JPH04160824A - System for monitoring optical repeater - Google Patents

Abstract

PURPOSE:To allow a reception side to monitor the state of each optical repeater by converting information to be monitored into an electric signal by an electric signal processing circuit, using a converter so as to modulate a subcarrier with the electric signal and using an amplitude modulator so as to apply amplitude modulation to a current flowing to a pump use laser diode with the subcarrier. CONSTITUTION:An optical signal from an optical transmitter through an optical repeater propagated through a transmission fiber 13 is fed to an photoelectric conversion element 14 via the transmission fiber 13, in which the signal is converted into an electric signal and the converted signal is amplified by an amplifier 15. Then a main signal is demodulated by a main signal demodulator 16 and an FSK signal from each optical repeater is modulated by FSK demodulators 18, 20, 22. That is, the FSK signal having a subcarrier whose frequency is f1 fed from an optical repeater is extracted from a band pass filter 17 whose center frequency is f1 and demodulated by an FSK demodulator 18. Thus, the state of each optical repeater is simultaneously monitored at a reception point based on the electric signal.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a monitoring system for optical repeaters using optical fiber type optical amplifiers.

(Prior Art) FIG. 2 is a block diagram of a conventional optical relay transmission system. The optical signal output from the optical transmitter 3 is transmitted through the transmission fiber 32.3.
4 and reaches the optical receiver 35, but the transmission fiber y
An optical repeater 33 is provided during transmission to compensate for transmission loss due to qsz and s4.

FIG. 3 is a block diagram showing an example of this optical repeater 33. In the figure, an optical signal propagated through a transmission fiber zse is converted into an electrical signal by an optical-to-electrical conversion element 37, sufficiently amplified by an amplifier 38, and then input to a signal processing circuit 39.

The signal processing circuit 39 encodes the information to be monitored in the repeater (optical repeater internal information) input from the terminal 42,
It is inserted into the bit array of the electrical signal from the amplifier 38 and output. The signal output from the signal processing circuit 39 modulates and drives an electric/optical conversion element 40 such as a laser diode (LD).

converted into an optical signal. This optical signal is sent to transmission fiber 4.

In this manner, the optical repeater converts the propagated optical signal back into an electrical signal, and the optical repeater information is inserted into the returned electrical signal before sending it to the optical receiver.

FIG. 4 is a block diagram showing a transmitting section of another example of the optical repeater 33 shown in FIG. 2, and FIG. 5 is a block diagram of a receiving section of an optical receiver corresponding thereto (" Proceedings of the Spring National Conference of the Institute of Electronics, Information and Communication Engineers, P4-99).

The transmission section of the optical repeater shown in Fig. 4 converts the transmitted optical signal into an electrical signal and directly modulates the LD 45 with the obtained main signal, and at the same time modulates the frequency with a signal representing the information inside the optical repeater. The LD 45 is amplitude-modulated with a low modulation degree using a sub-signal of a sub-carrier frequency subjected to shift keying (FSX) modulation, and an optical signal is sent out. In addition, 43 is an LD drive circuit (LDDRV), J4 is a monitor PD, and 46
is an amplitude modulator (PAM), and 47 is an LD bias current controller (BIASCONT).

The receiving section of the optical receiver shown in FIG. 5 demodulates the optical signal propagated through the transmission fiber with a photodetector module (APD module) 48, amplifies it with an amplifier (PRE) 49, and then outputs the main signal as the main signal. Signal demodulator (DEC) 51
At the same time, the subsignal of the FSX-modulated subcarrier frequency is taken out by a bandpass filter (S V FIL ) 53, which is FSK demodulated to obtain information within the optical repeater. This allows the receiving side to monitor the status of the optical repeater.

In addition, in FIG. 5, 50 is AGC anf (AGC
).

52 is a timing extraction circuit (TIM).

(Problem to be solved by the invention) However, all of the above optical repeater monitoring methods
It is an optical repeater that first converts the propagated optical signal into an electrical signal, then converts it back into an optical signal and sends it out.An optical repeater that uses an optical fiber type optical amplifier that directly amplifies the optical signal. cannot be applied to other monitoring methods.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an optical repeater monitoring method that allows the reception side to monitor the status of an optical repeater using an optical fiber type optical amplifier that directly amplifies an optical signal.

(Means for Solving the Problems) In order to achieve the above object, the present invention provides an optical repeater monitoring system in which the state of an optical repeater using an optical fiber type optical amplifier is monitored on the optical receiver side. and an electrical signal conversion circuit that converts information into electrical signals.

A modulator that modulates a subcarrier with a different frequency for each optical repeater using an electrical signal from the electrical signal conversion circuit, and a current in a pumping laser diode of the optical fiber type optical amplifier using the subcarrier from the modulator. an amplitude modulator for modulating the optical repeater; a bandpass filter for extracting the subcarrier from a signal obtained by demodulating an input optical signal; and a demodulator for demodulating the subcarrier from the bandpass filter and outputting an electrical signal. is provided in the optical receiver, and monitors the state of the optical repeater based on information to be monitored included in the electrical signal.

(Function) In an optical repeater, the information to be monitored is converted into an electrical signal by an electrical signal converting circuit, a subcarrier is modulated by this electrical signal by a converter, and a subcarrier is modulated by this subcarrier by an amplitude modulator. Amplitude modulation of the current flowing through the pump laser diode.

Therefore, the optical signal input to the optical repeater is amplified in the optical fiber type optical amplifier, and at the same time, sub-modulated in amplitude with the subcarrier, and output from the optical repeater.

In the optical receiver, after converting the arriving optical signal into an electrical signal, the subcarrier is extracted by a bandpass filter, and demodulated by a demodulator to obtain an electrical signal containing the information to be monitored. Therefore, the status of the optical repeater can be monitored at the receiving point based on this information.

Note that when there are a plurality of optical repeaters, each optical repeater can be monitored simultaneously by changing the frequency of the subcarrier for each optical repeater.

(Embodiment) FIG. 1 is a block diagram showing an embodiment of the present invention.
The figure is a block diagram of an example of an optical relay transmission system to which this embodiment is applied.

In FIG. 6, the optical signal output from the optical transmitter 54 is transmitted to the transmission fibers 55, 57, 59, 60 and the optical repeater 5.
6.58.60 to the optical receiver 62. Also, each optical repeater 56 , 58 .

60 amplifies the optical signals propagated through the transmission fibers 55, 57, and 59, and transmits the information in each optical repeater to the optical receiver 62 along with the optical signals to be relayed. On the receiving side, each optical repeater is monitored based on this information.

1(,) shows an embodiment of the optical repeater 56, 58, 60, and FIG. 1(b) shows an embodiment of the optical receiver 62, which will be described below.

The optical repeater shown in FIG. 1(,) consists of a transmission fiber 1. Wavelength multiplexing type Cassilla 2. Er-doped fiber 3.
Isolator 4. A part consisting of transmission fiber 5 and a pump LD for supplying stable pump light! 9. Monitor PDIO, output stabilization circuit 11. LD drive circuit 12
an electrical signal conversion circuit 6 for carrying the information in the optical repeater onto the optical signal, and an FSK modulator 7. It consists of a part consisting of an amplitude modulator 8.

Next, the operation of this embodiment will be explained. First, the LD for the pump
Information in the optical repeater that needs to be monitored, such as current and amplification 9, is converted into an electrical signal by an electrical signal converting circuit 6. The converted electrical signal is input to the FSX modulator 7, and the frequency is f
FSX modulate the i subcarrier. This subcarrier is assigned a different frequency for each optical repeater.
The optical repeater 56 shown in the figure has fl, and the optical repeater 58 has f.
2 is assigned to the optical repeater 59, and f3 is assigned to the optical repeater 59. The FSK modulated FSK signal is input to the amplitude modulator 8, which amplitude modulates the current flowing through the pump LD 9. Note that the monitor PDIO and output stabilizing circuit 11 are for stabilizing the light output from the pump LD 9. L for pump
The pump light from D9 is input to the Er-doped fiber 3 via the wavelength multiplexing coupler 2. On the other hand, the optical signal input from the transmission fiber 1 passes through the wavelength multiplexing coupler 2 and then passes through the wavelength multiplexing coupler 2.

The signal is input to the doping fiber 3 and amplified. The amplified optical signal is sent to the transmission fiber 5 via the isolator 4. Here, since the degree of amplification changes depending on the level of the pump light, the optical signal is amplified and at the same time is amplitude-modulated by the FSK signal containing the information inside the optical repeater, and the information inside the optical repeater is It is carried on an optical signal and sent to an optical receiver. Note that the modulation degree of this amplitude modulation is set within a range that does not degrade the transmission characteristics of the main signal.

The optical receiver shown in Fig. 1(b) has a transmission fiber of 13°.
Electric conversion element 14. Amplifier 15. Main signal demodulator 16. Bandpass filters 17, 19, 21, FSK demodulator 1
8, 20, and 22, and includes optical repeater internal information from optical repeaters 56, 58, and 60 shown in FIG.
It has the function of demodulating the K signal, and its operation is as follows.

The optical signal from the optical transmitter that has propagated through the transmission fiber and passed through the optical repeater is applied to the optical-to-electrical conversion element 14 via the transmission fiber 13, where it is converted into an electrical signal and then sent to the amplifier 1.
It is amplified by 5. The main signal is demodulated by the main signal demodulator 16, and the FSK signal from each optical repeater is demodulated by the FSK demodulators 1B and 20.22. That is, the FSX signal of the subcarrier with a frequency of 11 sent from the optical repeater 56 shown in FIG.
7 and demodulated by an FSK demodulator 18.

The frequencies sent from the optical repeaters 58 and 60 shown in FIG. 6 are respectively f2. Similarly, the FSX signal of the f5 subcarrier is extracted by the bandpass filter 19.21 and demodulated by the FSK demodulators 20 and 22. Since each of the demodulated electrical signals includes information to be monitored by the optical repeaters 56, 58, and 60, the status of each optical repeater can be simultaneously monitored at the receiving point based on this electrical signal.

Note that although the embodiment shown in FIG. 1(a) performs FSK modulation on the subcarrier, other modulation methods may also be used.

Furthermore, although the above embodiment is an example in which one pump LD is used, if a plurality of pump LDs are used, one or more of them may be amplitude-modulated with a subcarrier.

Furthermore, although the optical repeater transmission system shown in FIG. 6 has three optical repeaters, the number is not limited to this number.

In addition, although the embodiment shown in FIG. 1(b) is provided with the same number of FSK demodulators as each optical repeater, it is also possible to The number of 9 FSX demodulators may be reduced to one by switching the 9 FSX demodulators with a switch.

(Effects of the Invention) As described above in detail, according to the present invention, information to be monitored in an optical repeater used in an optical fiber type optical amplifier is sent to the receiving side by modulating the pump LD. This allows it to be sent completely independently of the main signal, and the status of all optical repeaters can be monitored simultaneously on the receiving side.

[Brief explanation of the drawing]

Fig. 1 is a block diagram of an embodiment of the present invention, Fig. 2 is a block diagram of a conventional optical repeater transmission system, Fig. 3 is a block diagram of a conventional optical repeater, and Fig. 4 is a block diagram of a conventional optical repeater. A block diagram of a transmitting section, FIG. 5 is a block diagram of a receiving section of a conventional optical receiver,
FIG. 6 is a block diagram of the optical relay transmission system of the embodiment. 1.5.13...Transmission fiber, 2...Wavelength multiplexing coupler, 3...E doped fiber, 4...Isolation, 6...Electrical signal conversion circuit, 7...FSK Modulator, 8... Amplitude modulator, 9... LD for pump, 10
...Monitor PD111...Output stabilization circuit, 12
...LD drive circuit, 15...Amplifier, 16...Main signal demodulator, 17r/19.21...Band filter,
18,20.22...FSK demodulator. Figure 2 PD f Shiba ice for 44t Nita. Transfer of large 4 abortion devices ↓ Scroll diagram No. 4
Garika? ) 10,000 selections

Claims (1)

[Claims] In an optical repeater monitoring system in which the status of an optical repeater using an optical fiber type optical amplifier is monitored on the optical receiver side, there is provided an electrical signal converting circuit that converts information to be monitored into an electrical signal; , a modulator that modulates a subcarrier with a different frequency for each optical repeater using an electrical signal from the electrical signal conversion circuit, and a current of a pumping laser diode of the optical fiber type optical amplifier using the subcarrier from the modulator. an amplitude modulator that modulates the input optical signal; a bandpass filter that extracts the subcarrier from a signal obtained by demodulating the input optical signal; and a demodulator that demodulates the subcarrier from the bandpass filter and outputs an electrical signal. A monitoring system for an optical repeater, characterized in that the optical receiver is provided with: and the state of the optical repeater is monitored based on information to be monitored included in the electrical signal.