JPH0421827A - Optical fiber communication system - Google Patents

Abstract

PURPOSE:To obtain necessary amplification gain only by an optical fiber transmission line itself, to eliminate the need for an optical repeater, to simplify system constitution, and to reduce the cost of the system by using an amplifying optical fiber itself as the transmission line. CONSTITUTION:A communication light source 1 is provided on the incident end of a signal light inputting optical fiber 2, an exciting light source 3 such as a semiconductor laser LD for projecting exciting light is provided on the incident end of an exciting light inputting optical fiber 4, a long amplifying optical fiber 7 constituted as a transmission amplifying line is connected to a multiplier 5 through an optical connector 6 and the other end is connected to a multiplier 11 through an optical connector 10. Since the fiber 7 having a core part in which Er (erbium) is doped in a 0.01 to 1ppm low concentration state is used for the whole optical fiber transmission line or a large part of it, necessary amplification gain can be secured only by the transmission line itself. Consequently, the need for an optical amplifier to be used only for amplification can be eliminated, the system constitution can be simplified and the reduction in the cost can be attained.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to an optical fiber communication system for transmitting information in the form of light via a long optical fiber.

<Prior art> In optical fiber communication systems currently in practical use, optical repeaters dedicated to amplification are interposed at predetermined distances to compensate for signal light attenuation due to loss in the optical fiber transmission line. ing. The optical repeater converts an optical signal into an electrical signal using an O/E element such as a photodiode, amplifies it using an electronic amplifier, and then converts it into an electrical signal using a semiconductor laser (LD).
The signal is converted into an optical signal by an E10 element such as E10, and sent out again to the optical fiber transmission line.

This optical repeater converts an optical signal into an electrical signal and then
In order to convert the signal back into an optical signal, there are problems such as increased noise, large loss in connection with the optical fiber, and an increase in the size of the device.

Therefore, a fourth method using an optical fiber with a stimulated emission effect was developed.
An optical amplifier A as shown in the figure has been proposed. This optical amplifier A consists of an amplification optical fiber a doped with Er (erbium) at a concentration of about 11,000 pp and a length of about 10 m, and an optical fiber transmission line e1 on the upper side and an optical fiber transmission line e1 on the lower side. Optical fiber transmission line e2
optical connectors b, b2 for connecting to the amplification optical fiber a, a pumping light source C such as a semiconductor laser that pumps Er in the amplification optical fiber a, and a signal light and pumping light source transmitted via the optical fiber transmission line e1. A multiplexer d that mixes the excitation light from C.
It is equipped with

The signal light and pump light mixed by the multiplexer d are connected to the optical connector b.
1, the Er in the amplification optical fiber a is excited by the excitation light to a high energy unit, and the signal light is amplified by stimulated emission.

If such an optical amplifier A is used, it is possible to directly amplify an optical signal in its optical state without converting it into an electrical signal, resulting in low noise and a There are advantages in that there is little loss in connection with the transmission line el+82, and the device can be made smaller and less expensive.

<Problem to be solved by the invention> The overall transmission distance of the optical fiber communication system is long (indeed, the attenuation of the signal light is large, but in order to compensate for this, the optical fiber transmission system is There is no change in the fact that an optical amplifier A as described above must be inserted at each predetermined distance of the line e.
There are of course certain limits to lowering prices.

The present invention has been made in view of these circumstances, and instead of using an amplification optical fiber that directly amplifies signal light by stimulated emission as an element of an optical amplifier constituting an optical repeater. By using the amplifying optical fiber itself as an optical fiber transmission line, it is possible to obtain the necessary amplification gain on the line itself, eliminating the need for optical repeaters and simplifying and reducing the cost of the system configuration. The purpose is to achieve this goal.

Conventionally, the amplification optical fiber, which has been understood as an element of an optical amplifier as an optical repeater, has a short length of about 10 m at most, and the Er concentration required to obtain a predetermined amplification gain is It has been common knowledge that the core of the optical fiber has a high concentration of about 11,000 pp.

It has never been considered to use such a short amplification optical fiber as an optical fiber transmission line.

However, according to recent research by the present inventor, it is possible to lower the E r 974 degrees doped into the core of the optical fiber.
The longer the length of optical fiber used, the more
It was found that the amplification gain was increased.

Means for Solving the Problems> An optical fiber communication system according to the present invention provides a pumping light source and a pumping light source at least at the sending end of the sending end and the receiving end of an optical fiber transmission line. a multiplexer that mixes the excitation light and the signal light, and all or most of the optical fiber transmission line,
The present invention is characterized by using an amplification optical fiber having a core doped with Er (erbium) at a low concentration of 0.01 to 1 ppm.

<Operation> In the present invention, the lower limit of the degree of ErflJ for doping is set to 0.
．． 01 ppm, and the upper limit is 1 ppm. This makes it possible to make the amplification gain sufficiently high, and the amplification optical fiber is not used as an element of an optical amplifier constituting an optical repeater, but as an optical fiber transmission line. Now it can be used as a transmission amplification line that occupies all or most of the area.

Note that if the excitation light source and the multiplexer are also provided at the receiving end of the optical fiber transmission line, a much higher amplification gain can be obtained, so the transmission distance can be further extended.

<Example> Examples of the present invention will be described in detail below.

FIG. 1 is a schematic configuration diagram of an optical fiber communication system according to an embodiment of the present invention.

A communication light source 1 such as a light emitting diode or a semiconductor laser (LD) that emits PCM-modulated signal light in a wavelength band of 1.55 μm is provided at the input end of an optical fiber 2 for inputting signal light. An excitation light source 3 such as a semiconductor laser (LD) that emits excitation light in a wavelength band of 1.48 μm is provided at the input end of an optical fiber 4 for inputting excitation light. The signal light input optical fiber 2 and the excitation light input optical fiber 4 are connected via a multiplexer 5.

A long amplification optical fiber 7 configured as a transmission amplification line is connected to the multiplexer 5 via an optical connector 6, and the other end of this amplification optical fiber is connected to a multiplexer 11 via an optical connector 10. has been done.

Excitation light source 12 that emits excitation light in a wavelength band of 1.48 μm
is provided at the input end of the excitation light input optical fiber 13.

The pump light input optical fiber 4 at the transmitting end of the optical fiber transmission line 9 inputs the pump light into the amplification optical fiber 7 along the transmission direction of the signal light, whereas the optical fiber transmission line 9 Optical fiber 13 for pumping light input at the receiving end of 9
The excitation light enters the amplification optical fiber 7 in a direction opposite to the transmission direction of the signal light, and from the stage when the excitation light enters the amplification optical fiber 7, Er is pumped to exert an amplification effect. .

The output fiber 8 of the multiplexer 1 is provided with a filter 14 that passes only the wavelength component of the signal light and removes the excitation light, and the signal light that has passed through the filter 14 is sent to a receiving photoelectric conversion element such as a photodiode. 15.

The amplification optical fiber huff may be a mated optical fiber or a convex optical fiber. A matt type optical fiber consists of a core and a cladding around the core.
It is doped. A convex type optical fiber is composed of a center core, side cores on the outer periphery of the center core, and a cladding on the outer periphery, and the center core is doped with Er. Note that a convex type optical fiber is more preferable because it allows better controllability of the zero dispersion wavelength.

Next, the operation of the optical fiber communication system of this embodiment will be explained.

Pumping light in the 1.48 μm band emitted from the pumping light source 3 at the transmitting side end is transmitted in the forward direction (
signal light transmission direction). In addition, the excitation light in the 1.48 μm band emitted from the excitation light source 12 at the receiving end is as follows:
Pumping light input optical fiber 131 multiplexer 11. The light is input into the amplification optical fiber 7 through the optical connector 10 in the opposite direction. The excitation light excites Er doped in the amplification optical fiber 7 (pumping).

In this case, the pumping effect remains the same regardless of whether the pumping light is incident on the amplification optical fiber 7 from either the forward or reverse direction.

When a 1.55 μm band signal light is emitted from the communication light source 1 in such an excited state and is input to the amplification optical fiber half via the signal light input optical fiber 21, the multiplexer 5, and the optical connector 6, This signal light is amplified by stimulated emission while traveling through the amplification optical fiber. and,
The amplified signal light reaches the filter 14 via the optical connector 102 and multiplexer 11, passes through the filter 14, enters the receiving photoelectric conversion element 15, and is demodulated into an electrical signal. The excitation light is cut by a filter 14.

Next, specific data will be shown when the amplification optical fiber 7 is a convex type optical fiber.

Add Er to the center core of convex type optical fiber, 5
Doping was performed to a concentration of ppm.

The center core diameter is 3μm, and the side core diameter is 10μm.
m, the diameter of the cladding is 125 μm.

The side core is made of pure quartz, and the relative refractive index difference between the center core and the side core is 0.65%, and the relative refractive index difference between the side core and the cladding is 0.15%. The zero dispersion wavelength at this time is 1.548 μm. Also, the cutoff wavelength λ. is 1.19 μm.

Amplification optical fibers with lengths of 9,370 m and 18,196 m with the above characteristics were amplified using pump light with a wavelength of 1°48 μm, and changes in amplification gain [dB] with respect to changes in pump light power [mW] were investigated. Ta. The results are shown in FIG. As is clear from the figure, the 9370 m long fiber (
In A), the pumping light power is approximately 8 mW, and the distance is 181.96 m.
In the fiber (B), the amplification gain and line loss are balanced at about 12.5 mW, and a lossless line is formed. Therefore,
It can be seen that if the Er)7% degree is the same, it is necessary to increase the pumping power according to the length of the amplification optical fiber.

Furthermore, looking at the graph of FIG. 2, it can be seen that the amplification gain of any of the amplification optical fibers shown by curves (A) and (B) becomes saturated no matter how much the pumping light power is increased. Let this saturated amplification gain be the maximum gain of the optical fiber of that length,
FIG. 3 shows a measurement of this change in maximum gain using E r tM degrees x length (p p m -m) of the optical fiber as a parameter.

According to the figure, the maximum gain peaks at about 16000 ppm-m.

-a, long-distance transmission refers to transmission over 10 km, and the attenuation of a practically used optical fiber line that does not impair Er is about 0.2 dB/km. Therefore, the line length is 10
km, the attenuation amount is 2 dB/10 km. other,
Even if the attenuation due to doped Er is taken into account, the distance is 10 km.
The total attenuation amount does not increase by 10 dB'a4a. Now, looking at Figure 3, the value of concentration x length to obtain the maximum gain that balances the line loss of 10 dB is 10010000 pp.
Therefore, it can be seen that when using an amplification optical fiber with an Er concentration of 0.5 ppm, a line length of 20 km may be used. Therefore, when designing a line with a length of 10 km for long-distance transmission, it is understood that the Er concentration may be set to ippm. In other words, 1
Erff1 exceeding ppm. High-temperature optical fibers are not practical for long-distance transmission.

On the other hand, if the Er91 degree is set to 1 ppm or less, the transmission distance becomes longer, but if the Er concentration is lowered too much, the maximum gain decreases. Furthermore, in order to stably perform long-distance transmission, the Er concentration must be at least 0.01 ppm. Note that the transmission distance at this time is 10''km.

Furthermore, in this embodiment, the zero dispersion wavelength is set to signal light wavelength band 1.
Since the relative refractive index difference and core diameter ratio between the center core and side core are appropriately determined so that the wavelength range is 1,49 to 1.60 μm centered on 55 μm, the lossless line length is sufficiently long. However, long-distance transmission without signal distortion is possible.

Note that the present invention is not limited to the above embodiments,
The multiplexer 11 on the receiving end side, the pumping light source 1] 1 2 and the pumping light input optical fiber 13 may be omitted, or the entire optical fiber transmission line 9 may be replaced by an Er-doped amplification optical fiber 7. Alternatively, a normal transmission optical fiber not doped with Er may be partially inserted between the optical connectors 6 and 10.

Further, in this embodiment, an optical fiber doped solely with Er is used, but it may also be doped with Er, etc. in addition to the optical fiber.

- Igbo q phrase <Effect of the invention> According to the present invention, the following effects are achieved.

That is, all or most of the optical fiber transmission line is
By using an amplification optical fiber doped with Er (erbium) at a low concentration of 0.01 to ippm as a transmission amplification line, the necessary amplification gain can be secured in the transmission amplification line itself. Therefore, the need for an optical repeater dedicated to amplification can be eliminated, thereby simplifying the system configuration and reducing the cost.

[Brief explanation of the drawing]

FIG. 1 is a schematic configuration diagram of an optical fiber communication system according to an embodiment of the present invention, FIG. 2 is a characteristic diagram of signal light amplification gain with respect to pumping light power, and FIG. 3 is Er? A characteristic diagram of the maximum amplification gain versus the product of M degree and transmission distance. Figure 4 is a configuration diagram of a conventional optical repeater dedicated to amplification. Figure 5 is a diagram showing the configuration of a conventional optical repeater for amplification. It is a configuration diagram of a state. 3.12... Pumping light source 5.11... Multiplexer 7... Optical fiber for amplification 9... Optical fiber transmission line

Claims (1)

[Claims] (1) A pumping light source and a multiplexer for mixing the pumping light from the pumping light source and the signal light are provided at least at the transmitting end of the transmitting end and the receiving end of the optical fiber transmission line. At the same time, all or most of the optical fiber transmission line contains 0.01 to 1 p of Er (erbium).
An optical fiber communication system characterized by using an amplifying optical fiber having a core doped with a low concentration of PM.