JPH03205929A - Optical repeater and optical repeating system - Google Patents

Abstract

PURPOSE:To obtain a compact optical repeater provided with a monitoring function by modulating an exciting light for amplifying an optical signal with a prescribed oscillation frequency and executing the loop-back. CONSTITUTION:For instance, when an input to an incoming repeating part 11 is interrupted, and the output of a main signal amplified from a fiber amplifier 13-1 is interrupted, a no-signal detecting circuit 27-1 outputs a control signal 28-1, and an optical shutter 29-1 sets an optical fiber 31-1 to a conduction state. Also, the oscillator 32-2 of an outgoing an outgoing repeating part 12 supplies the modulating signal 33-2 of a prescribed frequency to a fiber amplifier 13-2, and modulates the exciting light of a pump light source 17-2. A modulated optical signal outputted from the fiber amplifier 13-2 is supplied to a multiplexer 23-1 of the incoming repeating part 11 side through a demultiplexer 21-2 and the optical fiber 31-1, and transmitted to the incoming circuit from an output part 15-1. In such a manner, a fault such as a disconnection of a cable can be detected.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an optical repeater and an optical repeater system using a fiber amplifier, and particularly to an optical repeater and a pre-relay system for searching for a failure point.

[Conventional technology]

In an optical fiber communication system, an optical repeater is used to relay optical signals propagating through an optical fiber, which is a transmission path.

Conventional optical repeaters used in such optical fiber communications first convert an optical signal into an electrical signal, regenerate and amplify it, and then convert it back into an optical signal and send it out. This has resulted in the disadvantage that the device is complicated and large. Therefore, optical fiber amplifiers have been proposed that make it possible to downsize optical repeaters. Optical fiber amplifiers directly amplify optical signals without converting them into electrical signals, thereby achieving miniaturization of optical repeaters.

[Problem to be solved by the invention]

Conventional optical relay devices that convert optical signals into electrical signals and perform relaying generally have a monitoring and control function. In other words, the optical repeater uses a redundant LD (
It is equipped with a laser diode switching function, various monitoring functions, and a loopback function for returning signals from one's own line to another line.

The control commands, monitor voltage, and other information necessary for these functions are electrically processed inside the optical repeater, so they are transmitted by performing mark rate modulation and phase modulation on the main signal. .

However, since the optical fiber amplifier does not convert the main signal into an electrical signal, it is extremely difficult to add such a monitoring function to the optical repeater. Particularly in the case of submarine transmission systems that involve many relays, adding a function to check the location of failures such as disconnections in cables has the drawback of increasing the size of the line. Therefore, even if an optical fiber amplifier is used, the optical repeater cannot be sufficiently miniaturized.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a compact optical repeater and an optical repeater system using an optical fiber amplifier that can detect failures such as disconnection of cables.

[Means to solve the problem]

The optical repeater according to claim 1 includes (i) input means for inputting optical signals transmitted through an optical fiber upstream line and a downstream line, respectively; or (iii) an optical signal amplification means for amplifying the optical signal input from one line of the downlink line using pumping light; and (iii) the amplified signal output from this optical signal amplification means is supplied to the other line to form a loop. (iv) optical signal disconnection detection means for detecting disconnection of the optical signal transmitted through the other line and outputting a disconnection detection signal; and (v) loopback means for transmitting the optical signal back to the other line. (vi) an optical blocking means that allows the amplified signal to be looped back to pass when the optical signal interruption detection signal outputted from the optical signal interruption detection means is supplied, and cuts it off when the optical signal interruption detection signal is not supplied; The apparatus further includes a modulating means for modulating the excitation light of the optical signal amplifying means at a predetermined frequency in response to the supply of the disconnection detection signal.

That is, the optical repeater according to the first aspect modulates the pumping light for amplifying the optical signal at a predetermined oscillation frequency and loops it back.

An optical relay system according to a second aspect of the present invention is a system in which a plurality of optical relay devices according to the first aspect are arranged, each of which modulates the excitation light at different frequencies.

〔Example〕

Hereinafter, the present invention will be explained in detail with reference to Examples.

FIG. 1 shows the configuration of an optical repeater according to an embodiment of the present invention.

The optical relay device includes an uplink relay unit 11 that performs optical relay for uplinks, and a downlink relay unit 1 that performs optical relay for downlinks.
2. Note that the uplink relay section 11 and the downlink relay section 12 have the same structure, so the uplink relay section 1 and the downlink relay section 12 are in the same part.
1 with the suffix "-1" and the downlink relay section 12 with the suffix "-2", and the description thereof will be omitted as appropriate.

The uplink relay unit 11 includes a fiber amplifier 13-1 that directly amplifies the optical signal. The input side of the fine noise amplifier 13-1 is connected to the input section 14-1 through an optical fiber. In addition, the output side of the fiber amplifier 13-1 is an output section 15.
-1 and is connected with an optical fiber. In this embodiment, the main signal input from the input section 14 and output from the output section 15 after being amplified by the fiber amplifier l3 is 1.5
It is assumed that the wavelength is in the 5 μm band.

The fiber amplifier 13-1 is a two-man powered first optical multiplexer 16.
-1. An optical fiber connected to the input section 14-1 and an optical fiber connected to the pump light source 17-l are connected to the input side of the first optical multiplexer 16-1, respectively. The pump light source 17-1 is equipped with a laser diode (LD) (not shown), and a bias current causes
It outputs excitation light in the 1.48 μm band.

One end of an Er-doped fiber 18-1 from which erpium with an atomic number of 68 has been extracted is connected to the output side of the first optical multiplexer l6-1. At the other end of this Er-doped fiber 18-1, there is an optical band pass filter (○BPF).
19-1 is connected. OBPF19-1 is composed of, for example, a monochromatic filter or an interference filter, and has a diameter of 1.55μ.
This is a filter that passes m main signals. ○BPF19
The main signal that has passed through the fiber amplifier 13-1 is output from the fiber amplifier 13-1, and is supplied to the output section 15-1 via the optical fiber.

The optical fiber that connects the fiber amplifier 13-1 and the output section 15-1 has a first fiber in order from the fiber amplifier 13-1 side.
A branching filter 21-1, a second branching filter 22-1, and a second multiplexer 23-1 are arranged. Second duplexer 22-
The main signal demultiplexed by I is supplied to the photodiode 24-1 through an optical fiber. Photodiode 24-1
receives the light from the main signal and supplies an electrical signal 26-1 to the no-signal detection circuit 27-1. No signal detection circuit 27-1
is the electric signal 2 supplied from the photodiode 24-1.
6-1 is detected and an electrical control signal 28-
It is designed to output 1.

The uplink relay unit 11 includes an optical shutter 29- that blocks optical signals.
1. The optical shutter 29-1 is connected to the uplink relay section 1
The optical fiber 31-1 is disposed in the middle of an optical fiber 31-1 that connects the second multiplexer 23-1 of the first multiplexer 23-1 and the first demultiplexer 21-2 of the downlink relay section 12. The optical shutter 29-l normally blocks the optical signal transmitted through the optical fiber 31-1, but allows the optical signal to pass when the control signal 28-l is supplied from the no-signal detection circuit 27-1. ing.

The uplink relay unit 11 includes an oscillator 32-1. The oscillator 32-1 is connected to the no-signal detection circuit 27- of the downlink relay section 12.
2 oscillates a modulation signal 33-1 of a predetermined frequency f-1. This modulation signal 33-l is supplied to the fiber amplifier 13-1 to modulate the bias current of the pump light source 171.

The downlink relay section 12 is configured similarly to the uplink relay section 11 described above. Note that the modulated signal 33 of the downlink relay section l2
The frequency of the modulated signal 33-2 that oscillates at -2 is f-2.

Next, the operation of the optical repeater configured in this manner will be explained.

First, normal operation will be explained. The input section 14-1 of the uplink relay section 11 is supplied with a main signal, which is a small optical signal having a wavelength in the 1.55 μm band. This main signal is
It is supplied to the fiber amplifier 13-1 via an optical fiber. The main signal supplied to the fiber amplifier l3-1 is sent to the Er-doped fiber 18 via the first optical multiplexer 16-1.
-1 and output from the pump light source 17-1.
．． It is amplified by excitation light in the 48 μm band. The amplified signal is supplied to BPF 19-1. ○BPF19-1
In this case, the main signal having a wavelength in the 1.55 μm band passes,
The main signal that has passed is output from the fiber amplifier 13-1. The main signal output from the fiber amplifier 13-1 is
The signal is output from the output section 15 via the first branching filter 21-1, the second branching filter 22-1, and the second multiplexer 23-1.

On the other hand, the main signal amplified by the fiber amplifier 13-1 is
The photodiode 24 is divided by the second duplexer 22-1.
-1. The photodiode 24-l receives the main signal and supplies an electrical signal 26-1 to the no-signal detection circuit 27-1. While this electric signal 26-1 is being supplied,
The control signal 28-1 is not output from the no-signal detection circuit 27. Therefore, the optical shutter 29-1 does not operate, and the downstream light split by the first branching filter 21-2 of the downstream relay section 12 is blocked. and is not supplied to the second multiplexer 23-1.

Similarly, the main signal split by the first branching filter 21-■ is
The light is blocked by the optical shutter 29-2 of the downlink relay section 12.

Next, the operation when the uplink input is interrupted will be described. When the input to the uplink relay section 11 is interrupted, the output of the amplified optical main signal from the fiber amplifier 13-1 is also interrupted. Note that the excitation light output from the bomb light source 17-1 is cut by the ○BPF 191, and
-1 is not output. When the output of the main signal from the fiber amble l3-1 is interrupted, the photodiode 24-1 does not receive the main signal from the second branching filter 22-1.

Therefore, the electrical signal 26-1 is not supplied to the no-signal detection circuit 271. The no-signal detection circuit 27-1 detects the electrical signal 26-
1 and supplies the control signal 28-1 to the optical shutter 29-1.

The optical shutter 29-1 operates upon receiving the control signal 28-1, and makes the optical fiber 31-1 optically conductive.

Further, the control signal 28-1 is supplied to the oscillator 32-2 of the downlink relay section 12 to operate the oscillator 32-2. The oscillator 32-2 generates a modulated signal 3 at a predetermined frequency f-2.
3-2 as the pump light source 17-2 of the fiber amplifier 13-2
is supplied to modulate the bias current of the excitation light of the pump light source 17-2.

By modulating the pumping light with the modulation signal 33-2, a modulated optical signal is output from the fiber amplifier 13-2. This modulated optical signal is sent to the first demultiplexer 21-
2, passes through the optical shutter 29-1 via the optical fiber 31-1, and is sent to the second multiplexer 2 on the uplink relay section 11 side.
3-1. In the second multiplexer 23-1, the modulated optical signal is outputted from the output section 15-1 and transmitted through the uplink.

Here, when a plurality of optical repeaters are arranged, the frequency f-2 of the modulated signal 33-2 oscillated by the oscillator 32-2 is set to a different value for each optical repeater. In a terminal device (not shown), by measuring the oscillation frequency of the looped back optical signal, it is possible to easily confirm at which relay point a failure has occurred.

On the other hand, when the downlink input is interrupted, the uplink optical signal modulated by the oscillation of the oscillator 32-1 is transmitted to the first demultiplexer 21-1, the optical shutter 29-2, and the The signal is looped back to the downlink via the second sonicator 23-2. In this case, the oscillator 32-1 has an oscillation frequency f-
1, and is distinguished from failures in the upstream direction.

In the embodiments described above, the excitation light of the pump light source has a wavelength in the 1.48 μm band, and the main signal transmitted by the Er-doped fiber with a wavelength in the 1.55 μm band is amplified. It is not limited to this,
For example, any structure that can directly amplify the main signal using electric or optical bias means may be used.

〔Effect of the invention〕

As described above, according to the invention as claimed in claim 1, since the pumping light for amplifying the optical signal is modulated at a predetermined oscillation frequency and looped back, a compact optical repeater equipped with a monitoring function can be realized. can be provided.

Further, according to the invention as set forth in claim 2, since the excitation light is modulated at different frequencies, it is possible to easily discover the section where the fault has occurred. Therefore, repairs can be carried out quickly and the reliability of optical fiber communication can be improved.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing the structure of an optical repeater according to an embodiment of the present invention. 13-1, 13-2...Fiber amplifier, 17
-1, 17-2...Pump light source, 18-1, 1
8-2-----Er-doped 77 Iba, 19-1, l
9-2...○BPF, 24-1, 24-2...
...Photodiode, 27-1, 27-2...
...No signal detection circuit, 29-1, 29-2...
Optical shutter, 32-1, 32-2...Oscillator.

Claims (1)

[Scope of Claims] 1. Input means for inputting optical signals transmitted through an uplink line and a downlink line by optical fibers, respectively; and this input means allows one of the uplink line or the downlink line to be input. an optical signal amplifying means for amplifying an optical signal inputted from the line using excitation light; a loopback means for supplying the amplified signal output from the optical signal amplifying means to the other line and looping it back; optical signal disconnection detection means for detecting disconnection of an optical signal transmitted through a line and outputting a disconnection detection signal; and optical signal disconnection detection means for detecting an amplification signal that is looped back to the other line by the loopback means an optical cutoff means for passing the cutoff detection signal outputted from the optical signal cutoff detection means when it is supplied and shutting it off when the cutoff detection signal is not supplied; 1. An optical repeater comprising: modulation means for modulating excitation light at a predetermined frequency. 2. An optical repeater system, characterized in that a plurality of optical repeaters according to claim 1 are arranged, and the frequency at which the excitation light is modulated by the modulator is set to a different frequency for each optical repeater.