JP3323919B2 - Automatic optical characteristics measurement system for optical connectors - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for automatically measuring optical characteristics of an optical connector used for optical communication.

[0002]

2. Description of the Related Art In an optical connector for optical communication, optical characteristics are measured after assembling the optical connector to ensure low-loss and low-reflection optical connection. The measurement items include connection loss, which indicates the light transmittance at the connection part of the optical connector, and return loss, which indicates the reflectivity. Currently, these connection loss and return loss are individually measured manually. are doing. Hereinafter, a conventional measurement method will be described with reference to the drawings.

FIGS. 6A and 6B are diagrams for explaining a method of measuring a connection loss of an optical connector. In this figure, 4
1 is an LD light source, 42 is a master optical code, 42a is an optical connector, and 42b is a master optical connector. Here, the master optical connector is a reference optical connector having excellent mechanical dimensional accuracy and optical characteristics. For example, an optical connector (core eccentricity of 0.5 μm) described in Table 2 of JISC 5961 is used.
m, emission angle 0.2 degrees or less, ferrule outer diameter accuracy ±
0.5 μm or less). 43 is an adapter, 44 is an optical cord with optical connectors at both ends, 44a is an optical connector to be measured, 44b is an optical connector on the terminal end, 45 is a light receiving unit, and 46 is a power meter.

First, prior to the measurement of the connection loss of the optical connector, a reference setting of the connection loss is performed in the measurement system shown in FIG. The optical connector 42a at one end of the master optical cord 42 is connected to the LD light source 41, and the master optical connector 42
b is connected to the light receiving unit 45. Master optical connector 4
The light emitted from the light receiving unit 45 is emitted from the light receiving unit 45 through the air layer.
Is received by the The output power Pi0 is read from the master optical connector 42b by the power meter 46, and this value is defined as a reference value (connection loss is 0) in connection loss measurement.

Next, in order to measure the connection loss of the optical connector 44a to be measured, the master optical connector 42b is detached from the light receiving unit 45, and as shown in FIG. The optical connector 44a to be measured is connected via the adapter 43, and the optical connector 44b on the terminal side is connected to the light receiving unit 45. The light emitted from the optical connector 44b on the terminal side is received by the light receiving unit 45 via the air layer as in the case of the reference value measurement. The output power Pi1 at this time is measured by the power meter 46.

The connection loss IL at the connection part of the optical connector is:
The output power Pi0, the output power Pi1, the transmission loss α (dB / Km) of the optical fiber, and the reflection loss β at the end face of the optical connector are represented by the following equation.

[0007]

(Equation 1)

Here, the reflection at the end face of the optical connector is usually 0.01% or less, and the reflection loss β is not more than the resolution of the measuring instrument, so it is not necessary to consider it. In the case of a single mode optical fiber, the transmission loss α is 0.35 dB / K
m or less. Therefore, when the length of the optical cord to be measured is 30 m or less, the transmission loss α is about 0.01 dB, which is almost equal to the resolution of the measuring instrument, and can be ignored. Transmission loss (α
/ M) is measured or calculated in advance, and in any case, the connection loss IL of the optical connector can be easily obtained from equation (1).

Next, a method for measuring the return loss will be described with reference to FIGS. 7 (a) and 7 (b). In this figure, reference numeral 50 denotes a stabilized LD light source, 51 denotes an optical directional coupler, and 51a and 51b.
Is an input port of the optical directional coupler 51, 51c and 51d are output ports of the optical directional coupler 51, 51e and 51f are optical connectors for input ports, 51g and 51h are oblique polishing optical connectors for output ports, 52 Is the master optical code, 52
a is an oblique polishing optical connector connected to the master optical code 52; 52b is a master optical connector for measuring the return loss connected to the master optical code 52; 53 is an adapter; 54 is a light receiving unit for measuring the return loss , 55 is a power meter, 56 is an adapter, 57 is an optical code, 57a is an optical connector to be measured, 57b is a terminal-side optical connector, 58 is an adapter, 59 is a non-reflection terminal code, 59
Reference numeral a denotes a low-reflection optical connector connected to the non-reflection terminal optical code 59, and reference numeral 59b denotes an oblique polishing optical connector connected to the non-reflection terminal optical code 59.

A method of measuring a reference value in measuring the return loss of an optical connector will be described with reference to FIG. The input port 51a of the optical directional coupler 51 is connected to the stabilized LD light source 50.
And the other input port 51b is connected to a light receiving unit 54 for measuring the return loss. Next, the output port 51c of the optical directional coupler 51 is connected to the master optical cord 52 via the adapter 53. Other output port 51d
Is terminated by an obliquely polished optical connector 51g to suppress reflection from the output port 51d. Fresnel reflection between an optical fiber and air is often used as the reference value of the return loss. In this case, the reference value Pr0 of the power meter 55 when the master optical connector 52b is exposed to air becomes the reference value.

Next, a method of measuring the return loss of the optical connector will be described with reference to FIG. The optical connector 57a to be measured and the master optical connector 52b are connected via an adapter 56, and the terminal-side optical connector 57b is also connected to the adapter 58.
Through a low-reflection optical connector 59a attached to one end of the non-reflection terminal optical code 59. In this state,
The indicated value Pr ₁ of the optical power meter 55 is measured. The return loss R _L of the optical connector is expressed by the following equation using the indicated values Pr _{0 and} Pr ₁ of the optical power meter 55.

[0012]

(Equation 2)

Similarly, the measurement of the return loss of the terminal-side optical connector 57b is performed by removing the optical connector 57a and the terminal-side optical connector 57b to be measured from the adapters 56 and 58, respectively. The master optical connector 52b is connected to the terminal side optical connector 57b of the optical cord 57 to be measured, the optical connector 57a to be measured is replaced with the adapter 58, and the indicated value Pr ₁ is measured by the power meter 55. Thus, it can be similarly obtained.

[0014]

However, in the conventional measuring methods, the optical connector to be measured is attached to and detached from the adapter, the average of the connection loss and the return loss is calculated from the measured values, the measured values are stored, and the statistics are stored. There is a drawback that the inspection cost increases because the processing is manually performed. SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical connector automatic characteristic measuring apparatus for automatically measuring connection loss and return loss, which are optical characteristics of an optical connector.

[0015]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the invention according to claim 1 is directed to an optical connector for measuring the connection loss and return loss of an optical connector for optical communication. A measurement device , which has an optical output
Optical output unit for measuring connection loss having interface 10a
21 and a light receiving interface 10b for measuring connection loss.
Light receiving part 22 for measuring the connection loss, and for measuring the return loss
For measuring return loss with optical output interface 11a
Optical output / light receiving section 23 and a termination interface for return loss measurement
Terminal part 24 for measuring return loss provided with face 11b
And a light to be measured.
The first optical connector 1 attached to both ends of the cord 3 and the first
2 optical connector 2 is gripped and transferred three-dimensionally,
Each of the interfaces 10a and 10b for measuring the connection loss
Insert and remove the first and second optical connectors 1 and 2, respectively.
Or each interface 1 for measuring the return loss
1a and 11b are connected with the first and second optical connectors 1 and 2 respectively.
Robot hand machine that operates to insert and remove respectively
Structures 7 and 8 and their control units (computer 1 in the embodiment)
3), and the optical output unit 21 for connection loss measurement includes:
A connection loss measurement light source 25 and a connection loss measurement
Master light for connection loss measurement having a star optical connector 27
And a cord 26 for measuring the connection loss.
The optical connector 27 is an optical output interface for measuring the connection loss.
And a master for measuring the connection loss.
The other end of the optical cord 26 is connected to the connection loss measuring light source 25.
The light receiving unit 22 for measuring the connection loss is connected to the connection loss
A light receiving element 28 for measurement and a light receiving element for measuring the connection loss
A first output measuring device for measuring the output of the
The power meter 29 in the example) and the connection cord 28a
And the light receiving element 28 for measuring the connection loss is
It is arranged on the light receiving interface 10b for connection loss measurement.
And the first output via the connection cord 28a.
Optical output for measuring the return loss
The light receiving unit 23 includes a light source 30 for measuring the return loss and an optical cord.
31 and an optical fiber having two inputs and two outputs.
Iva coupler 32 and master light for measuring return loss at one end
Master optical cable for measuring return loss having connector 34
33, a light receiving element 35 for measuring the return loss,
Connected to a light receiving element 35 for measuring the amount of
The second output for measuring the output of the light receiving element for measuring the amount of attenuation.
Force measuring device (power meter 36 in the embodiment)
A polishing optical connector 37;
One of the input terminals of the plastic 32 is connected through the optical cord 31
The light source 30 for measuring the return loss is connected, and another
A light receiving element 35 for measuring the return loss is connected to the input terminal.
And one of the output ends of the optical fiber coupler 32 is
The other end of the master optical cord 33 for measuring return loss is connected.
And the other output end is connected to the oblique polishing optical connector 37.
Non-reflection terminated, master optical connector for measuring the return loss
Is a light output interface for measuring the return loss.
11a, and a terminal portion 24 for measuring the return loss.
Obliquely polishing, the other end has a low-reflection light connector 38 at one end
Non-reflection terminated optical cord 3 terminated by optical connector 40
9 and the low-reflection optical connector 38 is
Connected to the attenuation measurement termination interface 11b,
An automatic optical characteristic measuring apparatus for an optical connector, wherein the connection loss and the return loss of the first and second optical connectors are automatically measured by using the first optical characteristic measuring device.

The invention according to claim 2 is characterized in that the connection loss
Loss measurement optical output interface 10a and return loss
The optical output interface for measurement 11a is integrated
And a light receiving interface for measuring the connection loss.
10b and termination interface for measuring the return loss
11b is arranged so as to be integrated with the
Optical output interface 10a for measuring connection loss and
Integrated with optical output interface 11a for measuring return loss
Of the connection loss measuring light receiving interface 10b
And the termination interface 11b for measuring the return loss
2. An apparatus for automatically measuring optical characteristics of an optical connector according to claim 1, further comprising means for changing the mechanical position of the optical connector.

[0017] Further, the invention according to claim 3 is characterized in that:
An end face cleaner 9a for cleaning the end face of the second optical connector ,
Claim 1 or, characterized in that further comprising a 9b
According to a second aspect of the present invention, there is provided an optical connector automatic measuring apparatus for an optical connector.

[0018] Further, the invention according to claim 4 is the first invention.
Second optical property measurement having the same configuration as the optical property measurement device
Device , and the optical property measuring device to be used is
From the first optical property measuring device to the second optical property measuring device
Or from the second optical property measurement device to the first
Any one of claims 1 to 3, characterized in that further comprising means for changing Ri mechanically switching the optical characteristic measuring apparatus 1
The optical characteristic automatic measurement device of the optical connector described in the paragraph .

[0019]

According to the optical connector automatic characteristic measuring apparatus of the present invention, the optical connector is automatically handled by a robot hand mechanism capable of three-dimensionally moving the optical connector connected to both ends of the optical cord, and the interface of the optical characteristic measuring device is provided. The optical characteristics of an optical connector, which had previously been measured by manually inserting and removing an optical connector connected to both ends of an optical cord into the interface of an optical characteristic measuring instrument, can be automatically measured. . In addition, since there is a function of automatically changing the interface position of the optical characteristic measuring device, the optical characteristics of the optical connectors at both ends of the optical cord can be measured by a set of optical characteristic measuring devices. Furthermore, by having a cleaner mechanism for the optical connector, the end face of the optical connector to be measured can be cleaned, so that the reliability of the optical characteristic measurement can be improved, and the current measurement can be performed by adding a backup measurement system. When a failure occurs in the system, the measurement can be continued by switching to the backup measurement system, so that the measurement can be made highly reliable and the device operation rate can be improved.

[0020]

FIG. 1 shows an embodiment of an apparatus for automatically measuring the optical characteristics of an optical connector according to the present invention. In the figure, reference numerals 1 and 2 denote optical connectors to be measured connected to both ends of an optical cord 3, 4 a sample table, 5 a pallet for accommodating the optical cord 3, 6 a and 6
b is a receptacle, 7 and 8 are robot hand mechanisms for handling the optical connectors 1 and 2, 9a and 9b are end face cleaners for cleaning the end faces of the optical connectors 1 and 2, 10a is an optical output interface for measuring connection loss, and 10b is an interface. Light receiving interface for measuring connection loss, 11a is an optical output interface for measuring return loss, 11b is a termination interface for measuring return loss, 10a ', 10b', 11a ', 1
1b 'is a standby measuring instrument interface, 12 is a GPI
B and 13 are computers (computers), 20 is a turntable, 21 and 22 are optical output units and light receiving units for measuring connection loss, 23 is an optical output and light receiving unit for measuring return loss, and 26 is a connection loss measuring unit. Reference numeral 28a denotes a power meter connection cord, reference numeral 33 denotes a master optical cord for measuring the return loss, reference numeral 39 denotes a non-reflection terminal optical code, and reference numeral 40 denotes an oblique polishing optical connector.

FIG. 1 is a plan view showing the entirety of an optical characteristic automatic measuring device of an optical connector according to an embodiment of the present invention, and FIG. 2 is a front view thereof. It comprises a mechanical unit such as a hand mechanism and a transfer mechanism, an optical characteristic measuring unit, and a control unit for controlling the optical characteristics and the mechanical unit. As the measuring device for the optical characteristics, the connection loss measuring device and the return loss measuring device described in the conventional example may be used.

FIG. 3 shows a configuration of a measuring device for measuring the connection loss and the return loss with the same configuration as the conventional example, and the measuring device interface in the present invention will be described. In the figure, 21 is an optical output unit for measuring connection loss, 22 is a light receiving unit for measuring connection loss, 23 is an optical output / light receiving unit for measuring return loss, 24 is a termination unit for measuring return loss, 25 Is the LD for splice loss measurement
Light source, 26 is a master optical cord for measuring connection loss, 27 is a master optical connector for measuring connection loss, 28 is a light receiving element with a receptacle, 28a is a power meter connection cord, 29
Is a power meter, 30 is an LD light source for measuring return loss,
31 is an optical code, 32 is an optical fiber coupler, 33 is a master optical code for measuring return loss, 34 is a master optical connector for measuring return loss, 35 is a light receiving element for measuring return loss, and 36 is a light receiving element. A power meter, 37 is an obliquely polished optical connector, 38 is a low-reflection optical connector, 39 is a non-reflection terminal optical cord, and 40 is an obliquely polished optical connector.

Prior to the automatic measurement of the optical characteristics, it is necessary to set the respective reference values of the connection loss and the return loss described in the conventional example. This reference value is set by the optical cord 3 having the master optical connector 27 and the optical connectors 1 and 2 at both ends.
Detector 28 with receptacle for connection loss measurement via
And the value at this time is set as a reference value of connection loss (connection loss 0), and the reference value of return loss is set by exposing the master optical connector 34 for return loss measurement to the air layer. Set the reference value in the state where it was done. After the above settings are completed, connection loss and return loss are automatically measured.

The measurement of the connection loss is performed using the optical output unit 21 and the light receiving unit 22 for connection loss measurement. An optical connector adapter is applied to the connection loss measuring optical output interface 10a, and the master optical connector 27 and the master optical cord 2 are connected to the adapter.
6 and the LD light source 25 are connected. On the other hand, the light-receiving interface 10 for connection loss measurement of the light-receiving section 22 for connection loss measurement
A light receiving element 28 with a receptacle is arranged at b, and an optical output value is read from a power meter 29 via a power meter connection cord 28a to measure a connection loss.

The return loss measurement is performed by using the optical output / light receiving section 23 for return loss measurement and the terminal section 24 for return loss measurement. Optical output interface 11 for return loss measurement
An optical connector adapter may be applied to a, and the master optical connector 34, the optical fiber coupler 32, the optical cord 31, and the LD light source 30 may be connected thereto. The optical fiber coupler 32 includes, at one of its input terminals, the above-described LD light source 30 via the optical cord 31, and at the other input terminal, a light receiving element 35 for measuring the return loss and a power meter 36. Is connected. One of the output ends is a master optical cord 33 having a master optical connector 34, and the other output end is non-reflectively terminated by an oblique polishing optical connector 37.
On the other hand, an optical connector adapter is used for the return loss measuring terminal interface 11b, and the low-reflection optical connector 38 at one end of the non-reflection terminal optical cord 39 terminated by the oblique polishing optical connector 40 is connected to the adapter. I have. These interfaces include an optical output interface 10a for measuring connection loss and an optical output interface 11 for measuring return loss.
a, the connection loss measuring light receiving interface 10b and the return loss measuring end interface 11b are stacked and integrated in the Y-axis direction, respectively.

In FIGS. 1 and 2, the optical connectors 1 and 2 to be measured are attached to both ends of an optical cord 3, and the optical characteristics of the optical connector are measured separately at each end. First, the measurement of the optical characteristics of the optical connector 1 will be described. The optical connectors 1 and 2 attached to both ends of the optical cord 3 are accommodated in receptacles 6 a and 6 b on a pallet 5 mounted on a sample table 4. First, the optical connectors 1 and 2 are connected to the optical output interface 10a for connection loss measurement.
The robot hand mechanisms 7 and 8 move in the Z direction and are positioned above the optical connectors 1 and 2 to be measured, and then move down in the Y direction to transfer them to the light receiving interface 10b for connection loss measurement. Hold 2

Next, after the optical connectors 1 and 2 are removed from the receptacles 6a and 6b, the optical connectors 1 and 2 rise in the Y direction, and each interface 10 for measuring connection loss and return loss is measured.
The optical connectors 1 and 2 are transported in the directions a, 10b, 11a and 11b (Z direction). The end face cleaners 9a and 9b rise to the height of the optical connectors 1 and 2 gripped by the robot hand mechanisms 7 and 8, and clean the end faces of the optical connectors 1 and 2.
The end face cleaners 9a and 9b have a tape-shaped cloth therein, and the optical connectors 1 and 2 are pressed against the cloth end faces of the end face cleaners 9a and 9b by the robot hand mechanisms 7 and 8. In this state, the cloth in the end face cleaners 9a and 9b moves to clean the end faces of the optical connectors 1 and 2. After cleaning the end faces of the optical connectors 1 and 2, the end face cleaners 9a and 9b descend and return to their original positions.

Next, the optical connectors 1 and 2 are used to measure connection loss.
And, it is inserted and fixed to the light receiving interface 10b for connection loss measurement. The transfer of the robot hand mechanisms 7 and 8
The control is all performed by a control device (not shown). In the case where a complicated transfer is unnecessary and an economical configuration is possible, an air cylinder is often used for the transfer means of the robot hand mechanism and a sequencer is used for the control device. When the robot hand mechanism requires complicated transfer, a motor with an encoder is often used as the transfer means of the robot hand mechanism, and a computer (computer) is often used for control.

The optical connectors 1 and 2 are connected by the robot hand mechanisms 7 and 8 to the optical output interface 10a for measuring connection loss.
In the state where the light source is inserted and fixed in the light receiving interface for connection loss measurement 10b, light emitted from the LD light source 25 for connection loss measurement is emitted from the master optical connector 27 as shown in FIG. The light propagating into the optical code 3 through the optical connector 1 and emitted from the optical connector 2 at the other end is received by the light receiving element 28 with a receptacle.
By reading the output value of the light receiving element with receptacle 28 from the power meter 29 by the computer 13 via the bus of the GPIB 12, the connection loss of the optical connector can be measured.
If an average value of a plurality of measurements is required, the optical connector 1 may be repeatedly removed from the optical output interface 10a for connection loss measurement and recoupled by the robot hand mechanism 7.

Next, in order to measure the return loss of the optical connector 1, the optical connector 1 is pulled out of the optical output interface 10a for connection loss measurement and the light receiving interface 10b for connection loss measurement. Connect the connector 1 to the optical output interface 11a for measuring the return loss.
Then, the optical connector 2 at the other end is inserted and fixed to the termination interface 11b for measuring the return loss. In this state,
The light emitted from the LD light source 30 for measuring the return loss propagates through the optical fiber coupler 32 and emerges from the master optical connector 34, and then propagates through the optical connector 1 and the optical cord 3 to be measured and the other measurement. The light further propagates through the non-reflection terminal optical cord 39 through the optical connector connection between the target optical connector 2 and the low-reflection optical connector 38, and finally, the light is sent out of the optical cord 39 by the obliquely polished optical connector 40. Radiated.

Therefore, the light receiving element 35 attached to the input end of the optical fiber coupler 32 receives the reflected light at the optical connector connection, and outputs the output value of this light receiving element 35 from the power meter 36 to the bus of the GPIB 12. Via computer 13
, The return loss of the optical connector 1 can be measured. If you need the average of multiple measurements,
As with the measurement of the connection loss, the robot hand mechanism 7 may repeatedly remove and reconnect the optical connector 1 from the optical output interface 11a for measuring the return loss.

With the above operation, the optical characteristics of the optical connector 1 at one end can be measured. Next, in order to measure the optical characteristics of the optical connector 2 at the other end, the positions of the optical connectors 1 and 2 in the X direction are replaced, and the above measurement may be repeated. The simplest way to change the position of the optical connectors 1 and 2 is to use a pallet 5
Once the optical connectors 1 and 2 are connected to the robot hand mechanisms 7 and 8
After returning by, it is replaced by hand,
In this case, the optical connector at one end is automatically measured, and the measurement efficiency is low. Although the position of the optical connector can be automatically switched by the robot hand mechanism, it is not preferable because the mechanism and operation become complicated. Therefore, a method of changing the position of the optical connector with a simple mechanism and operation and automatically measuring the optical characteristics of the optical connector at the other end will be described.

FIGS. 4 and 5 are views showing the entire configuration of FIG. 1 as viewed from the Z direction. FIG. 4 shows a case where the optical characteristics of the optical connector 1 are measured. For example, when the connection loss of the optical connector 1 is measured, the robot hand mechanism 7 is used.
To insert the optical connector 1 into the optical output interface 10a for connection loss measurement, and the robot hand mechanism 8 to insert the optical connector 2 into the light receiving interface 10b for connection loss measurement. With such connection, the connection loss of the optical connector 1 can be measured.

Next, the return loss of the optical connector 1 is determined by setting the optical connector 1 to the optical output interface 11 for measuring the return loss.
a, and by inserting the optical connector 2 into the return loss measuring termination interface 11b. Thus, the optical characteristics of the optical connector 1 at one end can be measured. Next, in order to measure the optical characteristics of the optical connector 2 as the other object to be measured, as shown in FIG. 5, the interface of the measuring instrument is transferred and replaced in the x direction, and the optical connector is gripped. The height of the robot hand mechanism in the y direction is also changed, and the other optical connector 2 to be measured is connected to the optical output interface 10a for measuring connection loss and the optical output interface 11a for measuring return loss, and the optical connector 1 to be measured. Is the light receiving interface 10 for connection loss measurement
and the optical connector 2 in the same manner as described above.
Can be measured. Therefore, by introducing the position changing mechanism of the measurement interface, the optical characteristics of the optical connectors at both ends can be measured by a set of measuring instruments.

Furthermore, if another set of the measurement system shown in FIG. 3 is prepared and incorporated in the apparatus shown in this embodiment, highly reliable measurement can be performed by doubling the measurement system. In FIG.
Reference numerals 10a ', 10b', 11a ', and 11b' are standby measuring instrument interfaces. When the measured value exceeds an upper limit of a set standard value, the turntable 20 rotates, and each of the interfaces 10a, 10b, 11a, 1
1b is a standby measuring instrument interface 10a ', 10
The measurement is switched to b ', 11a', and 11b 'and measurement is performed again. If the measurement results are the same, it means that the measured value of the optical connector exceeds the specified value.If the measured value is less than the upper limit of the specified value in the re-measurement, the master optical connector used in the previous measurement is abnormal. You can see that there is. If the measurement system is duplicated in this way, it is possible to check for an abnormality in the inspection object and the measurement system, so that highly reliable measurement can be performed.

[0036]

Since the present invention is configured as described above, the optical connector is automatically handled by the robot hand mechanism capable of three-dimensionally moving the optical connector to be measured connected to both ends of the optical cord. The optical connector can be automatically inserted and removed from the interface of the optical characteristic measuring instrument, so that the optical connector connected to both ends of the optical cord was previously manually inserted and removed from the interface of the optical characteristic measuring instrument and measured. Characteristics can be measured automatically. In addition, since there is a function of automatically changing the interface position of the optical characteristic measuring device, the optical characteristics of the optical connectors at both ends of the optical cord can be measured by a set of optical characteristic measuring devices. Furthermore, by having a cleaner mechanism for the optical connector, the end face of the optical connector to be measured can be cleaned, so that the reliability of the optical characteristic measurement can be improved, and the current measurement can be performed by adding a backup measurement system. When a failure occurs in the system, the measurement can be continued by switching to the backup measurement system, so that the measurement can be made highly reliable and the device operation rate can be improved. As described above, by using the optical characteristic measuring instrument conventionally used for manual measurement as it is, complicated work such as attaching and detaching an optical connector to the measuring interface required for measurement is unnecessary, and furthermore, the measuring instrument interface is not required. By introducing a mechanical position change mechanism and a redundant configuration of the measurement system, it is possible to measure the optical characteristics of the optical connectors at both ends with a single measurement system with high reliability. The time can be reduced, the inspection cost can be reduced, and the reliability can be improved.

[Brief description of the drawings]

FIG. 1 is a plan view of an embodiment of an optical connector optical characteristic automatic measuring apparatus according to the present invention.

FIG. 2 is a front view of an embodiment of the optical connector optical characteristic automatic measuring apparatus according to the present invention.

FIG. 3 is a diagram illustrating a configuration of an optical characteristic measuring device in an optical connector automatic characteristic measuring apparatus according to an embodiment of the present invention.

FIG. 4 is a diagram for explaining a position change in a measurement interface in the embodiment of the optical connector automatic optical characteristic measuring apparatus of the present invention.

FIG. 5 is a diagram for explaining a position change in a measurement interface in the embodiment of the optical connector optical characteristic automatic measuring device of the present invention.

FIG. 6 is a diagram illustrating a conventional connection loss measurement.

FIG. 7 is a diagram illustrating a conventional return loss.

[Explanation of symbols]

 1, 2 Optical connector to be measured 3 Optical code 4 Sample table, 5 Pallet 6a Receptacle 6b Receptacle 7 Robot hand mechanism 8 Robot hand mechanism 9a End cleaner 9b End cleaner 10a Optical output interface for connection loss measurement 10b Light reception for connection loss measurement Interface 10a 'Stand-by measuring device interface 10b' Stand-by measuring device interface 11a Optical output interface for measuring return loss 11b Return termination measuring interface 11a 'Stand-by measuring device interface 11b' Standby measuring device interface DESCRIPTION OF SYMBOLS 12 GPIB 13 Calculator 20 Turntable 21 Optical output part for connection loss measurement 22 Light reception part for connection loss measurement 23 Optical output / light reception part for return loss measurement 24 Termination part for return loss measurement 25 Contact LD light source for loss measurement 26 Master optical code for connection loss measurement 27 Master optical connector for connection loss measurement 28 Light receiving element with receptacle 28a Power meter connection code 29 Power meter 30 LD light source for return loss measurement 31 Optical code 32 Optical fiber coupler 33 Master optical cord for measuring return loss 34 Master optical connector for measuring return loss 35 Light receiving element 36 Power meter 37 Oblique polishing optical connector 38 Low reflection optical connector 39 Non-reflection terminal optical code 40 Oblique polishing optical connector Reference Signs List 41 LD light source 42 Master optical cord 42a Optical connector 42b Master optical connector 43 Adapter 44 Optical cord with optical connector 44a Optical connector to be measured 44b Terminal optical connector 45 Light receiving unit 46 Power meter 50 Stabilized LD light source 51 Light Directional coupler 51a Input port 51b Input port 51c Output port 51d Output port 51e Optical connector for input port 51f Optical connector for input port 51g Oblique polishing optical connector for output port 51h Oblique polishing optical connector for output port 52 Master Optical code 52a Obliquely polished optical connector 52b Master optical connector for measuring return loss 53 Adapter 54 Light receiving unit 55 for measuring return loss 55 Power meter 56 Adapter 57 Optical code 57a Optical connector 57b to be measured 57b Terminal side light Connector 58 Adapter 59 Non-reflective termination optical cord 59a Low-reflection optical connector 59b Obliquely polished optical connector

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-6-241945 (JP, A) JP-A-5-40074 (JP, A) JP-A-63-241329 (JP, A) 105142 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) G01M 11/00-11/02 G02B 6/00 G02B 6/36

Claims (4)

(57) [Claims] 1. A optical characteristic automatic measuring apparatus der optical connector for measuring the connection loss and return loss of the optical connector for optical communication
Connection loss with an optical output interface for connection loss measurement
Optical output for measurement and photodetector interface for splice loss measurement
Receiver with splice loss measurement and return loss measurement
For measuring return loss with optical output interface
Output / receiver and termination interface for return loss measurement
First light having a return end for measuring return loss comprising:
And a first light attached to both ends of an optical cord to be measured.
Hold the connector and the second optical connector and transfer them three-dimensionally
And the second interface for the connection loss measurement is
Insert and remove the first and second optical connectors, respectively.
Is the interface for measuring the return loss.
1. Insert and remove the second optical connector
It has an operating robot hand mechanism and its controller.
The connection loss measurement light output unit is a connection loss measurement light source.
And one end has a master optical connector for connection loss measurement
Further comprising a master optical code for connection loss measurement,
The master optical connector for connection loss measurement
Connected to the optical output interface for the connection loss measurement
The other end of the master optical cord is connected to the connection loss measurement light source.
Connected, and the light-receiving section for connection loss measurement is a light-receiving section for connection loss measurement.
Measure the output of the device and the light-receiving device for measuring the connection loss.
A first output measuring instrument for connection and a connecting cord.
The connection loss measuring light receiving element is connected to the connection loss measurement
Placed on the light receiving interface for
Connected to the first output measuring device via a cable, and the optical output / light receiving section for measuring the return loss is provided with a return loss measuring device.
Light source for measurement, optical cord, two inputs and two outputs
Optical fiber coupler with one end and return loss measurement at one end
A master optical connector with a standard master optical connector
Star code, light receiving element for measuring return loss,
This return loss is connected to the light receiving element for measuring the return loss.
Second output for measuring the output of the light receiving element for measuring the amount
A measuring device, and an oblique polishing optical connector,
One of the input ends of the fiber coupler is connected via the optical cord.
Is connected to the light source for measuring the return loss, and
A light receiving element for measuring the return loss is connected to the force end,
One of the output terminals of the optical fiber coupler has the above-described return loss measurement.
The other end of the designated master optical cord is connected and
The force end is anti-reflection terminated by the oblique polishing optical connector,
The master optical connector for measuring return loss is the return loss
The terminal for measuring the return loss is connected to a low-reflection optical connector at one end.
And the other end is terminated by an oblique polishing optical connector
A low-reflection optical connector;
Is connected to the return interface for measuring return loss.
And the first and second optical characteristics are measured using the first optical characteristic measuring device.
Automatically measuring the connection loss and return loss of the optical connector. 2. An optical output interface for measuring the connection loss.
And the optical output interface for return loss measurement are integrated
And receiving light for measuring the connection loss.
Interface and return interface for measuring return loss
And the contact are arranged so as to be integral with each other.
Optical output interface for measuring continuous loss and return loss
Light output interface for measuring
Light receiving interface for connection loss measurement and the return loss
2. The apparatus for automatically measuring optical characteristics of an optical connector according to claim 1, further comprising: means for changing a mechanical position with respect to a measurement termination interface. Wherein the first optical characteristic automatic measurement apparatus for an optical connector according to claim 1 or claim 2, characterized in that further comprising an end face cleaner that cleans the end face of the second optical connector. 4. An apparatus having the same configuration as the first optical characteristic measuring device.
Further comprising a second optical characteristic measuring apparatus for, and to use
From the first optical property measuring instrument to the optical property measuring instrument.
To a second optical property measuring instrument or to said second optical property
Claim 1 to the measuring device, characterized in that further comprising a mechanically cut replacement <br/> obtain means the the first optical characteristic measuring apparatus -
The optical characteristic automatic measurement device for an optical connector according to claim 3 .