JP5937974B2 - Multimode optical fiber and optical fiber transmission system - Google Patents

Description

  The present invention relates to a multimode optical fiber and an optical fiber transmission system including the multimode optical fiber and using a higher-order mode.

  In the optical fiber transmission system, nonlinear effects and fiber fuses that occur in the optical fiber become problems, and the increase in transmission capacity and the increase in distance are limited. In order to relax these restrictions, it is necessary to reduce the density of light guided to the optical fiber, and a large core fiber has been studied (for example, refer to Non-Patent Documents 1 and 2).

  However, bending loss reduction, single-mode operation area expansion, and effective area expansion are in a trade-off relationship with each other, and there is a limit to the amount of effective area expansion under a predetermined condition. Therefore, an attempt has been made to apply a multi-input multi-output (MIMO) technique, which is a technique for increasing capacity in radio, to optical fiber transmission (see, for example, Non-Patent Document 3).

  Optical MIMO technology can expand transmission capacity by using a multimode optical fiber as a transmission medium, and further eliminates the need for single mode operating conditions, which are the limiting factors of large core optical fibers described above. It is also a feature that is possible. On the other hand, in optical fiber transmission using MIMO technology, if the group delay difference between modes increases, the amount of digital processing required for signal restoration increases, and the transmission distance is limited to a few tens of kilometers. (For example, refer nonpatent literature 4.).

  Therefore, an optical fiber in which the group delay difference between modes is suppressed to about 50 ps / km, an optical fiber in which the fundamental mode has a positive group delay difference faster than the higher-order mode, and a negative negative in which the fundamental mode is slower than the higher-order mode. A mode dispersion compensating transmission line combining optical fibers having a group delay difference has been proposed (see, for example, Non-Patent Documents 5 and 6).

T.A. Matsui, et al. , "Applicability of Photonic Crystal Fiber With Uniform Air-Hole Structure to High-Speed and Wide-Band Transmission OverTownConjugation" Lightwave Technol. 27, 5410-5416, 2009. K. Mukasa, et al. , "Comparisons of merits on wide-band transmission systems between using extremely improved solid SMFs with Aeff of 160μm2 and loss of 0.175dB / km and using large-Aeff holey fibers enabling transmission over 600nm bandwidth", the Proceedings of OFC2008, OthR1, Feb. 2008. B. C. Thomsen, “MIMO enabled 40 Gb / s transmission using mode division multiplexing in optical fiber communication” (OFC), 2010, p. OThM6. R. Ryf, S .; Randel, A.M. H. Gnauck, C.I. Boll, R.M. Essiambre, P.M. Winzer, D.C. W. Peckham, A .; McCurdy, and R.M. Lingle, "Space-division multiplexing over 10 km of three-mode fiber using coherent 6 × 6 MIMO processing", in Optical Fiber Communication Conference, OSA Technical Digest (CD) (Optical Society of America, 2011), paper PDPB10. L. G. -Nielsen1, et al. , “Few Mode Transmission Fiber with low DGD, low Mode Coupling and Low Loss”, the Proceedings of OFC2012, PDP5A. 1, Mar. 2012. T.A. Sakamoto, T .; Mori, T .; Yamamoto, S .; Tomita, "Differential Mode Delay Managed Transition Line for WDM-MIMO System Using Multi-Step Index Fiber, Journal of LightwaveTyvelwave. 30, no. 17, pp. 2783-2787, 2012 Y. Katsyuyama, M .; Tokuda, N.A. Uchida, M .; Nakahara, “A new method for measuring the V-value of a single-mode optical fiber”, Electron. Lett. 12, 669-670 (1976). M.M. Taylor, "Coherent Detection for Fiber Optic Communications Using Digital Signal Processing", in Optical Amplifiers and Their Applications / Coherent Optical Technologies and Applications, Technical Digest (CD) (Optical Society of America, 2006), paper CThB1.

  However, in Non-Patent Documents 5 and 6, the number of propagation modes is limited to two, and expansion of the number of modes is a problem. Accordingly, an object of the present invention has been made in view of the above problems, and a multimode optical fiber and an optical fiber transmission capable of reducing the group delay difference between propagation modes and increasing the number of propagation modes to more than two. The purpose is to provide a system.

  In order to achieve the above object, the multimode optical fiber of the present invention has a refractive index profile with a core having a graded refractive index profile and a clad structure in which a low refractive index layer is partially disposed. We decided to make each parameter appropriate.

Specifically, the multimode optical fiber according to the present invention is formed in the core from the center to the radius a ₁ , the cladding outside the core, and the cladding from the radius a ₂ to the radius a _3. A low refractive index layer,
The core is a graded type having an exponential constant α in which a refractive index profile in a radial direction from the center has a refractive index at the center as a relative refractive index Δ ₁ with respect to the cladding layer.
The low refractive index layer is a multimode optical fiber having a refractive index Δ ₂ relative to the cladding layer,
Each parameter of the refractive index distribution is
a ₁ = 11.9 to 12.1 μm, a ₂ = 13.4 to 13.8 μm, a ₃ = 16.0 to 20.5 μm, Δ ₁ = 0.59 to 0.61%, Δ ₂ = −0 A multi-mode optical fiber having .50 to -0.35% and .alpha. = 1.95 to 2.02.

  The multimode optical fiber includes a core having a refractive index that decreases exponentially outward from a central axis, a cladding that is outside the core and has a refractive index smaller than the refractive index of the core, the core, and the core And a low refractive index layer having a refractive index equal to or lower than the refractive index of the cladding. And by making these parameters of the refractive index distribution appropriate, the number of propagation modes can be set to four, and the group delay difference between the propagation modes can be reduced. Therefore, the present invention can provide a multimode optical fiber and an optical fiber transmission system that can reduce the group delay difference between the propagation modes and can increase the number of propagation modes to more than two.

Further, the multi-mode optical fiber according to the present invention includes a core to a radius a ₁ from the center, and a cladding outside the core, the low refractive index formed in the cladding from radius a ₂ to a radius a ₃ And having a layer
The core is a graded type having an exponential constant α in which a refractive index profile in a radial direction from the center has a refractive index at the center as a relative refractive index Δ ₁ with respect to the cladding layer.
The low refractive index layer is a multimode optical fiber having a refractive index Δ ₂ relative to the cladding layer,
Each parameter of the refractive index distribution is
a ₁ = 11.3 to 12.6 μm, a ₂ = 12.7 to 13.9 μm, a ₃ = 18.7 to 20.5 μm, Δ ₁ = 0.60 to 0.65%, Δ ₂ = −0 .48 to -0.44% and α = 1.85 to 2.10.

  In this multimode optical fiber, the number of propagation modes can be set to four by making these refractive index distribution parameters appropriate, and a positive mode delay difference or a negative mode delay difference can be set by setting the exponent constant α. .

  For this reason, the core of the multimode optical fiber according to the present invention may have a different exponent constant α in a section in the light propagation direction. In this case, it is desirable that there are two sections, the exponent constant α in one section is 1.97 or more, and the exponent constant α in the other section is less than 1.97.

  The exponent constant α can be a positive mode delay difference or a negative mode delay difference with 1.97 as a boundary, and by combining these, the group delay difference between propagation modes can be reduced. Therefore, the present invention can provide a multimode optical fiber and an optical fiber transmission system that can reduce the group delay difference between the propagation modes and can increase the number of propagation modes to more than two.

An optical fiber transmission system according to the present invention includes N (N is an integer of 2 or more) optical transmitters that respectively transmit N data as optical signals,
A multiplexer that multiplexes N optical signals from the optical transmitter so that propagation modes are different;
The multimode optical fiber according to any one of claims 1 to 4, which propagates an optical signal from the multiplexer;
A duplexer for demultiplexing the optical signal from the multimode optical fiber at different branching ratios;
M optical receivers (M is an integer greater than or equal to N) for receiving optical signals from the duplexer;
An FIR equalizer that compensates for signal degradation caused during propagation of the multimode optical fiber from M electrical signals output from the optical receiver and restores N data transmitted by the optical transmitter; ,
Is provided.

  The present optical fiber transmission system includes a multi-mode optical fiber that can reduce the group delay difference in the light propagation mode, and can reduce the load of digital signal processing during reception. Therefore, the present invention can provide an optical fiber transmission system capable of reducing the load of digital processing necessary for signal restoration.

  The present invention can provide a multimode optical fiber and an optical fiber transmission system that can reduce the group delay difference between the propagation modes and can make the number of propagation modes larger than two.

It is a figure explaining the refractive index distribution of the multimode optical fiber which concerns on this invention. It is a figure explaining the mode delay difference characteristic at the time of changing the relative refractive index (DELTA) ₂ of the multimode optical fiber which concerns on this invention. Is a diagram illustrating a mode delay difference characteristics when changing the a _{2 /} a ₁ of the multi-mode optical fiber according to the present invention. Is a diagram illustrating a mode delay difference characteristics when changing the a _{3 /} a ₂ of the multi-mode optical fiber according to the present invention. It is a figure explaining the mode delay difference characteristic at the time of changing (alpha) of the multimode optical fiber which concerns on this invention. It is a figure which shows an example of the impulse response in wavelength 1550nm of the multimode optical fiber which concerns on this invention. It is a figure which shows the wavelength dependence of the mode delay difference characteristic of the multimode optical fiber which concerns on this invention. It is a figure which shows an example of the impulse response of wavelength 1550nm in the multimode optical fiber which concerns on this invention. It is a figure explaining the optical fiber transmission system concerning the present invention. It is a figure explaining each parameter of refractive index distribution of the multimode optical fiber concerning the present invention.

  Embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments described below are examples of the present invention, and the present invention is not limited to the following embodiments.

(Embodiment 1)
FIG. 1 is a diagram showing a refractive index distribution in the radial direction in the multimode optical fiber of the present embodiment. This multimode optical fiber, chromatic and core to a radius a ₁ from the center, and a cladding outside said core, and a low refractive index layer formed in the cladding from radius a ₂ to a radius a _3, a The core is a graded type having an index constant α in which a refractive index profile in the radial direction from the center has a refractive index at the center as a relative refractive index Δ ₁ with respect to the cladding layer, and the low refractive index layer is The refractive index is a relative refractive index Δ ₂ with respect to the cladding layer.

The core has an outer radius a ₁ , a relative refractive index with respect to the cladding Δ ₁ , a radius to the inner boundary of the low refractive index layer a ₂ , and a radius to the outer boundary of the low refractive index layer a ₃ , low refractive index layer is a relative refractive index relative to the cladding is delta _2.

This low-delay multimode optical fiber is provided with a core having an α-power refractive index distribution expressed by Equation 1, an outer cladding, and an outer vicinity of the core, and has a lower refractive index and a uniform refractive index than the cladding. It is composed of a low refractive index layer having a distribution. Here, n (r) is the refractive index at a position r in the radial direction from the center, n ₁ is the refractive index of the core center, and α is an exponential constant. Refractive index profile of a multimode optical fiber shown in FIG. 1, the radius r follows the refractive index profile multiply α is a ₁ smaller area. The exponent constant α is a dimensionless parameter indicating a graded profile, and is sometimes called an alpha parameter.

The low refractive index layer is formed in a region from a ₂ to a ₃ (outside of the core having an α power refractive index distribution), and has a uniform refractive index distribution lower than that of the cladding. Specifically, the parameters of the multimode optical fiber of the present embodiment are as follows: a ₁ = 11.9 to 12.1 μm, a ₂ = 13.4 to 13.8 μm, a ₃ = 16.0 to 20.5 μm. , Δ ₁ = 0.59 to 0.61%, Δ ₂ = −0.50 to −0.35%, and α = 1.95 to 2.02. The multi-mode optical fiber having the above parameters can improve the bending loss characteristics of the modes that can be propagated while reducing the delay between modes.

Hereinafter, the parameters will be described in detail. Α-power refraction as a multimode optical fiber with a wavelength range of 1530-1625 nm (CL band), bending loss of 0.5 dB / 100 turn or less, and a propagation mode number of 4 (LP01, LP11, LP21, LP02 modes) Outside the core with a rate distribution (α = 2.0, a ₁ = 12.0 μm, Δ ₁ = 0.60%), a ₂ = 13.5 μm, a ₃ = 20.0 μm, Δ ₂ = −0 A low refractive index layer of 45% is provided.

When the relative refractive index difference Δ ₂ of the low refractive index layer is changed, a mode group delay difference (DMD: higher order mode (LP11, LP21, LP02 mode) and basic mode (LP01 mode) calculated based on the finite element method is used. FIG. 2 shows changes in the differential mode delay. DMD is a value obtained by subtracting the group delay of the basic mode from the group delay of the higher-order mode. In as shown in FIG. 2, DMD is less 200 ps / miles in four modes when the relative refractive index difference delta ₂ is -0.50～-0.35% of the low refractive index layer.

If you change the radius _{a 2} to the inner boundary of the low refractive index layer, FIG changes in DMD order mode calculated based on the finite element method (LP11, LP21, LP02 modes) and the fundamental mode (LP01 mode) 3 shows. As shown in FIG. 3, when the radius a ₂ to the inner boundary of the low refractive index layer is 13.4 to 13.8 μm, the mode group delay difference is 200 ps / km or less in the four modes.

If you change the radius _{a 3} to the outer boundary of the low refractive index layer, FIG changes in DMD order mode calculated based on the finite element method (LP11, LP21, LP02 modes) and the fundamental mode (LP01 mode) 4 shows. As shown in FIG. 4, the mode group delay difference in the four modes when radius a ₃ is not less than 16.0μm to the inner boundary of the low refractive index layer is less than 200 ps / miles.

  In order to limit the number of propagation modes to four at wavelengths of 1530 to 1625 nm, it is a condition that the LP31 mode, which is the fourth higher-order mode, does not propagate. The condition for not propagating was that the bending loss at a bending radius of 140 mm in the wavelength band used was 1 dB / m or more. This condition is based on the assumption that a bending radius of 140 mm is used to measure the cutoff wavelength as described in Non-Patent Document 7 and that the loss does not propagate at 1 dB / m or more as described in Non-Patent Document 1. Is based.

The LP31 mode bending loss in the most bending loss becomes smaller wavelength 1530nm in the use wavelength range contemplated is shown in Figure 4, _{a 3} becomes the LP31 mode bending loss 1 dB / m or more when: 20.5 microns, propagation The number of modes can be limited to four. That by adjusting the radius _{a 3} to inner boundary of the low refractive index layer 16.0～20.5Myuemu, while the number of propagation modes 4 Tsunishi, it is possible to below 200 ps / miles a DMD .

  FIG. 5 shows changes in DMD between the higher-order modes (LP11, LP21, LP02 mode) and the basic mode (LP01 mode) calculated based on the finite element method when the exponent constant α of the core portion is changed. As shown in FIG. 5, the DMD is 200 ps / km or less in the four modes when the exponent constant α of the core is 1.95 to 2.02.

  As described above, by setting each parameter of the refractive index distribution as described above, it is possible to manufacture a multimode optical fiber having a propagation mode number of 4 and a mode group delay difference of 200 ps / km or less. .

(Embodiment 2)
The multimode optical fiber according to the present embodiment is characterized in that the exponential constant α of the core is different in the section in the light propagation direction. Furthermore, when there are two sections, the exponent constant α of one section is 1.97 or more, and the exponent constant α of the other section is less than 1.97.

  From the graph of FIG. 5, the DMDs of the second higher order mode and the third higher order mode are almost equal and grouped, and the DMD increases from negative to positive at the core constant α = 1.97. You can see how it is. Furthermore, the DMD of each higher order mode is proportional to the exponent constant α of the core. Therefore, even when it is difficult to reduce the delay by one optical fiber due to a manufacturing error, it is possible to further reduce the DMD by connecting the positive and negative optical fibers and adjusting the fiber length. .

  For example, by connecting a 4-mode fiber having a negative DMD of α = 1.92 and a 4-mode fiber having a negative DMD of α = 2.02 by the same fiber length, a mode delay compensated transmission having a propagation mode number of 4 A road can be realized.

As described above, when there are a plurality of sections having different core index constants α in the light propagation direction, the parameters of the refractive index distribution are a ₁ = 11.3 to 12.6 μm and a ₂ = 12.7 to 13 respectively. 0.9 μm, a ₃ = 18.7 to 20.5 μm, Δ ₁ = 0.60 to 0.65%, Δ ₂ = −0.48 to −0.44%, α = 1.85 to 2.10 Preferably there is.

  FIG. 10 is a table showing parameters of the three types of multimode optical fibers used in the evaluation.

  FIG. 6 is a diagram for explaining the result of the impulse response of each multimode optical fiber shown in FIG. Among the three types, Fiber B can realize a multimode optical fiber with the lowest delay. It can also be seen that the second higher order mode and the third higher order mode are grouped. Fibers A and B are multimode optical fibers having a positive mode delay difference, and Fiber C is a multimode optical fiber having a negative mode delay difference.

  FIG. 7 is a diagram for explaining the wavelength dependency of the DMD of each multimode optical fiber shown in FIG. The plot is the measured value, and the line is the calculated value. The measured and calculated values agreed well. Fiber B DMD was 135 ps / km or less in the wavelength range of 1530 to 1625 nm. Also in Fiber A and Fiber C, the DMD achieves ± 500 ps / km or less.

  FIG. 8 is a diagram for explaining an impulse response when Fiber A and Fiber C are connected at a wavelength of 1550 nm. By connecting Fiber A and Fiber C, each pulse becomes one pulse, and a mode delay compensating transmission path that can further reduce delay can be realized.

  FIG. 9 is a diagram for explaining the wavelength dependency of the DMD of each multimode optical fiber shown in FIG. By connecting Fiber A and Fiber C, a mode delay compensation transmission line with a DMD of 50 ps / km or less can be realized in the wavelength region 1530 to 1625 nm.

  As described above, the mode delay difference of the multimode optical fiber can be adjusted to be positive or negative by adjusting each parameter of the refractive index distribution, and the positive mode delay difference of the multimode optical fiber and the negative mode delay difference of By connecting with a multimode optical fiber, it is possible to manufacture a multimode optical fiber (mode delay compensating transmission line) having four propagation modes and a mode group delay difference of 50 ps / km or less.

(Embodiment 3)
FIG. 9 is a schematic diagram of the optical fiber transmission system 301 of the present embodiment. The optical fiber transmission system 301 includes:
N (N is an integer of 2 or more) optical transmitters 10 each transmitting N data as optical signals,
A multiplexer 20 that multiplexes N optical signals from the optical transmitter 10 in different propagation modes;
The multimode optical fiber 30 described in the first or second embodiment for propagating the optical signal from the multiplexer 20, and
A demultiplexer 40 for demultiplexing an optical signal from the multimode optical fiber 30 with different branching ratios;
M optical receivers 50 (M is an integer equal to or greater than N) for receiving optical signals from the duplexer 40;
An FIR equalizer 60 that compensates for signal degradation generated during propagation of the multimode optical fiber 30 from the M electrical signals output from the optical receiver 50 and restores N data transmitted by the optical transmitter 10. When,
Is provided.

  N types of signals (x (n)) emitted from N (N is an integer of 2 or more) transmitters 10 are combined such that the propagation mode ratios to be combined in the multiplexer 20 are different. The combined signal light enters the multimode optical fiber 30 and is split into M ports (M is an integer equal to or greater than N) at different branching ratios in the duplexer 40 installed on the output side. The demultiplexed M types of signals (y (n)) are received by the M receivers 50, and the signal degradation received by the multimode optical fiber is compensated and restored by the FIR equalizer 60 installed in the subsequent stage. A signal (u (n)) is obtained. The optical fiber transmission system 301 is N-input M-output MIMO transmission, and can transmit N types of signals in parallel.

  The FIR equalizer 60 can also compensate for mode dispersion, chromatic dispersion, and polarization dispersion. Further, in order to acquire the electric field amplitude and phase information of the received signal, the receiver 50 is configured by a local light source, a 90 ° optical hybrid, a balance receiver, an analog-digital converter, and a calculator (for example, Non-Patent Document 8). See).

  The FIR equalizer 60 can compensate for the linear distortion generated in the multimode optical fiber 30, and appropriately transmits other transmissions generated in the multimode optical fiber 30 by appropriately setting the delay amount and coefficient of the tap. It is possible to compensate for signal degradation due to interference from the machine, mode dispersion, wavelength dispersion, and polarization dispersion. However, when the signal degradation due to mode dispersion is compensated, if the difference in mode delay between the basic mode and the higher order mode becomes large, the amount of calculation required for signal degradation compensation becomes enormous. However, the optical fiber transmission system 301 uses the multimode optical fiber 30 with a small mode delay difference, and can reduce the amount of calculation required for compensation. Furthermore, since the number of propagation modes is 4, the capacity can be increased. In other words, by providing the multimode optical fiber 30, it is possible to increase the capacity and distance of the transmission system with the conventional FIR equalizer.

  The following describes the multimode optical fiber and the optical fiber transmission system of the present embodiment.

<Issues>
An object of the present invention is to reduce a digital processing load necessary for signal restoration, enable long-distance transmission, and increase a transmission capacity with four propagation modes, and an optical fiber transmission system including the same Is to provide.

<Solution>
The present invention
(1): a core having a graded profile;
A cladding outside the core and having a refractive index smaller than the refractive index of the core;
Between the core and the clad, having a low refractive index layer having a refractive index equal to or lower than the refractive index of the clad,
The core, the outer peripheral radius a _1, the relative refractive index relative to the cladding layer is delta _1, an exponential constant alpha, radius a ₂ to the inner boundary of the low refractive index _layer, the outer side of the low refractive index layer Assuming that the radius to the boundary is a ₃ and the low refractive index layer has a relative refractive index of Δ ₂ with respect to the cladding layer, each parameter of the refractive index distribution is a ₁ = 11.3 to 12.6 μm, a ₂ = 12.7 to 13.9 μm, a ₃ = 18.7 to 20.5 μm, Δ ₁ = 0.60 to 0.65%, Δ ₂ = −0.48 to −0.44%, α = It is a multimode optical fiber having a propagation mode number of 4, which is 1.85 to 2.10.

The present invention also provides:
(2): a core having a graded profile;
A cladding outside the core and having a refractive index smaller than the refractive index of the core;
Between the core and the clad, having a low refractive index layer having a refractive index equal to or lower than the refractive index of the clad,
The core, the outer peripheral radius a _1, the relative refractive index relative to the cladding layer is delta _1, an exponential constant alpha, radius a ₂ to the inner boundary of the low refractive index _layer, the outer side of the low refractive index layer When the radius to the boundary is a ₃ and the low refractive index layer has a relative refractive index Δ ₂ with respect to the cladding layer, the parameters of the refractive index distribution are a ₁ = 12.0 μm and a ₂ = 13. Multi-mode light having a propagation mode number of 4 characterized by: .5 μm, a ₃ = 20.0 μm, Δ ₁ = 0.60%, Δ ₂ = −0.45%, and α = 2.00. It is a fiber.

(3): An optical fiber having a positive mode delay difference in which the core has an exponent constant α of 1.97 or more and a negative mode in which the core has an exponent constant α of 1.97 or less. At least one optical fiber having a delay difference is mixed, and the positive mode delay difference of the optical fiber having the positive mode delay difference and the negative mode delay difference of the optical fiber having the mode delay difference cancel each other. The mode delay compensation transmission line is characterized in that the mode delay difference in the whole is compensated.

The present invention
(4): N optical transmitters for transmitting optical signals (N is an integer of 2 or more), and a multiplexer for multiplexing the optical signals from the N optical transmitters so that the propagation modes are different. The optical signal from the multiplexer is propagated, and the optical fiber described in (1) or (2) above or the mode delay compensating transmission line described in (3) above and the optical signal from the optical fiber system are transmitted. Demultiplexers for demultiplexing at different branching ratios, M optical receivers (M is an integer equal to or greater than N) for receiving optical signals from the demultiplexers, and optical signals from the M optical receivers And an FIR equalizer that separates N into N.

<Effect>
The multimode optical fiber according to the present invention has a core having a graded profile and a low refractive index layer outside the core, and the mode delay difference between the second higher-order mode and the third higher-order mode is almost the same. It is grouped at 0, and the group delay difference in the light propagation mode can be reduced. That is, the load of digital signal processing can be reduced by using the multimode optical fiber in the optical transmission system using the MIMO technology. Therefore, the present invention can provide a multimode optical fiber that can reduce the load of digital processing required for signal restoration.

  Furthermore, the multimode optical fiber according to the present invention has four propagation modes, and the transmission capacity can be increased.

  An optical fiber transmission system according to the present invention includes the multimode optical fiber. Therefore, the present invention can provide an optical fiber transmission system that can reduce the load of digital processing necessary for signal restoration and can increase the transmission distance and capacity.

  The present invention can realize a large capacity and a long distance of optical fiber transmission by using a higher-order mode in the fiber.

10: transmitter 20: multiplexer 30: multimode optical fiber 40: duplexer 50: receiver 60: FIR equalizer 301: optical fiber transmission system

Claims (2)

A core from the center to a radius a ₁ , a cladding outside the core, and a low refractive index layer formed in the cladding from a radius a ₂ to a radius a ₃ ,
The core is a graded type having an exponential constant α in which a refractive index profile in a radial direction from the center has a refractive index at the center as a relative refractive index Δ ₁ with respect to the cladding layer.
The low refractive index layer is a multimode optical fiber having a refractive index Δ ₂ relative to the cladding layer,
The parameters of the refractive index profile,
a ₁ = 11.9 to 12.1 μm, a ₂ = 13.4 to 13.8 μm, a ₃ = 16.0 to 20.5 μm, Δ ₁ = 0.59 to 0.61%, Δ ₂ = −0 .50～-0.35%, as alpha = 1.95 to 2.02, and limit the number of propagation modes to four, four modes group delay difference in the propagation mode is characterized der Rukoto below 200 ps / miles Multimode optical fiber. N (N is an integer of 2 or more) optical transmitters that respectively transmit N data as optical signals;
A multiplexer that multiplexes N optical signals from the optical transmitter so that propagation modes are different;
The multimode optical fiber according to claim 1 , which propagates an optical signal from the multiplexer;
A duplexer for demultiplexing the optical signal from the multimode optical fiber at different branching ratios;
M optical receivers (M is an integer greater than or equal to N) for receiving optical signals from the duplexer;
An FIR equalizer that compensates for signal degradation caused during propagation of the multimode optical fiber from M electrical signals output from the optical receiver and restores N data transmitted by the optical transmitter; ,
An optical fiber transmission system comprising:

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