RU2624770C2 - Method of leveling mode connection in optical fibers on building length of optical cable of modular construction with multimode or small-mode optical fibers - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: according to the method for levelling the mode connection in optical fibers on the construction length of a modular optical cable with multimode or low-mode optical fibers, the construction length of the optical cable on the drum is placed in a climatic chamber and subjected to temperature cycles, during each temperature cycle, the set values of the negative temperature are reduced and then successively raised to the set values of the positive temperature, then the cycle is terminated, with each set temperature value being set for a predetermined time interval.

EFFECT: expanding the application field.

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Description

The invention relates to the field of electrical engineering and can be used to equalize mode coupling in optical fibers along the construction length of a modular design optical cable with multimode or low-mode optical fibers.

It is known [1, 2] that in order to reduce stresses in the optical fibers of an optical cable with external tensile loads on the cable, the optical fibers are laid in modular tubes of an optical cable with an excess length — the length of the optical fibers exceeds the length of the modular tubes. As a result, optical fibers are arranged in modular tubes along trajectories close to the helicoid, with bends. The bending radii of the optical fibers vary randomly along the length of the optical cable and, since the excess length of the optical fiber in the module increases with decreasing temperature, the average value of the bending radius on the building length of the optical cable decreases with decreasing temperature [1-3]. It is known that the parameters of the modes on the bends of the optical fiber, in particular, the propagation constant and the radius of the mode spot, depend on the bending radius [4]. As a result, at the junctions of optical fiber sections with different bending radii, mode coupling takes place. Moreover, since the bending radii of the optical fibers vary randomly along the cable and depend on the temperature, the mode coupling due to them in the optical fibers of the optical cable is random and depends on the ambient temperature. The coupling of modes in optical fibers of an optical cable, its random nature and temperature dependence limit the use of optical cables with small-mode and multimode optical fibers on long-distance communication lines, although these optical fibers are promising from the point of view of overcoming the non-linear Shannon limit [5-9]. With strong mode coupling, when the line length exceeds the length of the mode coupling correlation interval, which is typical for long-distance communication lines, as in the case of polarization mode dispersion, the differential mode delay is proportional not to the line length, but to the square root of the line length. It follows that in order to reduce the negative influence of mode coupling on the quality of signal recovery at reception of long cable lines, it is necessary to stabilize the changes in the mode coupling coefficients, reducing the spread of the values of the bending radii of optical fibers along the length of the optical fiber and during temperature fluctuations.

A known method [10] alignment of the transmission parameters of the optical fiber in bends by selecting the profile of the refractive index of a multimode or low-mode optical fiber. This method allows you to minimize additional loss in bending and thereby stabilize the attenuation coefficient. However, it does not ensure the stability of the differential mode delay characteristics and mode coupling coefficients.

Known methods [11-12] for aligning the parameters of optical fibers by adjusting the excess length of the optical fiber in a modular tube in the manufacturing process of the optical cable modules. Typically, a module includes 4, 8, or 12 optical fibers. The relative position of the optical fibers in the modular tube limits the alignment of the bending radii of the optical fiber along the length of the cable. The scatter in the values of the bending radii is greater, the more optical fibers in the module. In addition, in the future, in the process of manufacturing the building length, the excess length of the optical fiber in the module can change [13-14], and consequently, the distribution of the bending radii of the fibers along the cable length and the parameters of the optical fiber can also change. All this limits the scope of these methods for aligning mode coupling in optical fibers along the construction length of a modular design optical cable with multimode or low-mode optical fibers.

A known method of smoothing the attenuation of an optical fiber by selecting the construction lengths of the optical cable that meet the requirements for the stability of attenuation when exposed to temperature cycles on the construction length of the optical cable, for this the construction length of the optical cable on the drum is placed in a climate chamber, previously before the temperature cycles in the climate chamber set a predetermined initial positive value of the temperature during each temperature cycle at the beginning, the temperature is successively lowered to the set values of the negative temperature, and then it is successively increased to the set values of the positive temperature, after which the cycle is completed, each set temperature is set for a predetermined time interval and the transition from one set value to another is performed for a predetermined time interval moreover, the number of temperature cycles, preset temperature values and preset time intervals are selected from the conditions that ensure the selection of construction x the length of the optical cable according to the stability of the attenuation of the optical fibers in the given operating conditions. The disadvantages of this method from the point of view of alignment of mode coupling in optical fibers along the construction length of an optical cable of a modular design with multimode or low-mode optical fibers include the following. First, the attenuation stability does not guarantee the stability of the coupling of modes in optical fibers along the construction length of a modular design optical cable with multimode or low-mode optical fibers. Secondly, with a relatively large number of optical fibers in the optical cable module, the stability of the transmission parameters of the optical fiber is limited due to the relative position of the fibers. And finally, this method allows you to select optical fibers with a given stability of attenuation, but not to increase the stability of the transmission parameters of optical fibers in an optical cable. These disadvantages limit the scope of this method for aligning the mode coupling in optical fibers along the construction length of an optical cable of a modular design with multimode or low-mode optical fibers.

The essence of the invention is the expansion of the scope.

This essence is achieved by the fact that according to the method for aligning the mode coupling in optical fibers on the construction length of a modular optical cable with multimode or low-mode optical fibers, the construction length of the optical cable on the drum is placed in a climate chamber and exposed to temperature cycles, during each temperature cycle, first the temperature is successively reduced to the set values of the negative temperature, and then it is successively increased to the set values positive temperature, after which the cycle is completed, each set temperature value is set for a predetermined time interval and the transition from one set value to another is performed within a specified time interval, while the number of optical fibers in the optical cable module is limited, after the modules are manufactured the optical cable on the coils is placed in a climate chamber and exposed to temperature cycles during each temperature cycle At first, the temperature is successively reduced to the set values of the negative temperature, and then successively increased to the set values of the positive temperature, after which the cycle is completed, and each set temperature is set for a predetermined time interval and the transition from one set value to another is performed for a predetermined time interval, the number of optical fibers in the optical cable module, the number of temperature cycles, set temperature values and set time intervals they are not selected from the conditions for ensuring a given scatter of estimates of the bending radii of optical fibers in the optical cable module at a given minimum temperature, then, after completion of technological operations for manufacturing the construction length of the optical cable, the construction length of the optical cable on the drum is placed in a climate chamber and exposed to temperature cycles, during the execution of each temperature cycle, first the temperature is successively lowered to the specified values at a negative rate atures, and then successively increase to set values of positive temperature, after which the cycle is completed, each set temperature is set for a specified time interval and the transition from one set value to another is performed during a set time interval, the number of temperature cycles, set values temperatures and specified time intervals are selected from the conditions for minimizing the spread of the bending radii of the optical fibers in the modules along the construction length of the optical cable when temperature.

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

The device comprises a climate chamber 1, optical cable modules with optical fibers 2 on coils 3, a building length of optical cable 4 on reel 5. Moreover, either optical cable modules with optical fibers 2 on coils 3 are placed in climate chamber 1, or a construction length of optical cable 4 on the drum 5 is placed in the climate chamber 1.

The device operates as follows. Preliminarily limit the number of optical fibers in the optical cable modules with optical fibers 2. After manufacturing the optical cable modules with optical fibers 2, the optical cable modules with optical fibers 2 on the coils 3 are placed in the climate chamber 1 (Fig. 1a). By changing the temperature in the climate chamber 1, the optical cable modules with optical fibers 2 on the coils 4 are exposed to temperature cycles. The number of optical fibers in the modules of the optical cable with optical fibers 2 and the parameters of the temperature cycles are selected from the conditions for providing a given range of estimates of the bending radii of the optical fibers in the modules of the optical cable with optical fibers 2 at a given minimum temperature. Then, after making the construction length of the optical cable 4, the construction length of the optical cable 4 on the drum 5 s is placed in the climatic chamber 1 (Fig. 1b). By changing the temperature in the climate chamber 1, the construction length of the optical cable 4 on the drum 5 is subjected to temperature cycles. The number of temperature cycles, the set temperature values and the set time intervals are selected from the conditions for minimizing the spread of the bending radii of the optical fibers in the optical cable modules with optical fibers along the construction length of the optical cable 4 with a change in temperature.

In contrast to the known method, which is a prototype, the number of optical fibers in the optical cable modules is limited from the conditions for providing a given spread of estimates of the bending radii of optical fibers in the optical cable modules at a given minimum temperature, which can reduce the restrictions on controlling the spread of bending radius due to the relative position optical fibers in modular tubes. Previously, the modules of the optical cable after their manufacture are subjected to the influence of temperature cycles, the parameters of which are selected so as to provide a given spread of estimates of the bending radii of the optical fibers in the optical cable modules at a given minimum temperature. Due to the multiple changes in the excess length of optical fibers in the modules, the packing of optical fibers in the modules in the fiber bundle becomes more uniform and the spread of the bending radii of the optical fibers along the length of the module is reduced, which ensures alignment of mode bonds in low-mode and multimode optical fibers in the optical cable modules compared to prototype. After making the construction length of the optical cable with these modules, it is exposed to temperature cycles, the parameters of which are selected from the conditions for minimizing the spread of the bending radii of the optical fibers in the modules on the building length of the optical cable with temperature. After multiple changes in the excess length of the optical fibers, the optical fibers are more evenly distributed along the length of the modular tube. This allows you to partially compensate for the influence of technological operations in the production of optical cable, performed after the manufacture of the modules, on the excess length of the optical fibers and, accordingly, the distribution of the bending radii of the optical fibers along the construction length of the optical cable. As a result, the spread of mode coupling coefficients is reduced compared to the prototype. Thus, the claimed method provides improved compared with the prototype, the stabilization of mode bonds in optical fibers on the construction length of the optical cable of a modular design with multimode or low-mode optical fibers.

LITERATURE

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Claims (1)

The method of aligning the mode coupling in optical fibers on the building length of a modular optical cable with multimode or low-mode optical fibers, which means that the building length of the optical cable on the drum is placed in a climate chamber and subjected to temperature cycles, during each temperature cycle, the temperature is first consistently lowered to preset values of negative temperature, and then sequentially increased to preset values of positive temperature, after which the cycle is completed, each set temperature value is set for a predetermined time interval and the transition from one set value to another is performed for a predetermined time interval, characterized in that the number of optical fibers in the optical cable module is limited, after manufacturing the optical cable modules on the coils are placed in a climate chamber and exposed to temperature cycles, in the process of performing each temperature cycle first the temperature is successively reduced to the set values of the negative temperature, and then successively increased to the set values of the positive temperature, after which the cycle is completed, and each set value of the temperature is set for a given time interval and the transition from one setpoint to another is performed for a given time interval, at In this case, the number of optical fibers in the optical cable module, the number of temperature cycles, preset temperature values and preset time intervals they shave from the conditions for ensuring a given spread of estimates of the bending radii of optical fibers in the optical cable module at a given minimum temperature, then after completion of technological operations for the production of the optical cable construction length, the optical cable construction length on the drum is placed in a climatic chamber and subjected to temperature cycles during each temperature cycle, first the temperature is successively lowered to the set values of the negative temperature, and then successively increase to set values of positive temperature, after which the cycle is completed, each set temperature value is set for a given time interval and the transition from one set point to another is performed during a set time interval, the number of temperature cycles, set temperature values and the specified time intervals are selected from the conditions for minimizing the spread of the bending radii of the optical fibers in the modules on the construction length of the optical cable when the tempo changes Aturi.

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