RU2264639C1 - Method for increasing bandwidth of multi-mode fiber-optic communication line - Google Patents

Abstract

FIELD: fiber-optic communication lines.

SUBSTANCE: in the middle of portion of multi-mode fiber-optic communication line a mode multiplexer and mode demultiplexer are enabled, via which mode composition of optical emission, coming from output of multi-mode fiber-optic communication line of first half of portion, is divided on group of lower order modes and higher order modes, selected by mode demultiplexer group of higher order modes is transformed to group of lower order modes, and mode-converter selected lower order modes group is transformed to higher order modes group, after that these two modes groups are combined by mode multiplexer and sent to input of multi-mode fiber-optic line of second half of portion.

EFFECT: increased possible length of multi-mode fiber-optic communication line with increased bandwidth.

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Description

The invention relates to a fiber optic communication technique and can be used to increase the bandwidth of a multimode fiber optic transmission line.

The known method / 1-6 / increase the bandwidth of a multimode fiber optic transmission line, which consists in the fact that to a multimode optical fiber through a special matching device connect a single-mode radiation source (laser). In a multimode optical fiber, when optical radiation is input from a single-mode source, two groups of modes propagate: lower-order modes and higher-order modes, in which the propagation velocities of the modes differ significantly. This results in differential mode delay limiting the bandwidth. A special matching device provides predominant mode excitation of one group, which significantly suppresses the effect of differential mode delay at the beginning of the line. However, due to the coupling of modes on irregularities during the propagation of optical radiation in a multimode fiber, power is redistributed between the modes. As a result, when moving away from the input, the differential mode delay again becomes significant, which limits the length of the multimode optical transmission line, on which it is possible to increase the bandwidth by this method.

The known method / 7, 8 / increase the bandwidth of a multimode fiber optic transmission line, which consists in the fact that at the output of the line to the multimode optical fiber connect a device that includes a system of photodetectors, the outputs of which are connected through a delay line to a common output. The photodetectors are distributed in space so that each of the photodetectors receives a separate mode or group of modes at the output of a multimode optical fiber, and the time delay of the received modes is controlled by delay lines so as to suppress the differential mode delay and mode dispersion at the common output. This method provides for optoelectronic conversion and can be implemented only at the end of the line. But since the sensitivity of the photodetectors is limited, and the power of the optical signal is distributed between the modes, the length of the multimode optical transmission line, on which the bandwidth can be increased by this method, is also limited.

The known method / 9-14 / increase the bandwidth of the fiber optic transmission line, which consists in the fact that in the middle of the fiber optic transmission line include an inverter of the spectrum of the optical signal. This method is used to compensate for chromatic dispersion and is not applicable to suppress the effect of differential mode delay.

The known method / 15 / increase the bandwidth of a multimode fiber optic transmission line, which consists in the fact that the modal composition propagating in a multimode fiber optic transmission line of optical radiation is divided into a group of lower order modes and a group of higher order modes, lower order modes are suppressed, and higher-order modes pass, thereby eliminating differential mode delay and providing increased bandwidth. Various techniques can be used to separate and suppress modes. Due to suppression of lower-order modes, the losses of the multimode fiber-optic transmission line are large, which limits its length and requires an increase in the power of the optical radiation source, the sensitivity of the photodetector, and the use of optical amplifiers.

The essence of the invention is to increase the length of a multimode fiber optic transmission line with increased bandwidth.

This essence is achieved by the fact that, according to the method for increasing the bandwidth of a multimode fiber optic transmission line, namely, that the mode composition of optical radiation propagating in a multimode fiber optic transmission line is divided into a group of lower order modes and a higher order mode group, in the middle of the multimode fiber optic transmission line include a mode multiplexer and a mode demultiplexer, with which the mode composition of the optical radiation The output of the multimode fiber optic transmission line of the first half of the section is divided into a lower order mode group and a higher order mode group, the higher order mode group allocated by the mode demultiplexer is converted into a lower order mode group, and the lower order mode group allocated by the mode demultiplexer is converted into a group higher-order mode, after which these two groups of modes are combined using a mode multiplexer and fed to the input of a multimode fiber-optic transmission line of the second half of the section .

The drawing shows a structural diagram of a device for implementing the proposed method.

The device contains a modal demultiplexer 1, the input of which is connected to the output of a multimode fiber optic fiber 2 of the first half of the transmission line section, one output of which is connected to the input of the higher mode converter to the lower 3, and the other to the input of the lower mode converter to the higher 4, and mode multiplexer 5, the output of which is connected to multimode fiber-optic fiber 6 of the second half of the transmission line section, one of its input with the output of the higher mode converter to the lower 3, its other input with the output of the lower mode converter to the higher 4.

The device operates as follows.

The optical radiation propagating in a multimode fiber-optic transmission line from the output of a multimode optical fiber 2 of the first half of a portion of the transmission line is fed to the input of the mode demultiplexer 1, where the mode composition of the optical radiation is divided into two groups: a lower order mode group and a higher order mode group. A group of higher-order modes from one of the outputs of the mode demultiplexer 1 is fed to the input of the converter 3 of the higher modes to the lower ones, where the higher modes are converted to lower ones. A group of lower-order modes from the other output of the mode demultiplexer 1 is fed to the input of the converter 4 of the lower modes to the higher ones, where the lower modes are converted to higher ones. These groups of modes from the outputs of converters 3, 4 go to the inputs of the mode multiplexer 5, where they are combined, and from the output of the mode multiplexer 5 go to the input of the multimode optical fiber 6 of the second half of the transmission line section. Due to the phase inversion of the groups of mode components of the optical signal in the middle of the transmission line section, the differential mode delay of the multimode optical fiber of the first half of the transmission line section will be compensated by the differential mode delay of the multimode optical fiber of the second half of the transmission line section.

Since this method does not suppress any mode components of the optical signal, the losses in the multimode fiber optic transmission line are relatively small, which ensures an increase in the length of the multimode fiber optic transmission line with an increased bandwidth.

LITERATURE

1. Duser M., Bayvel P. 2.5 Gbit / s transmission over 4.5 km of 62.5 um multimode fiber using center launch technique. - Electronics letters, Vol. 36, No. 1, 2000.

2. Hackert M.J. Characterizing multimode fiber bandwidth for Gigabit Ethernet applications. - Corning, WP 4062, August, 2001.

3. US 4723828.

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9. Merker T., Meissner P., Feiste U. High bit rate OTDM transmission over standard-fiber using mid-span spectral inversion and its limitations. - TUD, AR 2000 29, pp. 99-104.

10. US 2002/0114040 A1.

11. EP 0776103 A2.

12. WO 00/14917.

13. US 6,160,942 A2.

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15. US 6356680.

Claims (1)

A method of increasing the bandwidth of a multimode fiber optic transmission line, namely, that the mode composition of optical radiation propagating in a multimode fiber optic transmission line is divided into a lower order mode group and a higher order mode group, characterized in that in the middle of the multimode fiber optic transmission lines include a mode multiplexer and a mode demultiplexer, with which the mode composition of the optical radiation coming from the output of the multimode fiber of the optical transmission line of the first half of the section, is divided into a lower order mode group and a higher order mode group, the higher order mode group allocated by the mode demultiplexer is converted into a lower order mode group, and the lower order mode group allocated by the mode demultiplexer is converted into a higher order mode group, after which these two groups of modes are combined using a mode multiplexer and fed to the input of a multimode fiber-optic transmission line of the second half of the section.