RU2548383C2 - Method of selecting multimode optical fibres of fibre-optic transmission line for operation with single-mode optical radiation source - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: multimode fibre-optic transmission line is probed with short optical pulses of a single-mode optical radiation source. The end of the single-mode source is moved on the end of the multimode optical fibre with a given step along the diameter. The pulse response of the optical fibre of the multimode fibre-optic transmission line is measured and the set of pulse response measurement result is then used to plot a differential modal delay graph, which is compared with a graph of allowable differential modal delay values. If the differential modal delay estimates for the graph plotted based on pulse response measurement results do not exceed corresponding estimates of the graph of allowable differential modal delay values, the multimode optical fibre of the fibre-optic transmission line is selected for operation with a single-mode optical radiation source.

EFFECT: faster and fewer measurements.

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Description

The invention relates to the field of fiber-optic communication technology and can be used to select multimode optical fibers of a fiber-optic transmission line for working with a single-mode optical radiation source.

A known method [1] selection of multimode optical fibers according to the results of assessing the throughput of a multimode fiber optic transmission line by the passband, which consists in measuring the passband of a multimode optical transmission line under conditions of uniform illumination of the end face of a multimode optical fiber with optical radiation at the input which estimate the throughput of a multimode optical transmission line. This is the so-called OFL method - overfilled launch. For high-speed transmission over a multimode fiber optic line, single-mode optical radiation sources — lasers — are used as optical radiation sources. Lasers excite a limited number of modes in a multimode optical fiber, and a so-called low-mode regime is formed in a multimode fiber-optic transmission line. In the low-mode mode of operation of a multimode fiber optic transmission line, its throughput depends on the differential mode delay of the transmission line and the distribution of optical radiation power at the end of the multimode optical fiber at the input. The latter, in turn, depends on the parameters of the optical radiation source and the conditions for its matching with a multimode optical fiber. The transmission line bandwidth is not correlated with the differential mode delay, the parameters of the radiation source and the conditions of its matching with a multimode optical fiber, which leads to errors in the selection of multimode optical fibers of a fiber-optic transmission line for operation with a single-mode optical radiation source.

A known method [2] of estimating the bandwidth of a multimode fiber optic transmission line by the passband, which consists in measuring the passband of a multimode optical transmission line in a low-mode mode when a single-mode optical radiation source is connected to a multimode optical fiber at the input through a single-mode optical fiber, by which the throughput of the multimode optical transmission line in the low-mode mode is estimated. This is the so-called RML method - restricted mode launch. The bandwidth estimates obtained by this method are also not correlated with the differential mode delay and do not depend on the parameters of the optical radiation source and the conditions for matching it at the input, which leads to errors in the selection of multimode optical fibers of a fiber-optic transmission line for operation with a single-mode optical radiation source.

A known method [3] for estimating the throughput of a multimode fiber optic transmission line according to a differential mode delay diagram, namely, that a multimode fiber optic transmission line is probed with short optical pulses of a single-mode optical radiation source, which are introduced into a multimode optical fiber of a multimode optical fiber transmission lines through a single-mode optical fiber, the end of which is moved at the input of a multi-mode fiber-optic transmission line and at the end of the multimode optical fiber with a given step along the diameter of the multimode optical fiber, and at each step of the movement of a single-mode optical fiber at the input of a multimode optical fiber transmission line, a differential mode delay diagram is measured at its output. To do this, the optical signal receiver is connected through a single-mode optical fiber, the end of which is moved at the output of the multimode fiber optic transmission line along the end of the multimode optical fiber with a given step along the diameter of the multimode optical fiber, and at each step of the movement of the single-mode optical fiber at the output of the multimode fiber transmission lines measure the impulse response at the output of a multimode fiber optic transmission line on the impulse effect of a probing signal input at its input, and then, based on the set of measurement results of the impulse responses obtained at the same position of the optical fiber at the input, a differential mode delay diagram is constructed. Each of the obtained differential mode delay diagrams is compared with a template (diagram of allowable values of the differential mode delay) and, if for all measured differential mode delay diagrams the corresponding estimates of the differential mode delay do not exceed the allowable values specified by the template, the multimode optical fiber of the optical fiber transmission line is selected for work with a single-mode source of optical radiation.

This method requires a large amount of measurements and, as a result, a significant investment of time and resources, which is especially undesirable when installing transmission lines.

The essence of the invention is to reduce the time and volume of measurements.

This essence is achieved by the fact that the multimode fiber-optic transmission line is probed with short optical pulses of a single-mode optical radiation source, which is introduced into the multimode optical fiber of the multimode fiber-optic transmission line through a single-mode optical fiber, the end of which is transferred at the input of the multimode fiber-optic transmission line the end face of the multimode optical fiber with a given step along the diameter of the multimode optical fiber, measure the pulse response fiber of a multimode fiber-optic transmission line on the pulsed effect of the probing signal, a differential mode delay diagram is constructed from the set of measurement results of the impulse responses, which is compared with a diagram of allowable values of the differential mode delay, while the multimode optical fiber is connected to the element at the output of the multimode optical transmission line with a high reflection coefficient in the operating wavelength range, the optical signal receiver is connected to m A single-mode fiber-optic transmission line at its input through the same single-mode optical fiber as the source of optical radiation, and the pulse responses are measured at the input of a multi-mode fiber-optic transmission line, a differential mode delay diagram is constructed from the set of measurement results of the pulse responses and, if differential mode delay for a diagram constructed from the results of measurements of impulse responses do not exceed the corresponding estimates of the diagram of permissible differential values ntsialnoy modal delay multimode optical fiber of fiber optic transmission lines are selected for use with single mode source of optical radiation.

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

The device comprises a multimode fiber optic transmission line 1 with a multimode optical fiber 2, a single-mode optical fiber 3, a pulsed single-mode optical radiation source 4, a single-mode directional coupler 5, an alignment device 6, a photodetector 7, a measuring device 8, a storage, processing and display device 9, a device with a high reflection coefficient in the operating wavelength range of 10, while the end of the multimode optical fiber 2 at the output of the multimode fiber optic 1st transmission line 1 is connected to a device with a high reflection coefficient in the operating wavelength range of 10, a pulsed single-mode optical radiation source 4 is connected to the first output of the directional splitter 5, the second output of which is connected to the input of the single-mode optical fiber 3, and the third output of the directional splitter 5 to the input of the photodetector 7, the output of the single-mode optical fiber 3 using the alignment device 6 is connected to the input of the multimode optical fiber 2 of the multimode optical fiber transmission line 1, the output of the photodetector 7 is connected to the input of the measuring instrument 8, the output of which is connected to the input of the data storage, processing and display device 9.

The device operates as follows. The probe pulses from a pulsed single-mode optical radiation source 3 through a directional splitter 5 and a single-mode optical fiber 3 enter the multimode optical fiber 2 of the multimode fiber-optic transmission line 1, they are reflected at the output of the multimode fiber-optic transmission line 1 in a device with a high reflection coefficient in operating range of wavelengths 10. Reflected optical pulses along the multimode optical fiber 2 arrive at the near end of the multimode fiber optic transmission lines 1 and through a single-mode optical fiber 3 and a single-mode directional coupler 5 are fed to the input of the photodetector 7, in which they are converted into an electrical signal. Then, the electrical signal from the output of the photodetector 7 is fed to the input of the measuring instrument 8, which performs measurements of impulse responses, and the measurement data of the pulse responses from the output of the measuring instrument 8 are fed to the input of the data storage, processing and display device 9. The alignment device 6 moves the end face of the single-mode optical fiber 3 at the end of the multimode optical fiber 2 along the diameter of the multimode optical fiber 2 with a given step, and at each step, the measurement tool The impulse response is measured, and the data storage, processing and display device 9 stores the impulse response measurement data for each step, constructs a differential mode delay diagram from it, compares it with a diagram of allowable differential mode delay values and displays the obtained comparison results.

In contrast to the known method, which is a prototype, the input / output of pulsed signals into a multimode optical fiber is performed through the same single-mode optical fiber at the input of a multimode fiber-optic transmission line, which reduces the number of measured responses to the pulsed action by m times, where m is the number of steps of moving a single-mode optical output of a multimode fiber-optic transmission line for the prototype. This reduces the time and volume of measurements during the implementation of the proposed method in comparison with the prototype. In addition, the pulses from the pulsed optical source to the photodetector, in contrast to the known method, which is the prototype, travel twice as long, which almost doubles the delay between the pulses of the mode components in a multimode optical fiber and, accordingly, increases the sensitivity and reduces the measurement error in comparison with the prototype, which, in the end, also reduces the total time for the selection of multimode fibers for working with single-mode optical radiation sources at instal yatsii multimode fiber optic transmission line.

LITERATURE

1. EIA / TIA-455-204 (FOTP-204) Measurement of bandwidth on multimode fiber. - 2000.

2. RML laser bandwidth measurement as per TIA-EIA 455-204 and IEC 60793-1-41.

3. US 6,788,397.

Claims (1)

A method for selecting multimode optical fibers of a fiber optic transmission line for operating with a single-mode optical radiation source, the method being that the multimode fiber optic transmission line is probed with short optical pulses of a single-mode optical radiation source that are introduced into a multimode optical fiber of a multimode optical fiber through a single-mode optical fiber, the end of which is moved at the input of the multimode fiber-optic transmission line along the end multimode optical fiber with a predetermined step along the diameter of the multimode optical fiber, measure the impulse response of the optical fiber of the multimode fiber optic transmission line to the impulse effect of the probe signal, from the set of measurement results of the impulse responses construct a differential mode delay diagram, which is compared with a diagram of allowable values of the differential mode delay characterized in that the output of the multimode optical transmission line multimode opt The optical fiber is connected to an element with a high reflection coefficient in the operating wavelength range, the optical signal receiver is connected to a multimode fiber-optic transmission line at its input through the same single-mode optical fiber as the optical radiation source, and the pulse responses are measured at the input of the multimode fiber optical transmission line, based on the set of measurement results of the impulse responses build a diagram of the differential mode delay and, if the estimates of the differential mode delay d For the diagram constructed from the results of measurements of the pulse responses, they do not exceed the corresponding estimates of the diagram of permissible values of the differential mode delay, the multimode optical fiber of the fiber-optic transmission line is selected for operation with a single-mode source of optical radiation.