OPTICAL FIBER

Abstract

An optical fiber of the invention satisfies Δcore>Δic>Δtmax>Δtmin, −0.15%≧Δtmax>Δtmin≧−0.7%, and 0.45≦(rtmax−rin)/(rout−rin)≦0.9 where the relative refractive index difference of the core is Δcore, the relative refractive index difference of the internal cladding coat is Δic, the relative refractive index difference of a highest refractive index layer in the trench coating is Δtmax, the relative refractive index difference of a lowest refractive index layer in the trench coating is Δtmin, the radius of an internal edge of the trench coating is rin, the radius of an external edge of the trench coating is rout, and the radius of an internal edge of a highest refractive index layer in the trench coating is rtmax and where the relative refractive index differences are based on a refractive index of the outermost cladding coat.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an optical fiber having the low-bending loss equal to that of a conventional trench structure at low cost.

2. Description of the Related Art

FTTH (Fiber To The Home) is in widespread use, accordingly, optical fibers have been installed indoors such as in buildings, households, and the like, and an optical fiber having reduced bending loss has been attracting attention.

By use of a bending loss insensitive fiber, the effect of preventing signals from being instantaneously interrupted due to loss generated by bending optical fibers, or the effect of reducing the laying cost due to easy handling of the optical fibers is expected.

There is a trade-off relationship between a mode field diameter (MFD) and bending loss in an optical fiber having a simple core-cladding structure which is used for a conventional single-mode optical fiber (S-SMF), it is possible to reduce the bending loss by reducing the MFD.

However, there is a problem in that the reduction of the MFD causes an increase in connection loss of S-SMF thereto or deviates from the range of the MFD determined by the international recommendation ITU-T G.652 related to a single-mode optical fiber (SMF) (the design criterion value at a wavelength of 1310 nm is a MFD of 8.6 to 9.5 μm), and there is a limitation in reducing the bending loss due to the reduction of the MFD.

As a technique of reducing the bending loss without reducing the MFD, a refractive index profile which is referred to as trench type is known (refer to Japanese Unexamined Patent Application, First Publication No. S63-43107).

Additionally, as a bending loss insensitive fiber, a number of methods using the trench-type refractive index profile has been proposed.

For example, PCT International Publication No. WO 2004/092794 discloses that the trench-type refractive index profile is not applied to a dispersion shifted optical fiber (DSF) disclosed in Japanese Unexamined Patent Application, First Publication No. S63-43107 but applied to a conventional SMF.

PCT International Publication No. WO 2006/025231 discloses a structure reducing the MFD and reducing the bending loss in addition to making the wavelength dispersion characteristics thereof to be the region similar to a normal SMF.

Published Japanese Translation No. 2010-503018 of PCT International Publication discloses a structure improving the reduction of the bending loss by making the relative refractive index difference of the trench region to be an extremely low value such as −0.63% or less.

Published Japanese Translation No. 2010-503019 of PCT International Publication discloses an optical fiber having a fiber cut-off wavelength less than 1260 nm and a zero-dispersion wavelength which is in the range of 1300 to 1324 nm and having reduced bending loss in the diameter of 10 mm.

As for shortening a manufacturing time of a trench optical fiber and designing for reducing the cost, a method of reducing a distance between a core and a trench is disclosed in Japanese Unexamined Patent Application, First Publication No. 2009-8850.

Japanese Unexamined Patent Application, First Publication No. 2007-279739 discloses a method of realizing both bending loss and single-mode transmission by providing an intermediate cladding coat and a low-refractive index layer outside of a trench coating.

Furthermore, a method is known which obtains the same effect as that of the trench-type by use of a constitution having air space at a part of a cladding coat (for example, refer to PCT International Publication No. WO 2004/092793 and Published Japanese Translation No. 2009-543126 of PCT International Publication).

In addition, as alternative approaches, a method is disclosed which releases the limitation of a cut-off wavelength by making the loss of a higher order mode increase, and obtaining a bending loss insensitive fiber (for example, refer to Japanese Unexamined Patent Application, First Publication No. 2008-310328).

Moreover, Louis-Anne de Montmorillon, et al, “Recent Developments of Bend-insensitive and Ultra-bend-insensitive Fibers Fully Compliant with Both G.657.B and G.652.D ITU-T Recommendations”, Proceedings of the 58th IWCS/IICIT, International Wire & Cable Symposium, 2009, pp. 270-276 discloses an example related to behavior of a higher order mode in a trench optical fiber.

However, connection is an issue in a structure having a hole such as a hole-assisted fiber (HAF), Clear Curve (registered trademark), or the like, as compared with an optical fiber having a solid glass structure which does not have a hole such as a trench optical fiber.

For example, since accurate core alignment is required for a fusion splice, many fusion splicers use a direct core observation method which detects and aligns a core by analyzing an observed image of a side face of an optical fiber.

However, in a case where a hole is present in a cladding, since it is impossible to detect the position of the core by use of the image of the side face, an outer diameter alignment method with reference to the cladding diameter should be used.

Since the outer diameter alignment method is influenced by eccentricity of the core with respect to the circumscribed circle of the cladding, there is a problem in that connection loss easily increases as compared with a direct core observation method.

Additionally, the structure of the optical fiber disclosed in Japanese Unexamined Patent Application, First Publication No. 2008-310328 is extremely complicated, and an advanced manufacturing technique is necessary; furthermore, since a layer having a low refractive index is provided at the region which is wider than that of a trench structure, a large amount in dopants making a refractive index low is necessary, and there is a problem in terms of the cost of manufacturing.

Even in a case of the conventional trench structure, when the relative refractive index difference of the trench is set low such as to be approximately −0.7% or −0.5%, as exemplified in Published Japanese Translation No. 2010-503018 of PCT International Publication and Published Japanese Translation No. 2010-503019 of PCT International Publication, a large amount in dopants for forming a trench is necessary, and there is problem of an increase in the cost of manufacturing.

Although the optical fiber having a trench structure can be manufactured by a variety of manufacturing methods, suppression of the material cost for forming a trench coating is an issue depending on manufacturing methods.

FIG. 3 shows an example of the relationship between a partial pressure of silicon tetrafluoride (SiF₄) in the case of forming a trench coating by use of a MVCD method, and the relative refractive index difference of the resultant fluorine-doped silica glass.

The relative refractive index difference of the resultant glass shows that it is proportional to approximately fourth root of a partial pressure of SiF₄.

Consequently, in a structure which requires relative refractive index difference Δ such as less than −0.5%, the used amount of a source material gas of SiF₄ dramatically increases.

For example, in order to obtain the relative refractive index difference Δ of 0.5%, it is necessary to set approximately 20 times partial pressure of SiF₄ which is in the case of obtaining the relative refractive index difference Δ of −0.2%.

In Japanese Unexamined Patent Application, First Publication No. 2009-8850, a low-refractive index layer is designed so as to be close to a core in order to reduce the cost of materials; however, since a trench having a great negative relative refractive index difference should be provided in order to reduce bending loss, the effect for reducing the cost is limited.

Moreover, when the trench and the core are extremely close to each other, since optical characteristics such as chromatic dispersion or the like are separated from the international recommendation, there is a limitation to make the low-refractive index layer approach the core.

In contrast, there is a problem in that the loss of an optical fiber having a trench structure under a higher order mode is smaller than that of a conventional SMF.

The tendency shown as described above appears as difference in length dependence of a cut-off wavelength.

For example, Louis-Anne de Montmorillon, et al, “Recent Developments of Bend-insensitive and Ultra-bend-insensitive Fibers Fully Compliant with Both G.657.B and G.652.D ITU-T Recommendations”, Proceedings of the 58th IWCS/IICIT, International Wire & Cable Symposium, 2009, pp. 270-276 discloses the behavior of a trench optical fiber under a higher order mode, wavelength-dependence in LP11 Leakage Loss is shown in FIG. 2 thereof.

When wavelengths are compared to each other on the line of 1 dB/m corresponding to the cable cut-off wavelength λ_c22m of 22 m, the wavelengths of three optical fibers are distributed in the range of 1225 to 1260 nm, the optical fibers satisfying the cable cut-off wavelength less than 1260 nm defined by ITU-T or the like.

When losses are compared to each other in a wavelength of 1310 nm used for communication, the losses in optical fibers are approximately 2 to 12 dB/m.

Because of this, in the case of using an optical fiber having a short length such as several meters, the higher order mode does not sufficiently attenuate, and there is a possibility that communication is interrupted.

The foregoing behaviors are easily compared to each other when the difference between the cable cut-off wavelength λ_c22m of 22 m and the fiber cut-off wavelength λ_c2m of 2 m is represented as an indicator.

In the case of three optical fibers disclosed in Louis-Anne de Montmorillon, et al, “Recent Developments of Bend-insensitive and Ultra-bend-insensitive Fibers Fully Compliant with Both G.657.B and G.652.D ITU-T Recommendations”, Proceedings of the 58th IWCS/IICIT, International Wire & Cable Symposium, 2009, pp. 270-276, the difference is 63 to 146 nm.

In the case of designing a trench optical fiber so as to improve bending loss when a diameter is small such as a bending radius of 5 mm, the difference λ_c2m−λ_c22m has a tendency to be long.

For this reason, a desired structure has the equivalent bending property, and the difference in the cut-off thereof becomes low.

SUMMARY OF THE INVENTION

The invention was conceived in view of the above-described circumstances and has an object thereof to provide a bending loss insensitive which can be manufactured at a low cost.

In order to solve the above-described problem, an optical fiber of an aspect of the invention includes: a core provided at a central portion; an internal cladding coat provided around the core, having a refractive index less than a refractive index of the core; a trench coating provided at a periphery of the internal cladding coat and constituted of two or more layers having different refractive indices; and an outermost cladding coat provided at a periphery of the trench coating.

A layer having the highest refractive index in the trench coating configures an outermost layer of the trench coating.

The relationships of Δ_core>Δ_ic>Δ_tmax>Δ_tmin, −0.15%≧Δ_tmax>Δ_tmin≧−0.7%, and 0.45≦(r_tmax−r_in)/(r_out−r_in)≦0.9 are satisfied where a relative refractive index difference of the core is represented as Δ_core, a relative refractive index difference of the internal cladding coat is represented as Δ_ic, a relative refractive index difference of a layer having the highest refractive index in the trench coating is represented as Δ_tmax, a relative refractive index difference of a layer having the lowest refractive index in the trench coating is represented as Δ_tmin, a radius of an internal edge of the trench coating is represented as r_in, a radius of an external edge of the trench coating is represented as r_out, and a radius of an internal edge of a layer having the highest refractive index in the trench coating is represented as r_tmax and where the relative refractive index differences are based on a refractive index of the outermost cladding coat.

In the optical fiber of the aspect of the invention, it is preferable that relationships −0.40%≧Δ_tmin≧−0.50% and −0.15%≧Δ_tmax≧−0.25% be satisfied in the trench coating.

In the optical fiber of the aspect of the invention, it is preferable that relationship 0.7≦(r_tmax−r_in)/(r_out−r_in)≦0.9 be satisfied in the trench coating.

In the optical fiber of the aspect of the invention, it is preferable that relationship 0.7≦(r_tmax−r_in)/(r_out−r_in)≦0.8 be satisfied in the trench coating.

In the optical fiber of the aspect of the invention, it is preferable that the layer having the lowest refractive index in the trench coating configure an innermost layer of the trench coating.

In the case where the trench coating is constituted of two layers having different refractive indexes, a low-refractive-index layer is disposed inside the trench coating and a high-refractive-index layer is disposed outside the trench coating.

In the case where the trench coating is constituted of three layers having different refractive indexes, a structure can be adopted in which a layer having the lowest refractive index in the trench coating is located at the innermost layer of the trench coating (the layer is close to the internal cladding coat).

In the optical fiber of the aspect of the invention, it is preferable that the outermost cladding coat be formed of pure silica glass and the trench coating be formed of silica glass into which fluorine is introduced.

EFFECTS OF THE INVENTION

According to the invention, since the aforementioned requisite is satisfied, it is possible to obtain an optical fiber having a low-bending loss equal to that of a conventional trench structure at a low cost.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a view schematically showing a refractive index profile of an optical fiber related to a first embodiment.

FIG. 2 is a view schematically showing a refractive index profile of an optical fiber related to a second embodiment.

FIG. 3 is a graph illustrating an example of the relationship between the partial pressure of SiF₄ and the relative refractive index difference of the resultant glass in the case of forming a trench coating by use of a modified chemical vapor deposition method.

FIG. 4 is a graph illustrating an example of change in the relative used amount of SiF₄ with respect to (r_tmax−r_in)/(r_out−r_in).

FIG. 5 is a graph illustrating an example of change in cut-off wavelength difference between 2 m and 22 m with respect to (r_tmax−r_in)/(r_out−r_in).

FIG. 6 is a view showing an example of a refractive index profile of a conventional trench optical fiber.

FIG. 7 is a graph on which bending losses in a wavelength of 1550 nm with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 1.

FIG. 8 is a graph on which bending losses in a wavelength of 1625 nm with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 1.

FIG. 9 is a graph on which λ_c2m−λ_c22m with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 1.

FIG. 10 is a graph on which the relative used amount of SiF₄ with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 1.

FIG. 11 is a graph on which bending losses in a wavelength of 1550 nm with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 2.

FIG. 12 is a graph on which bending losses in a wavelength of 1625 nm with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 2.

FIG. 13 is a graph on which λ_c2m−λ_c22m with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 2.

FIG. 14 is a graph on which the relative used amount of SiF₄ with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 2.

FIG. 15 is a graph on which bending losses in a wavelength of 1550 nm with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 3.

FIG. 16 is a graph on which bending losses in a wavelength of 1625 nm with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 3.

FIG. 17 is a graph on which λ_c2m−λ_c22m with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 3.

FIG. 18 is a graph on which the relative used amount of SiF₄ with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 3.

FIG. 19 is a graph on which bending losses in a wavelength of 1550 nm with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 4.

FIG. 20 is a graph on which bending losses in a wavelength of 1625 nm with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 4.

FIG. 21 is a graph on which λ_c2m−λ_c22m with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 4.

FIG. 22 is a graph on which the relative used amount of SiF₄ with respect to (r_tmax−r_in)/(r_out−r_in) are plotted in Example 4.

DETAILED DESCRIPTION OF THE INVENTION

Hereinafter, the invention will be described based on a preferred embodiment with reference to drawings.

FIG. 1 schematically shows a refractive index profile of an optical fiber related to a first embodiment of the invention.

The optical fiber F1 is provided with a core 11, an internal cladding coat 12, a trench coating 13, and an outermost cladding coat 14.

The core 11 is located at a central portion of the optical fiber F1.

The internal cladding coat 12 is located at the periphery of the core 11 and has a refractive index less than that of the core 11.

The trench coating 13 is located at the periphery of the internal cladding coat 12 and is constituted of two layers 15 and 16 (a first refractive index layer 15 and a second refractive index layer 16) having refractive indexes different from each other.

The outermost cladding coat 14 is located at the periphery of the trench coating 13.

Here, the first refractive index layer 15 (outermost layer) is a layer having the highest refractive index, and the second refractive index layer 16 is a layer having the lowest refractive index (innermost layer).

In addition, FIG. 2 schematically shows a refractive index profile of an optical fiber related to a second embodiment of the invention.

The optical fiber F2 is provided with a core 21, an internal cladding coat 22, a trench coating 23, and an outermost cladding coat 24.

The core 21 is located at a central portion of the optical fiber F2.

The internal cladding coat 22 is located at the periphery of the core 21 and has the refractive index less than that of the core 21.

The trench coating 23 is located at the periphery of the internal cladding coat 22 and is constituted of three layers 25, 26, and 27 (a first refractive index layer 25, a second refractive index layer 27, and a third refractive index layer 26) having refractive indexes different from each other.

The outermost cladding coat 24 is located at the periphery of the trench coating 23.

Here, the first refractive index layer 25 is a layer having the highest refractive index (outermost layer), and the second refractive index layer 27 is a layer having the lowest refractive index (innermost layer).

The optical fibers of the above-described first and second embodiments have a relationship of Δ_core>Δ_ic>Δ_tmax>Δ_tmin where the relative refractive indexes differences of the cores 11 and 21 are represented as Δ_core, the relative refractive index differences of the internal cladding coats 12 and 22 are represented as Δ_ic, the relative refractive index difference of the layer 15 having the highest refractive index in the trench coating 13 is represented as Δ_tmax, the relative refractive index difference of the layer 25 having the highest refractive index in the trench coating 23 is represented as Δ_tmax, the relative refractive index difference of the layer 16 having the lowest refractive index in the trench coating 13 is represented as Δ_tmin, and the relative refractive index difference of the layer 27 having the lowest refractive index in the trench coating 23 is represented as Δ_tmin, as the relative refractive index difference with reference to refractive indexes of the outermost cladding coats 14 and 24.

Here, Δ_core>Δ_ic means that the internal cladding coats 12 and 22 have a refractive index less than that of the cores 11 and 21; and Δ_ic>Δ_tmax means that each of the layers 15 and 16 included in the trench coating 13 has the refractive index less than that of the internal cladding coat 12 and each of the layers 25 to 27 included in the trench coating 23 has a refractive index less than that of the internal cladding coat 22.

Additionally, Δ_tmax>Δ_tmin means that the trench coatings 13 and 23 are formed of a plurality of layers having refractive indexes different from each other.

The refractive index of the trench coating 13 is less than the refractive index of the outermost cladding coat 14.

Furthermore, the refractive index of the trench coating 23 is less than the refractive index of the outermost cladding coat 24.

Consequently, Δ_tmax and Δ_tmin are negative values.

It is desirable that the range of the relative refractive index differences of the trench coatings 13 and 23 be appropriately determined in consideration of various factors in optical characteristics such as a confinement effect in a fundamental mode, the amount of dopant, or the like, or the cost of manufacturing or the like; for example, it is preferable that the relative refractive index difference be in the range of −0.15% to −1.0%.

Particularly, it is preferable that the relative refractive index difference satisfy −0.15%≧Δ_tmax>Δ_tmin≧−0.7%.

The range of the relative refractive index difference Δ_tmax is preferably −0.15%≧Δ_tmax>−0.7%, and −0.15%≧Δ_tmax≧−0.25% is more preferable.

The range of the relative refractive index difference Δ_tmax is preferably −0.15%>Δ_tmax≧−0.7%, and −0.3%≧Δ_tmin≧−0.7% is more preferable.

The range of the difference in Δ_tmax−Δ_tmin is preferably 0.55%≧Δ_tmax−Δ_min≧0.1%, and 0.35%≧Δ_tmax−Δ_tmin≧−0.15% is more preferable.

Furthermore, in the trench coating 13, the high-refractive-index layer 15 is provided at the outermost layer of the trench coating 13, and the layer 16 having a lower refractive index is provided inside the layer 15.

In the trench coating 23, the high-refractive-index layer 25 is provided at the outermost layer of the trench coating 3, and the layers 26 and 27 having lower refractive indexes are provided inside the layer 25.

Therefore, the difference in the refractive index with respect to the internal cladding coats 12 and 22 further increases, an electric field of a fundamental mode is confined by the trench coatings 13 and 23, and it is possible to realize reduction in bending loss.

Additionally, the amount of dopant such as fluorine F or the like, which makes a refractive index low, becomes greater in a low-refractive-index layer but becomes lower in a high-refractive-index layer.

Since the layers 15 and 25 having lowest amount of dopant is present as the outermost layer having the largest radius, the amount of dopant used for forming the trench coatings 13 and 23 is further reduced, and it is possible to reduce the cost of manufacturing.

In the case where the trench coating 23 is constituted of three layers or more such as the layers 25 to 27 as shown in FIG. 2, it is also possible to form the trench coating 23 so that the layer 27 having the lowest refractive index becomes the innermost layer of the trench coating 23.

As stated above, since the layer 27 having the greatest amount of dopant is present as the innermost layer the smallest radius, the amount of dopant used for forming the trench coating 23 is further reduced, and it is possible to enhance the effect of confining an electric field of a fundamental mode and reducing bending loss while reducing the cost of manufacturing.

It is preferable that the outermost cladding coats 14 and 24 be formed of pure silica glass and that the layers 15 and 16 constituting the trench coating 13 or the layers 25 to 27 constituting the trench coating 23 be formed of silica glass into which fluorine is introduced.

The cores 11 and 21 may be formed of silica glass, into which one, two, or more types of the dopant making a refractive index increase such as germanium Ge or the like is introduced.

The dopant, which increases the refractive index or reduces the refractive index, may be introduced into the internal cladding coats 12 and 22, or the internal cladding coats 12 and 22 may be formed of pure silica glass into which no dopant is introduced.

Each layer forming the refractive index profile may be formed by use of a publicly known method such as a modified chemical vapor deposition method, a plasma chemical vapor deposition method, a vapor-phase axial deposition method, or the like, or a method combining such methods.

For example, when the trench coating 13 is formed by a modified chemical vapor deposition method, a silica glass tube is used which corresponds to a portion adjacent to an external edge of the trench coating 13 in the outermost cladding coat 14.

Alternatively, when the trench coating 23 is formed by a modified chemical vapor deposition method, a silica glass tube is used which corresponds to a portion adjacent to an external edge of the trench coating 23 in the outermost cladding coat 24.

Furthermore, glass including a composition of the trench coatings 13 and 23 is deposited inside the glass tube by use of one, two, or more types of raw materials including Si and F.

At this time, by varying the used amount of the raw material including F, it is possible to form the trench coatings 13 and 23 which are constituted of two or more layers having different refractive indexes.

Furthermore, in the case of the modified chemical vapor deposition method, it is possible to form the internal cladding coat 12 and the core 11 inside the trench coating 13 in this order.

Alternatively, it is possible to form the internal cladding coat 22 and the core 21 inside the trench coating 23 in this order.

As a method for forming the cores 11 and 21, a separately-formed core serving as a core rod is inserted into the inside thereof, and the core may be integrated together with the above-described layer.

As a method for forming the outermost cladding coats 14 and 24, it is also possible to form the cladding coats 14 and 24 while depositing the cladding coat outside a starting glass tube by outside deposition so as to increase the external diameter until a necessary thickness thereof is obtained.

Since an optical fiber can be produced by fiber drawing of a optical fiber preform, the refractive index profile in the optical fiber preform has the profile which is enlarged similarly to the refractive index profile in the optical fiber.

It is preferable that the radius r_core and the relative refractive index difference Δ_core of the cores 11 and 21 be appropriately determined in consideration of the relationship between the radius r and the relative refractive index difference Δ_ic in the internal cladding coats 12 and 22 so that the MFD determined by the international recommendation becomes 8.6 to 9.5 μm or the approximate value thereof.

Where the radiuses of the internal edges of the trench coatings 13 and 23 are represented as r_in, the radiuses of the external edges of the trench coatings 13 and 23 are represented as r_out, and the radiuses of the internal edges of the layers 15 and 25 having the highest refractive index in the trench coatings 13 and 23 is represented as r_tmax, the ratio expressed by (r_tmax−r_in)/(r_out−r_in) is preferably in the range of 0.7 to 0.9.

In other cases, the case of (r_tmax−r_in)/(r_out−r_in)=1.0 means a conventional trench structure in which the relative refractive index difference Δ_t is Δ_tmin as shown in FIG. 6.

Moreover, the smaller the relative refractive index difference Δ, the more the used amount of SiF₄ of a raw material increases; therefore it is possible to effectively reduce the cost of raw materials by using a structure which makes the relative refractive index difference Δ_tmax of the trench-external layer high.

FIG. 4 shows an example of change in the used amount of SiF₄ in the case of r_in/r_core=2.25, r_out/r_core=3.9, Δ_ic=0.0%, Δ_tmin=−0.5%, Δ_tmax=−0.20% where the trench coating 13 is constituted of two layers as shown in FIG. 1.

The used amount of SiF₄ in this case is based on the amount of F which is introduced into glass and does not include influence of deposition efficiency.

Due to making (r_tmax−r_in)/(r_out−r_in) less than or equal to 0.9, it is possible to reduce the used amount of SiF₄ by approximately 10% as compared with a conventional trench structure.

Due to making (r_tmax−r_in)/(r_out−r_in) less than or equal to 0.8, it is possible to reduce the used amount of SiF₄ by approximately 20% or more as compared with a conventional trench structure.

Furthermore, in the case of (r_tmax−r_in)/(r_out−r_in)≦0.5, it is possible to reduce the used amount of SiF₄ by approximately 50% or more as compared with a conventional trench structure, and this is more preferable.

Additionally, in a process of continuously carrying out soot deposition and vitrification such as a modified chemical vapor deposition process as illustrated by using an example of the above-described FIG. 3, since the deposited glass is etched by the gas into which F of the raw material is introduced, there is a problem in that deposition efficiency decreases.

Consequently, the effect of decreasing the used amount of SiF₄ becomes greater than that of the calculated result as shown in FIG. 4.

In other cases, a source material gas used for F-doping into glass is not limited to SiF₄, in addition, a mixed gas can be used which includes one or more of CF4, SF6, F2, or the like, or such source material gases.

Such gases including F are all expensive, but, without depending on the types of the source material gas, it is possible to effectively reduce the cost of raw materials by using the structure which makes the relative refractive index difference Δ_tmax of the trench-external layer high.

Moreover, the optical fiber of the above-described embodiment has an advantage of promptly attenuating a higher order mode (particularly, even where the length thereof is short).

FIG. 5 illustrates dependency of cases of r_in/r_core=2.25, r_out/r_core=3.9, Δ_ic=0.0%, Δ_tmin−0.5%, Δ_tmax=−0.15%, −0.18%, or −0.20% with respect to (r_tmax−r_in)/(r_out−r_in) the cut-off wavelength difference λ_c2m−λ_c22m between 2 m and 22 m in the case where the trench coating 13 constituted of two layers as shown in FIG. 1.

In the case of (r_tmax−r_in)/(r_out−r_in)=1 in a conventional trench structure, the λ_c2m−λ_c22m becomes 148 nm.

Additionally, in the case of a conventional SMF having a simple core-cladding structure which does not have a trench structure, the λ_c2m−λ_c22m is approximately 50 nm.

In the disclosure of the above-described Louis-Anne de Montmorillon, et al, “Recent Developments of Bend-insensitive and Ultra-bend-insensitive Fibers Fully Compliant with Both G.657.B and G.652.D ITU-T Recommendations”, Proceedings of the 58th IWCS/IICIT, International Wire & Cable Symposium, 2009, pp. 270-276, there is no problem in practice even where λ_c2m−λ_c22m is approximately 150 nm, however, it is desirable that λ_c2m−λ_c22m be made as short as possible.

As evidenced by FIG. 5, it is possible to reduce λ_c2m−λ_c22m without deteriorating the bending loss of r=5 mm by suitably determining (r_tmax−r_in)/(r_out−r_in).

If (r_tmax−r_in)/(r_out−r_in) is less than or equal to 0.8, λ_c2m−λ_c22m can be shortened by approximately 10 nm, furthermore, if (r_tmax−r_in)/(r_out−r_in) is less than or equal to 0.5, λ_c2m−λ_c22m can be shortened by approximately 40 nm as compared with a conventional trench structure.

EXAMPLES

Hereinbelow, the invention will be particularly described with reference to Examples.

Comparative Example 1

Each Example described below shows an example of the optical fiber produced and provided with a conventional trench structure in order to compare Examples to each other.

FIG. 6 schematically shows a refractive index profile of an optical fiber having a conventional trench structure.

The optical fiber was provided with a core 1 disposed at a central portion; an internal cladding coat 2 disposed at the periphery of the core 1 and having a refractive index less than that of the core 1; a trench coating 3 disposed at the periphery of the internal cladding coat 2; and an outermost cladding coat 4 disposed at the periphery of the trench coating 13.

The relative refractive index difference of the core 1 is represented as Δ_core, the relative refractive index difference of the internal cladding coat 2 is represented as Δ_ic, the relative refractive index difference of the trench coating 3 is represented as Δ_t, the radius of the core 1 is represented as r_core, the radius of the internal edge of the trench coating 3 is represented as r_in, and the radius of the external edge of the trench coating 3 is represented as r_out where the relative refractive index differences are based on the refractive index of the outermost cladding coat 4.

Parameters and the values of Comparative Example 1 are shown in Table 1 and the characteristics thereof are shown in Table 2.

Additionally, each of the bending losses (dB/turn) in the bending radiuses in wavelengths of 1550 nm and 1625 nm is shown in Table 3.

TABLE 1
Comparative Example 1: Parameters
rin/rcore  2.50
rout/rcore 3.90
rout       14.9 μm
Δcore      0.330%
Δic        0.00%
Δt         −0.50%

TABLE 2
Comparative Example 1: Optical Characteristics
	Cable Cut-off wavelength of 2 m (λc2m)	1368	nm
	Cable Cut-off wavelength of 22 m (λc22m)	1220	nm
	λc2m − λc22m	148	nm
	MFD at 1310 nm	8.9	μm
	Zero-Dispersion Wavelength λ0	1313	nm
	Dispersion Slope S0 in Zero-Dispersion	0.091	ps/nm2/km
	Wavelength

TABLE 3
Comparative Example 1: Bending Loss (dB/turn)
	Wavelength
Bending Radius	1550 nm	1625 nm
15 mm	0.010	0.008
10 mm	0.051	0.060
7.5 mm	0.071	0.108
5 mm	0.325	0.471

Reference Example 1

The optical fiber of Reference Example 1 was constituted of a two-layer trench structure shown in FIG. 1.

The relative refractive index difference of the core 11 is represented as Δ_core, the relative refractive index difference of the internal cladding coat 12 is represented as Δ_ic, the relative refractive index difference of the layer 15 having the highest refractive index in the trench coating 13 is represented as Δ_tmax, the relative refractive index difference of the layer 16 having the lowest refractive index in the trench coating 13 is represented as Δ_tmin, the radius of the core 11 is represented as r_core, the radius of the internal edge of the trench coating 13 is represented as r_in, the radius of the external edge of the trench coating 13 is represented as r_out, and the radius of the internal edge of the layer 15 having the highest refractive index in the trench coating 13 is represented as r_tmax where the relative refractive index differences are based on the refractive index of the outermost cladding coat 14.

Parameters and the values of Reference Example 1 are shown in Table 4 and the characteristics thereof are shown in Table 5.

Additionally, each of the bending losses (dB/turn) in the bending radiuses in wavelengths of 1550 nm and 1625 nm is shown in Table 6.

TABLE 4
Reference Example 1: Parameters
rin/rcore   2.25
rtmax/rcore 3.00
rout/rcorc  3.90
rout        15.87 μm
Δcore       0.34%
Δic         0.00%
Δt min      −0.50%
Δt max      −0.20%

TABLE 5
Reference Example 1: Optical Characteristics
	Cable Cut-off wavelength of 2 m (λc2m)	1325	nm
	Cable Cut-off wavelength of 22 m (λc22m)	1220	nm
	λc2m − λc22m	105	nm
	MFD at 1310 nm	8.9	μm
	Zero-Dispersion Wavelength λ0	1306	nm
	Dispersion Slope S0 in Zero-Dispersion	0.091	ps/nm2/km
	Wavelength

TABLE 6
Reference Example 1: Bending Loss (dB/turn)
	Wavelength
Bending Radius	1550 nm	1625 nm
15 mm	0.001	0.011
10 mm	0.036	0.094
7.5 mm	0.072	0.211
5 mm	0.499	0.739

Regarding the bending loss, the MFD, the zero-dispersion wavelength 4, and the zero dispersion slope S₀, Reference Example 1 has substantially the same characteristics as that of Comparative Example 1, furthermore the λ_c2m−λ_c22m thereof was 105 nm which was shorter than Comparative Example 1 by approximately 40 nm.

The (r_tmax−r_in)/(r_out−r_in) was approximately 0.45, as evidenced by FIG. 4, the used amount of SiF₄ can be reduced by approximately 55% as compared with Comparative Example 1.

Reference Example 2

The optical fiber of Reference Example 2 was constituted of a three-layer trench structure shown in FIG. 2.

The relative refractive index difference of the core 21 is represented as Δ_core, the relative refractive index difference of the internal cladding coat 22 is represented as Δ_ic, the relative refractive index difference of the layer 25 having the highest refractive index in the trench coating 23 is represented as Δ_tmax, the relative refractive index difference of the layer 26 having the intermediate value in the refractive index in the trench coating 23 is represented as Δ_tmid, the relative refractive index difference of the layer 27 having the lowest refractive index in the trench coating is represented as Δ_tmin, the radius of the core 21 is represented as r_core, the radius of the internal edge of the trench coating 23 is represented as r_in, the radius of the external edge of the trench coating 23 is represented as r_out, the radius of the internal edge of the layer 25 having the highest refractive index in the trench coating 23 is represented as r_tmax, the radius of the internal edge of the layer 26 having the intermediate value in the refractive index in the trench coating 23 is represented as r_tmid where the relative refractive index differences are based on the refractive index of the outermost cladding coat 24.

Parameters and the values of Reference Example 2 are shown in Table 7 and the characteristics thereof are shown in Table 8.

Additionally, each of the bending losses (dB/turn) in the bending radiuses in wavelengths of 1550 nm and 1625 nm is shown in Table 9.

TABLE 7
Reference Example 2: Parameters
rin/rcore   2.25
rtmid/rcore 2.60
rtmax/rcorc 3.30
rout/rcore  3.90
rout        15.9 μm
Δcore       0.34%
Δic         0.00%
Δt min      −0.50%
Δt mid      −0.30%
Δt max      −0.20%

TABLE 8
Reference Example 2: Optical Characteristics
	Cable Cut-off wavelength of 2 m (λc2m)	1321	nm
	Cable Cut-off wavelength of 22 m (λc22m)	1220	nm
	λc2m − λc22m	101	nm
	MFD at 1310 nm	8.9	μm
	Zero-Dispersion Wavelength λ0	1313	nm
	Dispersion Slope S0 in Zero-Dispersion	0.091	ps/nm2/km
	Wavelength

TABLE 9
Reference Example 2: Bending Loss (dB/turn)
	Wavelength
Bending Radius	1550 nm	1625 nm
15 mm	0.001	0.013
10 mm	0.034	0.106
7.5 mm	0.071	0.243
5 mm	0.490	0.809

Regarding the bending loss, the MFD, the zero-dispersion wavelength λ₀, and the zero dispersion slope S₀, Reference Example 2 has substantially the same characteristics as that of Comparative Example 1. Furthermore, the λ_c2m−λ_c22m thereof was 101 nm which was shorter than Comparative Example 1 by approximately 47 nm.

The (r_tmax−r_in)/(r_out−r_in) was approximately 0.63 which was higher than that of Reference Example 1, but it was possible to reduce the cross-sectional area of layer having the relative refractive index difference Δ of −0.5% by separating the trench coating 23 into the three layers.

For this reason, Reference Example 2 can reduce the used amount of SiF₄ by approximately 75% as compared with Comparative Example 1 and realize a significant reduction greater than that of Reference Example 1 (reduction in approximately 55% as compared with Comparative Example 1).

Example 1

The optical fiber of Example 1 was constituted of a two-layer trench structure shown in FIG. 1.

The relative refractive index difference of the core 11 is represented as Δ_core, the relative refractive index difference of the internal cladding coat 12 is represented as Δ_ic, the relative refractive index difference of the layer 15 having the highest refractive index in the trench coating 13 is represented as Δ_tmax, the relative refractive index difference of the layer 16 having the lowest refractive index in the trench coating 13 is represented as Δ_min, the radius of the core 11 is represented as r_core, the radius of the internal edge of the trench coating 13 is represented as r_in, the radius of the external edge of the trench coating 13 is represented as r_out, and the radius of the internal edge of the layer 15 having the highest refractive index in the trench coating 13 is represented as r_tmax where the relative refractive index differences are based on the refractive index of the outermost cladding coat 14.

In Example 1, r_tmax was determined so that (r_tmax−r_in)/(r_out−r_in) becomes the values shown in Table 12, and Δ_core was adjusted and the optical fiber was thereby designed so that λ_c22m becomes 1220 nm as shown in Table 10 and the MFD in a wavelength of 1310 nm becomes 8.6 μm for each value.

TABLE 10
Common Ootical Characteristics in Example 1 to 4
Cable Cut-off wavelength of 22 m (λc22m) 1220 nm
MFD at 1310 nm                   8.6 μm

The parameters of the refractive index profile in Example 1 are shown in Table 11.

TABLE 11
Example 1: Parameters
rin/rcore   2.25
rout/rcore  3.90
rtmax/rcore 2.40 to 3.80
Δcore       0.359 to 0.373%
Δic         0.00%
Δt max      −0.20%
Δt min      −0.40%

Additionally, the bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm for each value (r_tmax−r_in)/(r_out−r_in), the difference λ_c2m−λ_c22m, and the ratio of the used amount of SiF₄ with reference to the used amount of SiF₄ in the single layer trench structure (the relative used amount of SiF₄) are shown in Table 12.

TABLE 12
Example 1
	Bending Loss (dB/turn)
	Wavelength of	Wavelength of
	1550 nm	1625 nm
	Bending	Bending	Bending	Bending		Relative Used
	Radius	Radius	Radius	Radius	λc2 m-λc22 m	Amount of
(rtmax-rin)/(rout-rin)	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
0.09	0.82	0.00122	1.50	0.00963	52	0.10
0.21	0.69	0.00108	1.19	0.01185	62	0.19
0.33	0.56	0.00092	0.98	0.01185	71	0.30
0.45	0.43	0.00074	0.76	0.01228	81	0.41
0.58	0.32	0.00058	0.52	0.01023	92	0.53
0.70	0.27	0.00051	0.45	0.00972	102	0.65
0.82	0.24	0.00048	0.39	0.00882	112	0.79
0.94	0.20	0.00049	0.33	0.00691	123	0.93
1.00	0.25	0.00100	0.35	0.00631	129	1.00

In other cases, an example of (r_tmax−r_in)/(r_out−r_in)=1.00 was an optical fiber provided with a conventionally-designed single layer trench structure.

In the case where (r_tmax−r_in)/(r_out−r_in) was in the range of 0.70 to 0.90, it was 1 possible to produce the optical fiber provided with a two-layer trench structure having the bending loss that was less than or equal to that of a conventionally-designed single layer trench structure.

When (r_tmax−r_in)/(r_out−r_in) was 0.70, it was possible to shorten λ_c2m−λ_c22m by 27 nm as a conventionally-designed single layer trench structure, and it was possible to reduce the used amount of SiF₄ by approximately 35%.

Also, when (r_tmax−r_in)/(r_out−r_in) was 0.90, it was possible to shorten λ_c2m−λ_c22m by approximately 10 nm, and it was possible to reduce the used amount of SiF₄ by approximately 10%.

FIGS. 7 to 10 show graphs on which the bending losses, λ_c2m−λ_c22m, and the relative used amount of SiF₄ shown in Table 12 are plotted.

Example 2

Example 2 shows an example of a two-layer trench structure having Δ_tmin of −0.50% which were designed so as to have λ_c22m and the MFD (with reference to Table 10) similar to Example 1.

The parameters of the refractive index profile thereof in Example 2 are shown in Table 13.

TABLE 13
Example 2: Parameters
rin/rcore   2.25
rout/rcore  3.90
rtmax/rcorc 2.40 to 3.80
Δcore       0.350 to 0.372%
Δic         0.00%
Δt max      −0.20%
Δt min      −0.50%

The bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm for each value (r_tmax−r_in)/(r_out−r_in), the difference in λ_c2m−λ_c22m, and the relative used amount of SiF₄ are shown in Table 14.

TABLE 14
Example 2
	Bending Loss (dB/turn)
	Wavelength of 1550	Wavelength of 1625		Relative
	nm	nm		Used
	Bending	Bending	Bending	Bending		Amount
	Radius	Radius	Radius	Radius	λc2 m-λc22 m	of
(rtmax-rin)/(rout-rin)	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
0.09	0.82	0.00125	1.33	0.01107	54	0.08
0.21	0.63	0.00101	1.06	0.01345	68	0.18
0.33	0.48	0.00080	0.86	0.01346	79	0.28
0.45	0.34	0.00060	0.56	0.01128	93	0.39
0.58	0.26	0.00049	0.47	0.01003	105	0.52
0.70	0.23	0.00049	0.40	0.00830	116	0.64
0.82	0.19	0.00053	0.33	0.00605	128	0.78
0.94	0.20	0.00510	0.33	0.00816	138	0.92
1.00	0.19	0.01006	0.36	0.03369	141	1.00

In the case where (r_tmax−r_in)/(r_out−r_in) was in the range of 0.70 to 0.90, preferably, 0.70 to 0.80, it was possible to produce the optical fiber provided with a two-layer trench structure having the bending loss that was less than or equal to that of a conventionally-designed single layer trench structure.

When (r_tmax−r_in)/(r_out−r_in) was 0.70, it was possible to shorten λ_c2m−λ_c22m by 25 nm as a conventionally-designed single layer trench structure, and it was possible to reduce the used amount of SiF₄ by approximately 36%.

Also, when (r_tmax−r_in)/(r_out−r_in) was 0.90, it was possible to shorten λ_c2m−λ_c22m by approximately 5 nm, and it was possible to reduce the used amount of SiF₄ by approximately 10%.

FIGS. 11 to 14 show graphs on which the bending losses, λ_c2m−λ_c22m, and the relative used amount of SiF₄ shown in Table 14 are plotted.

Example 3

Example 3 shows an example of a two-layer trench structure having Δ_tmax of −0.15% or −0.25% which were designed so as to have λ_c22m and the MFD (with reference to Table 10) similar to Example 1.

The bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm for each value (r_tmax−r_in)/(r_out−r_in), the difference in λ_c2m−λ_c22m and the relative used amount of SiF₄ are shown in Tables 15 and 16.

Particularly, Tables 15 and 16 correspond to Δ_tmax of −0.15% and −0.25%, respectively.

TABLE 15
Example 3: Δtmax = −0. 15%
	Bending Loss (dB/turn)
	Wavelength of	Wavelength of
	1550 nm	1625 nm		Relative
	Bending	Bending	Bending	Bending		Used
	Radius	Radius	Radius	Radius	λc2 m-λc22 m	Amount of
(rtmax-rin)/(rout-rin)	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
0.09	1.59	0.00185	2.38	0.00838	39	0.08
0.21	1.10	0.00144	1.74	0.00990	43	0.17
0.33	0.88	0.00126	1.33	0.01129	51	0.28
0.45	0.63	0.00098	0.96	0.01022	61	0.39
0.58	0.48	0.00080	0.80	0.01103	73	0.51
0.70	0.31	0.00057	0.57	0.01099	90	0.64
0.82	0.24	0.00047	0.42	0.00933	105	0.78
0.94	0.21	0.00047	0.33	0.00729	122	0.92
1.00	0.25	0.00100	0.35	0.00631	129	1.00

TABLE 16
Example 3: Δtmax = −0.25%
	Bending Loss (dB/turn)
	Wavelength of 1550	Wavelength of 1625		Relative
	nm	nm		Used
	Bending	Bending	Bending	Bending		Amount
	Radius	Radius	Radius	Radius	λc2 m-λc22 m	of
(rtmax-rin)/(rout-rin)	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
0.09	0.53	0.00091	0.89	0.01190	75	0.16
0.21	0.37	0.00067	0.62	0.01097	85	0.25
0.33	0.32	0.00059	0.55	0.01063	92	0.34
0.45	0.29	0.00055	0.49	0.01035	99	0.45
0.58	0.25	0.00050	0.46	0.00999	105	0.56
0.70	0.25	0.00050	0.44	0.00963	112	0.68
0.82	0.23	0.00050	0.38	0.00836	118	0.80
0.94	0.19	0.00048	0.33	0.00658	126	0.93
1.00	0.25	0.00100	0.35	0.00631	129	1.00

The bending losses in a wavelength of 1550 nm at the bending radiuses of 5 mm and 15 mm is shown in FIG. 15, and the bending loss in a wavelength of 1625 nm at the same bending radius is shown in FIG. 16.

The solid line located at the upper portion of FIGS. 15 and 16 showed the bending loss at bending radius of 5 mm, and the broken line located at the lower portion showed the bending loss at bending radius of 15 mm.

Additionally, λ_c2m−λ_c22m is shown in FIG. 17, and the relative used amount of SiF₄ is shown in FIG. 18.

In addition, the data in the case where Δ_tmax was −0.20% adopted in Example 1 are plotted in the FIGS. 15 to 18.

As shown in FIGS. 15 and 16, in the case where (r_tmax−r_in)/(r_out−r_in) was in the range of 0.70 to 0.90 with respect to −0.15%≧Δ_tmax≧−0.25%, it was possible to produce the optical fiber provided with a two-layer trench structure having the bending loss that was less than or equal to that of a conventionally-designed single layer trench structure.

As shown in FIGS. 17 and 18, when (r_tmax−r_in)/(r_out−r_in) was 0.70, it was possible to shorten λ_c2m−λ_c22m by approximately 20 to 40 nm as a conventionally-designed single layer trench structure, and it was possible to reduce the used amount of SiF₄ by approximately 35%.

Also, when (r_tmax−r_in)/(r_out−r_in) was 0.90, it was possible to shorten λ_c2m−λ_c22m by approximately 8 to 15 nm, and it was possible to reduce the used amount of SiF₄ by approximately 10%.

Example 4

Example 4 shows an example of a two-layer trench structure having Δ_tmin of −0.50% and Δ_tmax of −0.15% or −0.25% which were designed so as to have λ_c22m and the MFD (with reference to Table 10) similar to Example 1.

That is, Δ_tmin was equal to that of Example 2, and Δ_tmax was only changed from Example 2.

The bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm for each value (r_tmax−r_in)/(r_out−r_in), the difference in λ_c2m−λ_c22m, and the relative used amount of SiF₄ are shown in Tables 17 and 18.

Particularly, Tables 17 and 18 correspond to Δ_tmax of −0.15% and −0.25%, respectively.

TABLE 17
Example 4: Δtmax = −0.15%
	Bending Loss (dB/turn)
	Wavelength	Wavelength
	of 1550	of 1625		Relative
	nm	nm		Used
	Bending	Bending	Bending	Bending		Amount
	Radius	Radius	Radius	Radius	λc2 m-λc22 m	of
(rtmax-rin)/(rout-rin)	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
0.09	1.55	0.00182	2.31	0.00899	39	0.07
0.21	0.99	0.00135	1.58	0.01110	47	0.17
0.33	0.75	0.00111	1.14	0.01194	58	0.28
0.45	0.52	0.00084	0.88	0.01251	72	0.39
0.58	0.35	0.00061	0.58	0.01126	90	0.51
0.70	0.25	0.00048	0.41	0.00912	108	0.64
0.82	0.22	0.00052	0.36	0.00716	123	0.78
0.94	0.20	0.00346	0.28	0.00540	138	0.92
1.00	0.19	0.01006	0.36	0.03369	141	1.00

TABLE 18
Example 4: Δtmax = −0.25%
	Bending Loss (dB/turn)
	Wavelength of 1550	Wavelength of 1625
	nm	nm		Relative
	Bending	Bending	Bending	Bending		Used
	Radius	Radius	Radius	Radius	λc2 m-λc22 m	Amount of
(rtmax-rin)/(rout-rin)	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
0.09	0.52	0.00090	0.88	0.01251	78	0.10
0.21	0.34	0.00062	0.56	0.01118	92	0.19
0.33	0.29	0.00054	0.48	0.01030	101	0.30
0.45	0.25	0.00050	0.41	0.00893	109	0.41
0.58	0.24	0.00052	0.41	0.00819	117	0.53
0.70	0.22	0.00056	0.35	0.00650	125	0.65
0.82	0.23	0.00120	0.29	0.00531	131	0.79
0.94	0.20	0.00615	0.36	0.01961	139	0.93
1.00	0.19	0.01006	0.36	0.03369	141	1.00

The bending losses in a wavelength of 1550 nm at the bending radiuses of 5 mm and 15 mm is shown in FIG. 19, and the bending loss in a wavelength of 1625 nm at the same bending radius is shown in FIG. 20.

The solid line located at the upper portion of FIGS. 19 and 20 showed the bending loss at bending radius of 5 mm, and the broken line located at the lower portion showed the bending loss at bending radius of 15 mm.

Additionally, λ_c2m−λ_c22m is shown in FIG. 21, and the relative used amount of SiF₄ is shown in FIG. 22.

In addition, the data in the case where Δ_tmax was −0.20% adopted in Example 2 are plotted in the FIGS. 19 to 22.

As shown in FIGS. 19 and 20, in the case where (r_tmax−r_in)/(r_out−r_in) was range of 0.70 to 0.90 with respect to −0.15%≧Δ_tmax≧−0.25%, it was possible to produce the optical fiber provided with a two-layer trench structure having the bending loss that was less than or equal to that of a conventionally-designed single layer trench structure.

As shown in FIGS. 21 and 22, when (r_tmax−r_in)/(r_out−r_in) was 0.70, it was possible to shorten λ_c2m−λ_c22m by approximately 15 to 30 nm as a conventionally-designed single layer trench structure, and it was possible to reduce the used amount of SiF₄ by approximately 35%.

Also, when (r_tmax−r_in)/(r_out−r_in) was 0.90, it was possible to shorten λ_c2m−λ_c22m by approximately 5 to 8 nm, and it was possible to reduce the used amount of SiF₄ by approximately 10%.

Example 5

A two-layer trench structure having Δ_tmin of −0.70% and Δ_tmax of −0.15% was designed under a condition in which the MFD becomes 8.6 μm at λ_c22m of 1260 nm and a wavelength of 1310 nm.

The bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm for each value (r_tmax−r_in)/(r_out−r_in), the difference in λ_c2m−λ_c22m, and the relative used amount of SiF₄ are shown in Table 19.

TABLE 19
Calculated Result of Example 5
	Bending Loss (dB/turn)
	Wavelength of 1550	Wavelength of 1625
	nm	nm		Relative
	Bending	Bending	Bending	Bending		Used
	Radius	Radius	Radius	Radius	λc2 m-λc22 m	Amount of
(rtmax-rin)/(rout-rin)	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
0.09	0.21	0.00002	0.40	0.00028	40	0.07
0.21	0.13	0.00002	0.23	0.00030	53	0.17
0.33	0.10	0.00002	0.17	0.00043	70	0.27
0.45	0.07	0.00002	0.11	0.00054	93	0.39
0.58	0.07	0.00013	0.11	0.00118	114	0.51
0.70	0.06	0.00022	0.09	0.00072	133	0.64
0.82	0.05	0.00019	0.10	0.00077	147	0.78
0.94	0.04	0.00073	0.11	0.00713	159	0.92
1.00	0.04	0.00625	0.10	0.01362	159	1.00

When the two-layer trench structure and a conventional single layer trench structure were compared regarding bending loss, the bending loss at the bending radius of 5 mm of the two-layer trench structure was substantially the same as that of the bending loss of the conventional single layer trench structure under where (r_tmax−r_in)/(r_out−r_out) was 0.45 to 0.94.

Furthermore, the bending loss at the bending radius of 15 mm of the two-layer trench structure was less than that of the bending loss of the conventional single layer trench structure.

When (r_tmax−r_in)/(r_out−r_in) was 0.45, λ_c2m−λ_c22m was shorter than that of the single layer trench structure by 66 nm, and it was possible to reduce the used amount of SiF₄ by 61%.

Example 6

Example 6 shows an example of a two-layer trench structure having Δ_tmin of −0.30% and Δ_tmax of −0.20% which were designed so as to have λ_c22m and the MFD similar to Example 5.

The bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm for each value (r_tmax−r_in)/(r_out−r_in), the difference in λ_c2m−λ_c22m, and the relative used amount of SiF₄ are shown in Table 20.

TABLE 20
Calculated Result of Example 6
	Bending Loss (dB/turn)
	Wavelength of 1550	Wavelength of 1625		Relative
	nm	nm	λc2	Used
	Bending	Bending	Bending	Bending	m-	Amount
(rtmax-rin)/	Radius	Radius	Radius	Radius	λc22 m	of
(rout-rin)	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
0.09	0.15	0.00002	0.29	0.00024	48	0.19
0.21	0.13	0.00002	0.24	0.00026	54	0.28
0.33	0.11	0.00002	0.21	0.00023	58	0.37
0.45	0.10	0.00002	0.19	0.00025	63	0.47
0.58	0.09	0.00001	0.16	0.00024	69	0.58
0.70	0.09	0.00002	0.15	0.00033	75	0.69
0.82	0.09	0.00003	0.15	0.00056	81	0.81
0.94	0.08	0.00003	0.13	0.00075	91	0.93
1.00	0.08	0.00006	0.13	0.00120	98	1.00

When the two-layer trench structure and a single layer trench structure were compared regarding bending loss, the bending loss at the bending radius of 5 mm of the two-layer trench structure was substantially the same as that of the bending loss of the single layer trench structure under where (r_tmax−r_in)/(r_out−r_in) was 0.58 to 0.94.

Furthermore, the bending loss at the bending radius of 15 mm of the two-layer trench structure was less than that of the bending loss of the single layer trench structure.

When (r_tmax−r_in)/(r_out−r_in) was 0.58, λ_c2m−λ_c22m was shorter than that of the single layer trench structure by 29 nm, and it was possible to reduce the used amount of SiF₄ by 42%.

Example 7

A three-layer trench structure shown in FIG. 2 was designed under a condition in which the MFD becomes 8.9 μm at λ_c22m of 1260 nm and a wavelength of 1310 nm.

Parameters and the values of Example 7 are shown in Table 21.

Moreover, in order for comparison with Example 7, by use of an example formed by λ_c22m and the MFD similar to Example 7 as Comparative Example 2, the parameters of the conventional trench structure as shown in FIG. 6 are shown in Table 22.

TABLE 21
Parameters of Example 7
rin/rcore   2.25
rtmid/rcore 3.20
rtmax/rcorc 3.60
rout/rcore  3.90
rout        15.63 μm
Δcore       0.3295%
Δic         0.00%
Δt min      −0.70%
Δt mid      −0.50%
Δt max      −0.15%

TABLE 22
Parameters of Comparative Example 2
rin/rcore  2.25
rout/rcore 3.90
rout       14.5 μm
Δcore      0.297%
Δic        0.00%
Δt         −0.70%

The bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm, the difference in λ_c2m−λ_c22m, and the relative used amount of SiF₄ are shown in Table 23.

TABLE 23
Calculated Results of Example 7 and
Comparative Example 2
	Bending Loss
	(dB/turn)
	Wavelength of	Wavelength of
	1550 nm	1625 nm
						Rela-
					λc2	tive
	Bend-	Bend-	Bend-	Bend-	m-	Used
	ing	ing	ing	ing	λc22	Amount
	Radius	Radius	Radius	Radius	m	of
	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
Exam-	0.07	0.0004	0.16	0.0022	149	0.56
ple 7
Com-	0.06	0.0049	0.10	0.0147	165	1.00
parative
Exam-
ple 2

As compared with Comparative Example 2 that is a conventional trench structure, the bending loss of Example 7 was less than or equal to that of Comparative Example 2, λ_c2m−λ_c22m becomes shortened by 17 nm, the used amount of SiF₄ can be reduced by 44%.

Example 8

A three-layer trench structure shown in FIG. 2 was designed under a condition in which the MFD becomes 8.9 μm at λ_c22m, of 1260 nm and a wavelength of 1310 nm.

Parameters and the values of Example 8 are shown in Table 24.

Moreover, in order for comparison with Example 8, by use of an example formed by λ_c22m and the MFD similar to Example 8 as Comparative Example 3, the parameters of the conventional trench structure as shown in FIG. 6 are shown in Table 25.

TABLE 24
Parameters of Example 8
rin/rcore   2.25
rtmid/rcore 3.40
rtmax/rcorc 3.60
rout/rcore  3.90
rout        16.21 μm
Δcore       0.3525%
Δic         0.00%
Δt min      −0.30%
Δt mid      −0.25%
Δt max      −0.20%

TABLE 25
Parameters of Comparative Example 3
rin/rcore  2.25
rout/rcore 3.90
rout       16.07 μm
Δcore      0.349%
Δic        0.00%
Δt         −0.30%

The bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm, the difference in λ_c2m−λ_c22m, and the relative used amount of SiF₄ are shown in Table 26.

TABLE 26
Calculated Results of Example 8 and
Comparative Example 3
	Bending Loss (dB/turn)
	Wavelength of	Wavelength of
	1550	1625		Rela-
	nm	nm	λc2	tive
					m-	Used
	Bending	Bending	Bending	Bending	λc22	Amount
	Radius	Radius	Radius	Radius	m	of
	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
Exam-	0.14	0.0005	0.20	0.0022	92	0.73
ple 8
Com-	0.10	0.0005	0.15	0.0014	112	1.00
parative
Exam-
ple 3

As compared with Comparative Example 3 that is a conventional trench structure, the bending loss of Example 8 was less than or equal to that of Comparative Example 3, λ_c2m−λ_c22m becomes shortened by 20 nm, the used amount of SiF₄ can be reduced by 27%.

Example 9

A three-layer trench structure shown in FIG. 2 was designed under a condition in which the MFD becomes 8.6 μm at λ_c22m, of 1260 nm and a wavelength of 1310 nm.

Parameters and the values of Example 9 are shown in Table 27.

Moreover, in order for comparison with Example 9, by use of an example formed by λ_c22m and the MFD similar to Example 9 as Comparative Example 4, the parameters of the conventional trench structure as shown in FIG. 6 are shown in Table 28.

TABLE 27
Parameters of Example 9
rin/rcore   2.25
rtmid/rcore 3.20
rtmax/rcorc 3.40
rout/rcore  3.90
rout        15.49 μm
Δcore       0.366%
Δic         0.00%
Δt min      −0.70%
Δt mid      −0.50%
Δt max      −0.15%

TABLE 28
Parameters of Comparative Example 4
rin/rcore  2.25
rout/rcore 3.90
rout       14.27 μm
Δcore      0.328%
Δic        0.00%
Δt         −0.70%

The bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm, the difference in λ_c2m−λ_c22m, and the relative used amount of SiF₄ are shown in Table 29.

TABLE 29
Calculated Results of Example 9 and Comparative Example 4
	Bending Loss (dB/turn)
	Wavelength	Wavelength
	of	of		Relative
	1550 nm	1625 nm		Used
	Bending	Bending	Bending	Bending		Amount
	Radius	Radius	Radius	Radius	λc2 m-λc22 m	of
	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
Example 9	0.06	0.0002	0.10	0.0009	129	0.54
Comparative	0.04	0.0062	0.10	0.0136	159	1.00
Example 4

As compared with Comparative Example 4 that is a conventional trench structure, the bending loss of Example 9 was less than or equal to that of Comparative Example 4, λ_c2m−λ_c22m became shortened by 30 nm, the used amount of SiF₄ was reduced by 46%.

Example 10

A three-layer trench structure shown in FIG. 2 was designed under a condition in which the MFD becomes 8.6 μm at λ_c22m, of 1260 nm and a wavelength of 1310 nm.

Parameters and the values of Example 10 are shown in Table 30.

Moreover, in order for comparison with Example 10, by use of an example formed by λ_c22m and the MFD similar to Example 10 as Comparative Example 5, the parameters of the conventional trench structure as shown in FIG. 6 are shown in Table 31.

TABLE 30
Parameters of Example 10
rin/rcore   2.25
rtmid/rcore 3.20
rtmax/rcorc 3.40
rout/rcore  3.90
rout        15.73 μm
Δcore       0.38%
Δic         0.00%
Δt min      −0.30%
Δt mid      −0.25%
Δt max      −0.20%

TABLE 31
Parameters of Comparative Example 5
rin/rcore  2.25
rout/rcore 3.90
rout       15.61 μm
Δcore      0.376%
Δic        0.00%
Δt         −0.30%

The bending loss in the bending radiuses of wavelengths of 1550 nm and 1625 nm, the difference in λ_c2m−λ_c22m, and the relative used amount of SiF₄ are shown in Table 32.

TABLE 32
Calculated Results of Example 10
and Comparative Example 5
	Bending Loss (dB/turn)
	Wavelength	Wavelength
	of	of		Relative
	1550 nm	1625 nm		Used
	Bending	Bending	Bending	Bending		Amount
	Radius	Radius	Radius	Radius	λc2 m-λc22 m	of
	5 mm	15 mm	5 mm	15 mm	(nm)	SiF4
Example 10	0.09	0.00002	0.16	0.00028	72	0.61
Comparative	0.08	0.00006	0.13	0.00120	98	1.00
Example 5

As compared with Comparative Example 5 that is a conventional trench structure, the bending loss of Example 10 was less than or equal to that of Comparative Example 5, λ_c2m−λ_c22m became shortened by 26 nm, the used amount of SiF₄ was reduced by 39%.

In other cases, the technical scope of the invention is not limited to the above embodiments, but various modifications may be made without departing from the scope of the invention.

Claims

1. An optical fiber, comprising: a core provided at a central portion;an internal cladding coat provided around the core, having a refractive index less than a refractive index of the core;a trench coating provided at a periphery of the internal cladding coat and constituted of two or more layers having different refractive indices; andan outermost cladding coat provided at a periphery of the trench coating, whereina layer having the highest refractive index in the trench coating configures an outermost layer of the trench coating,Δcore>Δic>Δtmax>Δtmin, −0.15%≧Δtmax>Δtmin≧−0.7%, and

2. The optical fiber according to claim 1, wherein relationships −0.40%≧Δtmin≧−0.50% and −0.15%≧Δtmax≧−0.25% are satisfied in the trench coating.

3. The optical fiber according to claim 1, wherein relationship 0.7≦(rtmax−rin)/(rout−rin)≦0.9 is satisfied in the trench coating.

4. The optical fiber according to claim 1, wherein relationship 0.7≦(rtmax−rin)/(rout−rin)≦0.8 is satisfied in the trench coating.

5. The optical fiber according to claim 1, wherein the layer having the lowest refractive index in the trench coating configures an innermost layer of the trench coating.

6. The optical fiber according to claim 1, wherein the outermost cladding coat is formed of pure silica glass and the trench coating is formed of silica glass into which fluorine is introduced.