JPH11150510A - Optical soliton transmission line - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the optical soliton transmission line through which an optical soliton pulse signal is sent stably for a long distance. SOLUTION: In a first block, abnormal dispersion is applied to an optical fiber 11, normal dispersion is applied to a dispersion compensation device 21 and the mean dispersion in total of the above two is set to become normal dispersion. In a 2nd block, abnormal dispersion is applied to an optical fiber 12, normal dispersion is applied to a dispersion compensation device 22 and the mean dispersion in total of the above two is set to become abnormal dispersion. The 1st and 2nd blocks are connected to form one system and pluralities of the systems are provided in succession to prevent deterioration in an optical soliton pulse signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transmission line. More specifically, the present invention relates to an optical soliton transmission line.

[0002]

2. Description of the Related Art Optical soliton transmission is an optical transmission system that has been receiving attention in recent years. A general configuration for transmitting an optical soliton pulse signal on an optical fiber transmission line is to connect a dispersion compensating device to an optical fiber transmission line having large chromatic dispersion. That is, dispersion compensation is performed by a compensation device having a chromatic dispersion value whose sign is opposite to the chromatic dispersion value generated in the optical fiber transmission line. Therefore, the soliton effect is maintained by obtaining a predetermined average dispersion value. An example of such a configuration is described in Yamada et al., "10 Gb / s-10,600 using 1.3 μm SM fiber using dispersion compensation technology.
Km Optical Soliton Transmission ", 1997 IEICE Communications Society Conference, 1997.

[0003]

Incidentally, it is difficult to perform the same dispersion compensation on all the fiber transmission lines in the transmission line when applied to an actual system regardless of the experimental system. Further, when trying to maximize the transmission distance of an optical soliton signal, it may not be optimal to perform the same dispersion compensation on all fiber transmission lines.

[0004]

Accordingly, the present invention provides an optical soliton transmission line comprising an optical fiber transmission line for transmitting an optical soliton pulse signal and a compensating means for performing dispersion compensation of the optical soliton pulse. In the above, dispersion compensation is performed by connecting a first section in which the average dispersion of the optical repeater section is normal dispersion and a second section in which the average dispersion of the optical repeater section is abnormal dispersion.

[0005]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an optical transmission line to which the present invention is applied. The transmission line to which the present invention is applied connects the transmission station 1 and the reception station 2 by an optical fiber transmission line. Optical fiber transmission lines include
Optical amplifiers are inserted at predetermined intervals.

A first optical fiber 11 is connected to the transmitting station 1. Subsequent to the first optical fiber 11, a first dispersion compensator 21 is connected. Subsequent to the first dispersion compensator 21, a first optical amplifier 31 is connected.

[0007] The second optical fiber 21 is connected to the first optical amplifier 31. Subsequent to the second optical fiber 12, a second dispersion compensator 22 is connected. Subsequent to the second dispersion compensator 22, a second optical amplifier 32 is connected. The second optical amplifier 32 is connected to the receiving station 2
It is connected to the.

As the optical fibers 11 and 12, a single mode optical fiber (SMF) is used here. Further, one having anomalous dispersion in wavelength dispersion is used. The dispersion compensators 21 and 22 have normal dispersion. The dispersion compensator uses a dispersion compensation fiber, a dispersion compensation fiber grating, a dispersion compensation etalon, and the like. Hereinafter, the relationship between the chromatic dispersion of each optical fiber and each dispersion compensator will be described.

FIG. 2 is a diagram for explaining the state of chromatic dispersion of the optical fiber transmission line according to the present invention. This optical fiber transmission line includes a first section, that is, a section including the first optical fiber 11, the first dispersion compensator 21, and the first optical amplifier 31, and a second section, that is, the second section, that is, the second section. Optical fiber 12, second dispersion compensator 22, and second optical amplifier 3
2 are divided into sections.

First, in the first section, the first optical fiber 1
The section 1 has anomalous dispersion, and the first dispersion compensator 21 sets the dispersion as normal. Here, the total amount of chromatic dispersion (abnormal dispersion amount) of the first optical fiber 11 and the normal dispersion amount of the first dispersion compensator 21 are equal to the first dispersion compensator 2.
The normal dispersion amount of 1 is set large. As a result, the section variance of this section is slightly overcompensated as shown by the dashed line (a) in FIG.

Next, in the second section, the second optical fiber 1
The normal dispersion amount of the second dispersion compensator 22 is set to be small between the total chromatic dispersion amount of the second dispersion compensator 2 and the normal dispersion amount of the second dispersion compensator 22. As a result, the section variance of this section is slightly under-compensated as shown by the dashed line (b) in FIG.

As a result, in the entire optical fiber transmission line, 2
As shown by the dashed line, the dispersion is slightly abnormal to satisfy the soliton condition. As described above, the transmission path is configured by combining the section where the dispersion compensation amount is excessive and the section where the dispersion compensation amount is insufficient.

Next, the state of an optical soliton pulse in the optical fiber transmission line of the present invention will be described with reference to FIG.
First, in the first section, the optical soliton pulse signal transmitted from the transmitting station 1 undergoes pulse spreading in the first optical fiber having anomalous dispersion, and is input to the first dispersion compensator 21. If overcompensated here, the optical soliton pulse will have a pulse spread and up-chirp due to over-chirp.

When this is input to the second optical fiber 12, the up-chirped pulse is linearly compressed by the anomalous dispersion of the fiber 12, and has a pulse width close to the original pulse.

According to this embodiment, the optical pulse width hardly widens in a transmission line fiber of about 20 km from the optical amplifier where the nonlinear effect of light greatly affects.
Therefore, the overlap of the skirt between adjacent soliton pulses is small,
Waveform deterioration due to the optical nonlinear effect between adjacent soliton pulses is eliminated. Therefore, the optical soliton pulse can be transmitted over a longer distance.

It is also effective to insert an optical bandpass filter into the optical fiber transmission line. This filter is a band-pass filter that passes an optical signal band, and desirably has a smooth transmission / blocking characteristic.
Specifically, a Lorentz-type or Gaussian-type filter can be used.

Each time an optical soliton pulse signal passes through an optical fiber, a dispersion compensator or an optical amplifier many times, components other than its sideband components are generated in the transmission line fiber by an optical nonlinear effect (optical Kerr effect). Occurs in When this is accumulated, the original optical soliton waveform is deteriorated as a result. Therefore, by inserting an optical bandpass filter, it is possible to suppress the growth of such unnecessary components and to suppress the deterioration of the optical soliton pulse signal. Therefore, the optical soliton pulse signal can be stably transmitted over a long distance.

In the above embodiment, the case where the combination of the first section whose section average is normal variance and the second section whose section average is variance is described as one set. May be further repeated a plurality of times.

[0019]

As described above, according to the present invention, an optical soliton pulse signal can be transmitted more stably and over a longer distance.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of an optical fiber transmission line of the present invention.

FIG. 2 is a diagram illustrating a state of chromatic dispersion of an optical fiber transmission line according to the present invention.

FIG. 3 is a diagram illustrating a state of an optical soliton pulse in the optical fiber transmission line according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Transmitting station 2 ... Receiving station 11, 21 ... Optical fiber 21, 22 ... Dispersion compensator 31, 32 ... Optical amplifier

Claims (2)

[Claims] In an optical soliton transmission line comprising an optical fiber transmission line for transmitting an optical soliton pulse and a dispersion compensating means inserted into the optical fiber transmission line, the average dispersion of the optical repeater section is different from the normal dispersion. A first section,
An optical soliton transmission line that connects one unit to the second section where the average dispersion of the optical repeater section is anomalous dispersion. 2. The optical soliton transmission line according to claim 1, wherein one or more optical filters are inserted into said optical fiber transmission line.