modal field diameter between 8.6 pm and 9.5 pm for a wavelength of 1310 nm;

- a ratio (of MAC value) of the modal field diameter of the fiber at 1550 nm to the effective cutting wavelength l _Ce ff less than

8.2;

- a zero chromatic dispersion wavelength (λ ₀ between 1300 nm and 1324 nm) with a chromatic dispersion slope less than or equal to 0.092 ps / nm ² / km at this wavelength.

The present invention also relates to an optical module including a housing in which at least a portion of fiber according to the present invention is wound; as well as to a storage box in which at least a portion of fiber according to the present invention is wound.

According to some modalities, the fiber is wound with a radius of curvature less than 15 mm, and / or with a radius of curvature less than 7.5 mm.

The present invention also relates to a Fiber to the Home (FTTH) or Fiber to the Sidewalk (FTTC) optical system comprising at least one optical module or a storage box according to the present invention.

Other aspects and advantages of the present invention will become apparent after reading the following description, of modalities of the present invention, given by way of example and with reference to the attached drawings, in which:

Figure 1, described earlier, shows a graph illustrating the loss of curvature at the wavelength of 1625 nm with a radius of curvature of 15 mm in a standard step index fiber versus the

MAC value at the wavelength of 1550 nm;

Figure 2 shows a graphical illustration of the defined profile of a step index fiber according to an embodiment of the present invention;

Figure 3 shows graphs illustrating the curvature losses at the wavelength of 1625 nm versus the radius of curvature for a step index SSMF fiber, for another prior art fiber and for a fiber according to the present invention.

The fiber of the present invention has a central core, a first inner intermediate coating and a first recessed inner coating. The fiber also has a second internal intermediate coating and a second recessed internal coating. By lowered inner lining is meant that a radial portion of the fiber has a lower refractive index than the outer lining index. The first rebated inner coating has a strong index difference with the external optical coating, being less than -5.10 ' ³ and which can reach -15.10' ³ . The second recessed lining has a smaller index difference with the outer lining than the first recessed lining, which is preferably between-0.3.10 ' ³ and-3.10' ³ .

Figure 2 illustrates an index profile for a transmission fiber according to the present invention. The illustrated profile is a defined profile, that is, a representative of the theoretical profile of the fiber, the fiber in question obtained after stretching a preform fiber may have a substantially different profile.

The step index transmission fiber according to the present invention comprises a central core having a difference of index Dn _1y with an outer coating, acting as an optical coating; a first internal intermediate coating having a difference of index Dn ₂ , with the external coating; a first in30 lower optical layer having a difference of index Dn ₃ , with the outer coating; a second internal intermediate coating having a difference of index Dn _4l with the external optical coating and a second lowered internal coating having a difference of index Dns, with the external coating. The D ₆ index difference is an absolute value less than the Dn3 index difference. The refractive indices in the central core, in the first and second recessed internal stainless steel linings and in the first and second of the intermediate internal stainless steel linings, are substantially constant throughout their width. The defined profile is a step index fiber. The width of the core is defined by its radius η and the width of the stainless steel linings is defined by their respective external radii r ₂ -r ₅ .

In order to define a defined index profile for an optical fiber, the index value of the outer coating is generally taken as a reference. Figure 2 shows only a small part of the outer optical coating and is intended to be a schematic illustration of the index differences in the core. The external optical coating of a substantially constant index stretches out to the external side of the optical fiber, that is, there is no other optical coating having different refractive indexes outside the external optical coating. The index values for the central core, for the lowered internal stainless steel linings and for the intermediate stainless steel linings are shown below as the Dni index differences, 2,3.4,5 · In general, the external optical coating it consists of silica, but this coating can be used to increase or reduce its refractive index, for example, in order to change the propagation characteristics of the signal.

The table below offers the preferred limit values for the radii and the index differences that allow a fiber profile to be obtained so that the fiber presents reduced curvature losses, while meeting the optical propagation criteria of the G.652 standard for transmission fibers. The values in the table correspond to the defined fiber profiles.

ΙΊ (μπί) Γ ₂ (μπί) Γ3 (μΓΠ) Γ4 (μπί) Γ5 (pm) Dni (.10- ³⁾ Dn Dn _{r ^{2 (.10- 3)}} Dn ^{_{3 (.10- 3)}} Dn ^{_{5 (.10- 3)}} min 35 9.0 14.0 18.0 25.0 5.0 4.5 -5 -0.3 Max 4.5 12.0 16.0 20.0 40.0 5.6 6.0 -15 -3

·· »t · ·· · ♦

The presence of the second recessed inner lining (rs, Dns) which is less recessed than the first recessed inner lining provides a limitation of the presence of leakage modes capable of propagating along the fiber and inducing an increase in the length of on5 effective cut. Due to the presence of the first internal intermediate coating (r2, Dn2), it becomes possible to guarantee the proper confinement of the signal in a single mode in the central core in order to limit a modal field diameter compatible with the G.652 standard. Due to the presence of the first deeply recessed inner lining (r ₃ , Dn ₃ ), the curve loss10 can be further reduced.

The transmission fiber according to the present invention having an index profile such as that described above has reduced losses of curvature in the use wavelengths. In particular, the fiber according to the present invention has, for a wavelength of 1625 nm, losses of curvature less than or equal to 0.1 dB for a winding of 100 turns around a coil with a radius of curvature 20 mm; curvature losses less than or equal to 0.1 dB for a 10-turn winding around a coil with a 15 mm radius of curvature; curvature losses less than or equal to 0.2 dB for a winding of 1 vol20 ta around a coil with a radius of curvature of 10 mm; curvature losses less than or equal to 0.5 dB for a 1 turn winding around a coil with a 7.5 mm radius of curvature; curvature losses less than or equal to 1 dB for a 1 turn winding around a coil with a 5 mm radius of curvature. The fiber according to the present invention has even lower curvature losses at the wavelength of 1550 nm. In particular, the fiber according to the present invention has, for a wavelength of 1550 nm, curvature losses less than or equal to 0.02 dB for a 10-turn winding around a coil with a radius of curvature of 15 mm; curvature losses less than or equal to 0.05 dB for a 1 turn winding around a coil with a 10 mm radius of curvature; curvature losses less than or equal to 0.2 dB for a 1 turn winding

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• * · * · · 1 around a coil with a radius of curvature of 7.5 mm.

In addition, the fiber according to the present invention also has reduced microcurvature losses compared to an SSMF fiber. Microcurvature losses can be estimated with a test, a so-called grid test (10 needles of 1.5 mm) at a wavelength of 1550 nm. In this test, a grid formed with 10 polished needles with a diameter of 1.5 mm is used, spaced 1 cm apart. The fiber passes through the grid through two passes, in an orthogonal direction to the geometric axis of the needles. The fiber and the grid are pressed between two rigid sheets covered with a layer of about 3 mm of high density polyethylene foam. The assembly layers (plates, grids, fiber) are positioned horizontally and the whole is covered with a weight of 250 g. With this test, the fiber according to the present invention has microcurvature losses less than or equal to 0.025 dB at 1550 nm. Microcurvature losses can also be estimated by the so-called fixed diameter drum method at a wavelength of 1625 nm. This method is described in the technical recommendation of the International Electrotechnical Commission of sub-committee 86A under reference IEC TR-62221. The diameter of the drum used is 60 cm, the drum is covered with extra fine sand paper. With this method, the fiber according to the present invention has microcurvature losses less than or equal to 0.6 dB / km at 1625 nm.

In addition, the fiber of the present invention meets the criteria of the G.652 standard.

In particular, it has an effective Iceff shear wavelength less than 1330 nm so that the L _C c cable shear wavelength is less than 1260 nm, according to the G.652 standard. The fiber according to the present invention also has an MFD diameter for a wavelength of 1310 nm, between 8.6 pm and 9.5 pm.

The fiber of the present invention can still have a MAC ratio ranging up to 8.2; the yield for making the fiber according to the present invention is therefore better, since there is no obligation to select fibers exclusively with a lower MAC value

that 7.9.

The graph in figure 3 illustrates the curvature losses at 1625 nm versus the radius of curvature for an SMMF fiber, for an identical fiber according to the present invention, but without the second recessed section and for two fibers according to the present invention . , _Λ

A first curve (3A) shows the loss of curvature of a single step index SSMF fiber. This fiber has a MAC value of 8.1. Note that for small radii of curvature smaller than 7.5 mm, the curvature losses increase considerably and the excess of 1 DB for a 1-turn winding. This conventional fiber, generally used for long-distance transmissions, is therefore not very suitable for an FTTH or FTTC fiber application, as it does not need to be wrapped in a miniature box of an optical module, nor submitted. possible accidental curvatures related to the installation without inducing strong optical losses.

A second curve (3B) shows the loss of curvature of a fiber similar to the present invention but without any second recessed section. This fiber has a MAC value of 8.2 and meets the criteria of the G.652 standard. Note that for small radii of curvature, less than 7.5 mm, curvature losses are less than 1 dB / turn. On the other hand, curvature losses remain relatively significant for larger radii of curvature. Therefore, the fiber has curvature losses of the order of 0.5 dB for a 10-turn winding around a coil with a radius equal to 20 mm and of the order 04 dB for a 100-turn winding around a coil with a radius equal to 20 mm. These values of curvature loss for the 15 mm and 20 mm radii of curvature do not allow this fiber to be used in storage boxes with these winding radii.

A third curve (3C) shows the loss of curvature of a fiber according to the present invention. The fiber corresponding to this curve has a MAC value of 8.2 and meets the criteria of the G.652 standard. It is noted that for small radii of curvature, less than 7.5 mm, the losses of curvature are in the order of 0.4 dB / turn, less than the preferred maximum vector of 0.5 dB / turn; and for a radius of curvature of 10 mm, the fiber according to the present invention has losses of curvature of the order of 0.2 dB / revolution, that is, the target upper limiting value. Also, for larger radii of curvature, curvature losses remain limited; therefore, for a radius of curvature of 15 mm, the fiber according to the present invention has curvature losses of the order of 0.04 dB / 10 turns, less than the maximum preferred value of 0.1 dB / 10 turns; and for a radius of curvature of 20 mm, the fiber according to the present invention has curvature losses of the order of 0.03 dB / 100 turns, less than the maximum preferred value of 0.1 dB / 100 turns.

A fourth curve (3D) shows the loss of curvature of another fiber according to the present invention. The fiber corresponding to this curve has a MAC value of 8.1 and meets the criteria of the G.652 standard.

Note that for small radii of curvature, less than 7.5 mm, the curvature losses are in the order of 0.1 dB / revolution, less than the maximum preferred value of 0.5 dB / revolution; and for a radius of curvature of 10 mm, the fiber according to the present invention has losses of curvature of the order of 0.07 dB / revolution, less than the maximum preferred value of 0.2 dB / revolution. Also, for larger radii of curvature, curvature losses remain limited; therefore, for a radius of curvature of 15 mm, the fiber according to the present invention has curvature losses of the order of 0.04 dB / 10 turns, less than the preferred maximum value of 0.1 dB / 10 turns; and for a radius of curvature of 20 mm, the fiber according to the present invention has losses of curvature of the order of 0.01 dB / 100 turns, less than the maximum preferred value of 0.01 dB / 100 turns.

The transmission fiber according to the present invention can be made by dragging the fiber in a preform looking for an index profile as described above. In a known way, a fiber by itself is produced by stretching the preform in a fiber stretching tower. A preform, for example, comprises a preform consisting of a very high quality glass tube, constituting a portion of the coating / V · * · · · · · · · «« * ·· * »• · · · · · · · «* * · ··· ··» ·· * ·· · φ · <> · ment (shell) and fiber core. This primary preform is then refilled or gloved in order to increase its diameter and form a preform that can be used in a fiber tow tower. The scaled fiber drag operation consists of placing the preform vertically on a tower and dragging a fiber wire from the end of the preform. For this, a high temperature is applied locally at one end of the preform until the silica softens, the fiber drag ratio and the temperature are then permanently monitored during the fiber drag, as they determine the diameter of the fiber. fiber. The geometry of the preform must perfectly observe the reasons of the refractive indices and the diameters of the coating and the fiber core so that the stretched fiber has the required profile.

Component deposition in the tube is generally referred to as doping, that is, impurities ”are added to the silica in order to change its refractive index. Thus, germanium (Ge) or phosphorus (P) increase the refractive index of silica; they are often used for doping the central core of the fiber. In addition, fluorine (F) or boron (B) decreases the refractive index of silica, fluorine being frequently used to form lowered coatings (shells).

The production of a preform with a highly lowered coating is a delicate operation. Indeed, fluorine is poorly incorporated into the heated silica beyond a certain temperature, while a high temperature is required for glass production.

Through the compromise between a high temperature required for the production of glass, and a low temperature that promotes the appropriate incorporation of fluorine, it is not possible to obtain much lower rates than those of silica.

It is preferred that the fiber preform according to the present invention is made according to a plasma chemical vapor deposition (PCVD) technique, since the reactions can be conducted at lower temperatures than in conventional techniques ( CVD, VAD, OVD) by ionizing the reaction compounds. Such a manufacturing technique is

»· * * * ·« »· * ·« Fr ** ♦ * · »·» · φ · • · · · · * · ♦ · · * * »*» · »· *** · * «» · · Described in US RE 30 635 and US 4 314 833, and allows fluorine to be significantly incorporated into silica to form highly lowered stainless steel coatings. However, the fiber preform according to the present invention can also be made with CVD, VAD, or OVD techniques. /

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A tube of silica, pure or slightly doped with fluorine, and provided and mounted on a glass latch. A glass mixture of glass-forming precursors on which it may or may not be doped is injected into the tube. Microwave-generated plasma passes along the tube. In plasma, precursors of glass formation are reacted in the glass that is deposited on the inner surface of the tube.

The high reactivity of dopants, generated by microwave heating, allows a high concentration of dopants to be incorporated into the silica layers. In particular, in the case of fluorine, which is little incorporated in the silica with local heating by means of a blow torch, with PCVD, a layer of silica can be doped with a high concentration of fluorine in order to produce the first highly lowered coating. (r ₃ , Dn3>. The second slightly lowered coating (r _5l Dn ₅ ) can also be obtained through a deposition of the PCVD type as the first highly lowered internal coating, or can be obtained with the silica tube in question , slightly doped with fluorine, or can still be done during the glove or refilling of the preform, for example, by using a lightly fluorinated intermediate glove tube or by producing a refill portion with lightly fluorinated silica grains .

The transmission fiber according to the present invention can be used in a transmission or receiving module in an FTTH or FTTC fiber system or in a high proportion, long distance optical transmission cable with reduced optical losses. The fiber of the present invention is compatible with commercial systems, since it complies with the G.652 standard. In particular, the excess lengths of the fiber according to the present invention can be rolled up in storage boxes associated with the optical modules of FTTH fiber systems or • t · * <· * «·« · · · »» * * * *> · »· · ··« «« • · «« «<· 1« «« · ··· ·· · · »··· ·« * »« «

FTTC, the fiber according to the present invention can be wound with a radius of curvature less than 15 mm, or even less than 7.5 mm without inducing strong optical losses. The fiber according to the present invention is also very suitable to withstand accidental curvatures related to its installation in a person's residence, with radii of curvature of a range less than 5 mm.

Of course, the present invention is not limited to the described modalities and uses described by way of example. In particular, the fiber according to the present invention can also be used in applications other than FTTH or FTTC fibers.

Claims (15)

1. FIBER OF OPTICAL TRANSMISSION, characterized by comprising: - a central core having a difference of index Dn with an external optical coating, in which the central core has a radius r1 comprised 5 between 3.5 pm and 4.5 pm for an index difference with the outer optical coating Dn between 5,0x10 ^-3 and 5,6x10 ^-3; - a first intermediate coating having a difference of Dn2 index with the external optical coating, in which the first intermediate coating has a radius r2 between 9 pm and 12 pm; 10 - a first recessed coating having an index difference Dn3 with the external optical coating that is between -5.10 ^-3 and -95x10 ^-3 , where the first recessed coating has a radius r3, between 14 pm and 16 pm; - a second intermediate coating having a difference of Dn4 index with the external optical coating; 15 - a second recessed coating having an index difference Dn5 with the external optical coating which is, in absolute value, lower than the difference in index Dn3 of the first recessed coating with the external optical coating, and where the difference in index Dn5 between the second recessed coating and the external optical coating is comprised between -0.3x10 ^-3 and -3x10 ^-3 and where the The second recessed coating has a radius r5 between 25 pm and 40 pm; and - wherein the index difference between the central core and the first intermediate coating (Dn-ι - DN2) is between 4.5x10 ^-3 and ³ 6.0X10-; - optical fiber having a shorter cable cut-off wavelength 25 or equal to 1260 nm and having, at a wavelength of 1625 nm, curvature losses less than or equal to 0.1 dB / 10 turns for a curvature radius of 15 mm and curvature losses less than or equal to 0.5 dB / turn for a 7.5 mm bend radius. 2. FIBRA, according to claim 1, characterized by the second 30 intermediate coating having an index difference approximately zero Dn4 with the external optical coating. 3. FIBRA, according to claim 1 or 2, characterized by Petition 870180004344, of 01/17/2018, p. 6/12 second intermediate coating having a radius r4 between 18 pm and 20 pm, FIBER according to any one of claims 1 to 3, characterized by having a wavelength of 1625 nm, loss of curvature 5 less than or equal to 0.1 dB / 100 turns for a radius of curvature of 20 mm. FIBER according to any one of claims 1 to 4, characterized in that it has a wavelength of 1625 nm, curvature losses less than or equal to 0.2 dB / revolution for a radius of curvature of 10 mm. FIBER according to any one of claims 1 to 5, 10 characterized in that it has a wavelength of 1625 nm, curvature losses less than or equal to 1 dB / turn for a radius of curvature of 5 mm. FIBER according to any one of claims 1 to 6, characterized in that it has a wavelength of up to 1625 nm, losses of microcurvature according to the drum method of fixed diameter less than or equal 15 to 0.8 db / km. FIBER according to any one of claims 1 to 7, characterized in that it has a wavelength of 1310 nm, a modal field diameter (MFD) comprised between 8.6 pm and 9.5 pm. FIBER according to any one of claims 1 to 8, 20 characterized by having a ratio (MAC) of the modal field diameter at 1550 nm by the effective cutting wavelength Àeff below 8.2. 10. FIBER according to any one of claims 1 to 9, characterized in that it has a zero chromatic dispersion wavelength (À0) between 1300 nm and 1324 nm with a chromatic dispersion inclination. 25 less than or equal to 0.092 ps / nm ² / km at said wavelength. 11. OPTICAL MODULE, characterized in that it comprises a housing that receives at least a rolled portion of the fiber as defined in any one of claims 1 to 10. 12. STORAGE BOX, characterized by receiving at least a rolled portion of the fiber as defined in any one of claims 1 to 10. 13. OPTICAL MODULE OR STORAGE BOX, as required Petition 870180004344, of 01/17/2018, p. 7/12 defined in claim 11 or 12, characterized in that the fiber is wound with a radius of curvature of less than 15 mm. 14. OPTICAL MODULE OR STORAGE BOX, as defined in 11 or 12, characterized by the fiber being wound with a radius of curvature 5 less than 7.5 mm. 15. FIBER TO HOUSE (FTTH) OR FIBER TO SHOE (FTTC) OPTICAL SYSTEM, characterized in that it comprises at least one optical module or a storage box as defined in any of claims 11 to 14. Petition 870180004344, of 01/17/2018, p. 12/8 1/2 FIG 1 Loss of curvature (R «1Smm; @ 162Snm) [dB / 1 turn (s)] MAC @ l550nm FIG 2 2/2 ··· ··· ·· »··· ·· · ·· FIG 3 Loss of curvature rushed in dB / 1 vo