KR102038376B1 - Optical signal measuring device Capable of measuring directional optical power and optical wavelength - Google Patents

Abstract

The present invention relates to an optical signal measuring apparatus capable of measuring a directional optical power and a wavelength of light, and more particularly, to combine two optical signals into a photodetector in a two-way transmission / receiving optical path without inputting the optical signals and input them into a photodetector. The present invention relates to an optical signal measuring apparatus capable of measuring optical power and simultaneously measuring optical wavelengths and directional optical power capable of analyzing optical wavelengths.
According to the present invention, two optical signals are combined into one photodetector in a bidirectional transmission / reception optical beam in a state where the optical signal is not switched, and then the optical wavelength can be analyzed and the optical wavelength can be analyzed simultaneously. Will provide a beneficial effect.

Description

Optical signal measuring device Capable of measuring directional optical power and optical wavelength

The present invention relates to an optical signal measuring apparatus capable of measuring directional optical power and optical wavelength, and more particularly, to combine two optical signals into a photodetector in a bidirectional transmission / receiving optical path without inputting the optical signals and input them into a photodetector. The present invention relates to an optical signal measuring apparatus capable of measuring optical power, and at the same time measuring directional optical power and optical wavelength.

As a prior art, there is an optical path automatic switching device for loopback optical power monitoring, which is Republic of Korea Patent Publication No. 10-0939349.

Specifically, as shown in FIG. 1, the bursa side switching part 30 and the remote side switching part 50 are divided, and the bursa side switching part 30 has two optical switches 31 and 32 and two tabs. Optocoupler (33, 34), two photodetectors (35, 36) and the control unit 37, the remote switching section 50 is a tab optocoupler 51, two 50:50 optocouplers (52) 54 and a directional optocoupler 53.

Referring to the optical path automatic switching method according to Fig. 1, first, the optical signal from the optical transmission device transmitting end Tx1 of the station side is transferred to the optical switch 31-the main optical path 61-the tab optical coupler 51-50: 50 optical coupler 52 is transmitted to the remote side optical transmitter end (Rx1), and similarly the optical signal from the remote side optical transmitter end (Tx2) is a 50:50 optocoupler (54)-the main optical path (62). Assuming that the tap optical coupler 34 is being transmitted to the station-side optical transmission apparatus receiver Rx2 through the optical switch 32, the optical power monitoring system for automatic switching is as follows.

The optical power from the transmitter side Tx1 is transmitted by the optical switch 31-the main optical path 61-the tap optical coupler 51-the directional optical coupler 53-the spare optical path 71-the tab optical coupler 33 Weakens through), but is detected by photodetector 1 (35), and likewise, optical power from the remote-side transmitter (Tx2) is weakened through 50:50 optocoupler (54) -tab optocoupler (34). But is detected by the photodetector 2 36.

Based on the light detected by the two photodetectors 35 and 36, the control unit 37 determines whether to transfer or not, and when the transfer is to be performed, the transfer control is performed by controlling the optical switches 31 and 32. .

In this case, the criterion for determining whether to transfer is when no light is detected by both photodetectors 35 and 36. In this case, the main optical paths 61 and 62, which become different optical cores in the same optical cable, fail. This is the case.

Looking at the optical signal transmission system after the transfer is made, the optical signal from the transmission side (Tx1) of the station side is the optical switch (31)-tap optical coupler (33)-spare optical path (71)-directional optical coupler (53)-50: 50 is transmitted to the remote receiving end (Rx1) through the optocoupler 52, the optical signal from the remote transmitting end (Tx2) is 50:50 optocoupler (54)-spare light (72)-optical switch (32) Is transmitted to the receiving side Rx2.

As described above, in the related art, optical power is measured through switching, and for this purpose, optical power for each optical signal is measured using two photodetectors 35 and 36 in a bidirectional transmission and reception optical line.

Therefore, a process of switching to measure the optical power is required, a complicated system structure design is required, and the associated cost increases, and there is no system to detect the optical wavelength. There was no way to determine if there was a problem with the wavelength.

As a result, in the present invention, in order to improve the above-mentioned problems, after combining two optical signals in a bidirectional transmission and reception optical beam into one and then input to the photodetector, the optical power is measured and at the same time directional light that can analyze the optical wavelength An optical signal measuring apparatus capable of measuring power and optical wavelength has been proposed.

Republic of Korea Patent Publication No. 10-0939349

Therefore, the present invention has been proposed in view of the above-described problems of the prior art, and an object of the present invention is to combine two optical signals into one photodetector in a two-way transmission / reception optical beam without changing the optical signals and input them into one photodetector. After that, the optical power is measured and at the same time the optical wavelength can be analyzed.

Specifically, in the state in which the optical signal is not transferred, the optical power of the first optical signal and the second optical signal is measured through the photodetector 300 or simultaneously, respectively, and the wavelength division filter forming optical coupler 200 is measured. By distinguishing the specific wavelength band, it is possible to distinguish whether the first optical signal or the second optical signal.

In order to achieve the problem to be solved by the present invention,

An optical signal measuring apparatus capable of measuring directional optical power and optical wavelength according to an embodiment of the present invention,

The first optical signal transmitted from the optical line terminal (OLT) 10 to the optical terminal device (ONU, 20) and the second optical signal transmitted from the optical network terminal device (ONU, 20) to the optical line terminal device (OLT, 10). A bidirectional optical splitter 100 which transmits the first optical signal and the second optical signal to the wavelength division filter forming optical coupler 200 without changing, and

An optical coupler (210) connected to the bidirectional optical splitter for providing a first optical signal and a second optical signal provided by the bidirectional optical splitter to the wavelength division filter unit; and

The wavelength division filter unit 220 is installed at the rear end of the optical coupler to distinguish one of the first optical signal and the second optical signal and transmit one of the first optical signal and the second optical signal to provide the photodetector to the photodetector. A wavelength division filter-forming optical coupler 200 configured to include;

By including a photodetector 300 for measuring the optical power of any one of the first optical signal and the second optical signal provided by the wavelength division filter formed optical coupler 200, the object of the present invention Will be solved.

Optical signal measuring apparatus capable of measuring the directional optical power and the optical wavelength according to the present invention having the above configuration and action,

In the state that the optical signal is not transferred, two optical signals are combined into one optical detector in a bidirectional transmission / reception optical beam, and then, the optical power is measured and the optical wavelength can be simultaneously analyzed. do.

1 is a block diagram showing an automatic optical path switching device for monitoring a conventional loopback optical power.
2 is an overall configuration diagram of an optical signal measuring apparatus capable of measuring directional optical power and optical wavelength according to an embodiment of the present invention.
3 is an exemplary view schematically showing an internal configuration of an optical signal measuring apparatus capable of measuring directional optical power and optical wavelength according to an embodiment of the present invention.

An optical signal measuring apparatus capable of measuring directional optical power and optical wavelength according to an embodiment of the present invention,

The first optical signal transmitted from the optical line terminal (OLT) 10 to the optical terminal device (ONU, 20) and the second optical signal transmitted from the optical network terminal device (ONU, 20) to the optical line terminal device (OLT, 10). A bidirectional optical splitter 100 which transmits the first optical signal and the second optical signal to the wavelength division filter forming optical coupler 200 without changing, and

An optical coupler (210) connected to the bidirectional optical splitter for providing a first optical signal and a second optical signal provided by the bidirectional optical splitter to the wavelength division filter unit; and

The wavelength division filter unit 220 is installed at the rear end of the optical coupler to distinguish one of the first optical signal and the second optical signal and transmit one of the first optical signal and the second optical signal to provide the photodetector to the photodetector. A wavelength division filter-forming optical coupler 200 configured to include;

And a photo detector 300 for measuring the optical power of any one of the first optical signal and the second optical signal provided by the wavelength division filter forming optical coupler 200.

At this time, the bidirectional optical splitter 100,

When the optical power transmitted from the optical line terminal (OLT, 10) to the optical terminal device (ONU, 20) and the optical terminal device (ONU, 20) to the optical line terminal device (OLT, 10) is set within the range of 99 to 80, The optical power transmitted to the wavelength division filter forming optical coupler 200 is set within a range of 1 to 20.

At this time, the bidirectional optical splitter,

It is characterized by a 2 X 2 form.

At this time, the optocoupler 210,

It is characterized by a 2 X 1 form.

At this time, the photodetector 300,

The optical power of the first optical signal and the second optical signal may be measured respectively or simultaneously.

At this time, through the wavelength-division filter-forming optical coupler 200,

By dividing a specific wavelength band, it is possible to distinguish whether it is a first optical signal or a second optical signal, and the optical power of the divided optical signal may be measured through the photodetector 300.

In addition, the optical signal measuring apparatus capable of measuring the directional optical power and optical wavelength of the present invention,

By combining the first optical signal and the second optical signal into one in the two-way transmission and reception optical path to one photodetector 300, the optical power can be measured through one photodetector.

Hereinafter, an embodiment of an optical signal measuring apparatus capable of measuring directional optical power and optical wavelength according to the present invention will be described in detail.

2 is an overall configuration diagram of an optical signal measuring apparatus capable of measuring directional optical power and optical wavelength according to an embodiment of the present invention.

3 is an exemplary view schematically showing an internal configuration of an optical signal measuring apparatus capable of measuring directional optical power and optical wavelength according to an embodiment of the present invention.

As shown in FIG. 2, the optical signal measuring apparatus capable of measuring the directional optical power and the optical wavelength according to an embodiment of the present invention includes a bidirectional optical splitter 100 and a wavelength division filter forming optical coupler 200. ) And the photodetector 300.

The two-way optical splitter 100 is a first optical signal transmitted from the optical line terminal (OLT, 10) to the optical terminal device (ONU, 20) and the optical line terminal (OLT, 10) from the optical terminal device (ONU, 20) The first optical signal and the second optical signal are transmitted to the wavelength separation filter forming optical coupler 200 at a predetermined ratio without switching the second optical signal transmitted to the second optical signal.

The set ratio is the optical power transmitted from the optical line terminal (OLT) 10 to the optical terminal device (ONU) 20, and the optical power transmitted from the optical terminal device (ONU) 20 to the optical line terminal device (OLT) 10 is in the range of 99 to 80. When set within, the optical power transmitted to the wavelength division filter-forming optical coupler 200 is set within a range of 1 to 20.

For example, when the optical power is set to 90: 10, when the optical power is 1 mW, the optical line terminal (OLT) 10 to the optical terminal unit (ONU, 20), and the optical terminal terminal (ONU, 20) to the optical line terminal ( The optical power transmitted to the OLT 10) is 0.9 mW, the optical power transmitted to the wavelength division filter formed optical coupler 200 should be 0.1 mW, and the optical power detected by the photodetector 300 should be 0.1 mW. It is determined that normal optical power is being transmitted.

However, if the optical power detected by the photodetector is 0.05 mW instead of 0.1 mW, it may be determined that a problem occurs in the optical power.

On the other hand, according to an additional aspect, the bidirectional optical splitter 100,

It is characterized by a 2 X 2 form.

That is, as shown in Figure 2, it is configured in the form of 2 X 2, the optical cable connected to the optical line terminal (OLT, 10) connected to the port P1, and the optical network termination device (ONU,) to the port P2 Connect the optical cable connected to 20).

At this time, the optical power is distributed at a set ratio. The optical power input to P1 is provided to P2, and some optical power is provided to P4.

Then, the optical power input to P2 is provided to P1, and some optical power is provided to P3.

In addition, as shown in Figure 2, the wavelength separation filter forming optical coupler 200,

An optical coupler (210) connected to the bidirectional optical splitter for providing a first optical signal and a second optical signal provided by the bidirectional optical splitter to the wavelength division filter unit; and

The wavelength division filter unit 220 is installed at the rear end of the optical coupler to distinguish one of the first optical signal and the second optical signal and transmit one of the first optical signal and the second optical signal to provide the photodetector to the photodetector. It characterized by comprising;

Specifically, the optical coupler 210 is connected to the bidirectional optical splitter to provide the first and second optical signals provided by the bidirectional optical splitter to the wavelength division filter 220.

At this time, according to an additional aspect, the optocoupler 210,

It is characterized by a 2 X 1 form.

That is, as shown in FIG. 2, the ports C1 and C2 are configured, the C1 port is connected to the P3 port of the bidirectional optical splitter, and the C2 port is connected to the P4 port.

Therefore, the second optical signal input to the C1 port and the first optical signal input to the C2 port are provided to the wavelength division filter unit.

That is, since the shape is 2 X 1, the first optical signal and the second optical signal may be provided to the wavelength division filter unit by connecting to the wavelength division filter unit 220 at the C3 port.

In addition, the wavelength division filter unit 220 is installed at the rear end of the optical coupler 210 to distinguish one of the first optical signal and the second optical signal and transmit one of the first optical signal and the second optical signal. To provide a photodetector.

That is, to distinguish between the first optical signal provided by the optical line terminal (OLT) 10 or the second optical signal provided by the optical network termination device (ONU) 20, one of the optical signals is transmitted.

In short, it is to transmit a specific wavelength band, for example, it is possible to distinguish whether the first optical signal of 1,550nm or the second optical signal of 1,310nm.

If the wavelength is set to 1,550 nm, only the first optical signal corresponding to the wavelength band is transmitted. If 1,310 nm is provided instead of the wavelength band, the wavelength division filter unit converts the filter so as to obtain it.

To this end, the wavelength classification filter unit may further include a wavelength analysis module for analyzing the input wavelength band.

At this time, the wavelength division filter forming optical coupler 200, by distinguishing a specific wavelength band, it is possible to distinguish whether the first optical signal or the second optical signal, and through the photodetector 300, the light of the divided optical signal The power can be measured.

For example, wavelength-1550 nm, optical power-0.1 mW can be detected.

In summary, the wavelength division filter unit 220 may distinguish a specific wavelength band, and the optical power may be measured through the photodetector 300.

Therefore, in the related art, only the optical power is measured by switching the optical signal. However, the present invention provides an effect of simultaneously measuring the optical power and the optical wavelength without switching the optical signal, which is a core effect. .

In addition, the photodetector 300 measures the optical power of any one of the first optical signal and the second optical signal provided from the wavelength division filter formed optical coupler 200.

In the case of the first optical signal it can be measured that the optical power is 0.1dBm.

That is, as shown in FIG. 1, the optical detector 300 and the optical power monitoring terminal 70 are connected to each other so that the optical power provided from the photo detector can be analyzed by the optical power monitoring terminal 70.

On the other hand, according to another aspect of the present invention, the photodetector 300 may further comprise an optical power analysis unit.

When configured as described above, the optical power is analyzed through the optical power analyzer configured in the optical detector without transmitting to the optical power monitoring terminal.

In this case, when the display panel is configured in the photodetector, the analyzed optical power may be output through the display panel.

Therefore, the manager can check the optical power in real time at the site where the photodetector is configured.

On the other hand, according to an additional aspect, the photodetector 300,

The optical power of the first optical signal and the second optical signal may be measured respectively or simultaneously.

For example, in the case of measuring each, only one first optical signal or second optical signal is connected and measured, and thus, each optical power and optical wavelength can be measured, and the first optical signal and the second optical signal are simultaneously connected. By measuring, optical power and optical wavelength of two optical signals can be measured.

In other words, it is possible to measure by connecting either one or both without necessarily connecting two.

If there is a wavelength desired by the user, the wavelength is optionally selected and measured.

On the other hand, the optical signal measuring apparatus capable of measuring the directional optical power and the optical wavelength of the present invention, by combining the first optical signal and the second optical signal in one bidirectional transmission and reception optical path to one photodetector 300, Optical power can be measured through the two photodetectors.

That is, as described in the prior art, conventionally, two PDs (photo diodes) are configured on a bidirectional transmission and reception line, and optical power for each optical signal is measured.

However, the present invention, when configured as described above, by combining the first optical signal and the second optical signal in a bi-directional transmission and reception optical path to one photodetector 300, it is possible to measure the optical power through one photodetector It can provide the effect.

Through the above-described configuration and operation, two optical signals are combined into one photodetector in a bidirectional transmission / reception optical line without switching the optical signals, and then the optical power is measured and the optical wavelength is simultaneously It will provide the effect that can be analyzed.

Those skilled in the art to which the present invention pertains as described above may understand that the present invention may be implemented in other specific forms without changing the technical spirit or essential features of the present invention. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not restrictive.

The scope of the invention is indicated by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the invention. do.

100: bidirectional optical splitter
200: wavelength division filter forming optical coupler
300: photodetector

Claims (3)

An optical signal measuring apparatus capable of measuring directional optical power and optical wavelength,
The first optical signal transmitted from the optical line terminal (OLT) 10 to the optical terminal device (ONU, 20) and the second optical signal transmitted from the optical network terminal device (ONU, 20) to the optical line terminal device (OLT, 10). A bidirectional optical splitter 100 which transmits the first optical signal and the second optical signal to the wavelength division filter forming optical coupler 200 without changing, and
An optical coupler (210) connected to the bidirectional optical splitter to provide a wavelength division filter unit with a first optical signal and a second optical signal provided from the bidirectional optical splitter;
The wavelength division filter unit 220 is installed at the rear end of the optical coupler to distinguish one of the first optical signal and the second optical signal and transmit one of the first optical signal and the second optical signal to provide the photodetector to the photodetector. A wavelength division filter-forming optical coupler 200 configured to include;
And a photo detector 300 for measuring the optical power of any one of the first optical signal and the second optical signal provided by the wavelength division filter forming optical coupler 200.
The bidirectional optical splitter 100,
When the optical power transmitted from the optical line terminal (OLT, 10) to the optical terminal device (ONU, 20) and the optical terminal device (ONU, 20) to the optical line terminal device (OLT, 10) is set within the range of 99 to 80, The optical power transmitted to the wavelength division filter forming optical coupler 200 is characterized in that it is set within the range of 1 to 20,
Through the wavelength-division filter-forming optical coupler 200,
By distinguishing a specific wavelength band, it is possible to distinguish whether it is a first optical signal or a second optical signal, and through the photodetector 300, the optical power of the divided optical signal may be measured.
The wavelength division filter unit 220 is characterized in that it comprises a wavelength analysis module for analyzing the input wavelength band,
An optical signal measuring apparatus capable of measuring the optical power and the optical wavelength, characterized in that for measuring the optical power and the optical wavelength at the same time without switching the optical signal.
The method of claim 1,
The bidirectional optical splitter 100,
Optical signal measuring apparatus capable of measuring the directional optical power and the wavelength of light, characterized in that the 2 X 2 form.
The method of claim 1,
The optocoupler 210,
Optical signal measuring apparatus capable of measuring the directional optical power and the wavelength of light characterized in that the 2 X 1 form.

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