KR20080108720A - Optical connector loss measurement apparatus and method - Google Patents

Abstract

An optical connector loss measurement apparatus and method is provided to determine the connection state of the optical fiber and optical connector by making an optical fiber bent forcedly and measuring leakage power. In an optical connector loss measurement apparatus and method, the light adapter(120) is connected with the light source and optical connector is mounted in it. The optical fiber bending guide(130) makes an optical fiber connected with the optical connector bent. The leakage light detection unit(150) receives leakage light from the bent optical fiber and outputs a value corresponding to the power of the leakage light. The controller(180) determines whether the optical connector is defect or not by using a reference value and the output of the leakage light detection unit.

Description

Loss and defect measuring device of field-mounted optical connector and its measuring method {Optical connector loss measurement apparatus and method}

1 is a block diagram of a typical passive optical subscriber network.

Figure 2 is a block diagram showing the configuration of a loss and defect measurement device of the optical connector according to the present invention.

Figure 3 is a flow chart for explaining a method for measuring the loss and failure of the optical connector using the measuring device of the present invention.

4 is a view showing a state in which the bend is formed in the optical fiber by using the optical fiber bending guide.

<Description of Symbols for Main Parts of Drawings>

110: light source 120: optical adapter

130: optical fiber bending guide 132, 134: optical fiber fixing rubber

140: cover 150: leakage light detection unit

152: light receiving element 154: gain amplifier

156: A / D converter 160: memory

170: setting switch 180: control unit

190: display unit

The present invention relates to an apparatus and a method for measuring the loss and failure of the field-mounted optical connector, and more particularly to the optical power leaked by the bending by artificially bending the optical fiber of the field-mounted optical connector The present invention relates to a measuring device and a method for measuring the loss of an optical connector more quickly and accurately by comparing with a reference value and calculating a loss value thereof.

Due to the rapid development of optical communication technology, subscriber wired communication environment is changing accordingly.

In physical change, the subscriber's home communication infrastructure is changing from the existing telephone line or coaxial cable to the fiber-to-home based fiber subscriber network that connects the telephone company and each home by optical cable.

1 is a configuration diagram of a general passive optical subscriber network, in which a passive optical subscriber network is composed of an optical line terminal (OLT) 11 and an optical power distributor 12, which are largely placed in a telephone station. And an optical node terminal (ONT) 13, which is a subscriber-side optical termination device.

In this passive optical subscriber network, the OLT 11, which is physically located at the national office, is connected to the RN 12 and the feed optical cable 14 of one core, and is branched into N branch optical cables through the RN 12 to ONT (or ONU). By connecting to the (13) has a 1: N structure in which the N ONT (13) share one feed optical cable (14).

As described above, since the N ONTs 13 share one optical cable 14, a multiplexing method is used for data transmission between the OLT 1 and the ONTs 13, and various methods are used as the multiplexing method.

The most commonly used multiplexing scheme is a time division multiplexing passive optical subscriber network technology in which N subscribers share a given bandwidth downward by transmitting data by dividing the time that ONT 13 can communicate with OLT 11. . Alternatively, a wavelength-dividing coupling element can be used in the time division multiplexing passive optical network technology instead of using an optical power divider passive element in the RN 12 to provide independent wavelengths between the OLT 11 and each ONT 13. There is a wavelength division multiplexing passive optical subscriber network technology that can provide a large guarantee rate per subscriber by allocating a communication channel. The latter case is currently being piloted and is expected to be supplied in the future.

However, if the passive light subscriber network technology is applied to the site and applied to the general home subscribers, the OLT 11 is installed in the telephone station and the RN 12 is installed in the underground manhole near the corresponding residential area. Further, the optical cables branched from the RN 12 are connected to one side of the optical distribution box 16 accommodated in the optical terminal box 15 after being formed into a nearby electric pole, and is opposite to the optical distribution box 16. The ONT 13 placed in the subscriber's premises is connected with an incoming optical cable 17. At this time, both the incoming optical cable 17 is installed on-site optical connector (18, 19) that the opening personnel to assemble in the field directly.

After installing the incoming optical cable 17 to the home, the intensity of the optical power is first measured in order to open the equipment. At this time, when the light power intensity is low as a result of the measurement, it is currently impossible to immediately determine which optical connector is causing the loss due to assembly failure in the optical connector. In this case, field personnel solve the problem by cutting the field-mounted optical connectors 18, 19 attached to both sides of the incoming optical cable 17 one by one and then reassembling them with other field-assembled optical connectors to measure the optical power again. Doing. For example, first cut the field assembly optical connector (19) attached to the incoming optical cable (17) introduced into the house, and then reassembled with another field assembly optical connector to measure the optical power and this time the optical power is still low. Cut the field-assembled optical connector 18 attached to the incoming optical cable 17 connected to the optical distribution box 16, and then reassembled with another field-assembled optical connector to measure the optical power.

Therefore, such work is a major factor that hinders the large-scale spread of the optical subscriber network by causing inconvenience that a lot of time and field personnel have to work on the electric pole and have to work again, and the unconnected optical connector is also cut off. There is a problem of economic loss.

Therefore, an object of the present invention for solving the above-mentioned problem is to be able to find out the assembly failure of the optical connector simply and quickly.

Loss and failure measurement apparatus of the optical connector of the present invention for achieving the above object is a light source; An optical adapter equipped with a field assembly optical connector to which an optical fiber is connected; An optical fiber bend guide for forming a bend in the optical fiber; A leakage light detector which receives light leaked from the optical fiber bent by the optical fiber bend guide and outputs a value corresponding to the power of the leakage light; And a controller configured to determine whether the optical connector is defective by using an output value of the leakage light detector and at least one preset reference value.

In the method for measuring the loss and defect of the optical connector according to the present invention, a bend is formed in the optical fiber connected to the field assembly type optical connector to be measured according to a user's operation, and then a light source is applied to the curved optical fiber through the field assembly type optical connector. A first step of entering a light; A second step of detecting a measurement target leakage optical power value leaked from the curved optical fiber by the incidence of the light source; And a third step of determining whether the measurement target optical connector is defective by comparing the measurement target leakage optical power value with a preset reference value.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

2 is a block diagram showing the configuration of a device for measuring the loss and failure of the optical connector according to the present invention.

Measuring device of the present invention is a light source 110, optical adapter 120, optical fiber bend guide 130, cover 140, leakage light detector 150, memory 160, setting switch 170, control unit 180 ) And a display unit 190.

The light source 110 is a means for applying the light to the optical fiber to be measured may be a communication light of a specific wavelength used in the visible light or the actual optical system that is generally used for optical fiber disconnection inspection in optical communication. At this time, since the amount of light leaked due to the communication is less than the visible light due to the bending, when using the communication light to measure the optical power leaked as in the present invention, a rather expensive communication light receiving element should be used. However, when a communication light source is used, there is an advantage in that the loss value of the optical connector can be more accurately calculated.

The optical adapter 120 is configured such that one side is connected to the light source 110 and the other side can be mounted with the field-assembled optical connectors 18 and 19 with the optical fiber to be measured so that the light from the light source 110 can be field-assembled. It can be transferred to the optical fiber through the optical connector (18, 19).

The optical fiber bend guide 130 is a means for allowing light to leak from the optical fiber by forming a bend by artificially applying force to the optical fiber. As the optical fiber bending guide 130, an elliptic bending guide 130a or a steeple-shaped bending guide 130b may be used as shown in FIGS. 4A and 4B, but is not limited thereto.

The cover 140 is a means for opening and closing the space in which the field-assembled optical connectors 18 and 19 and the optical fiber are located in the measuring device of the present invention, in which impurities are introduced into the space or leaked light is leaked to the outside. To prevent them.

The leakage light detector 150 receives the light leaked from the optical fiber bent by the optical fiber bend guide 130, converts the light into an electrical signal, and outputs the electrical signal to the controller 180. The leakage light detector 150 receives the light leaked from the bent optical fiber and converts it into an electrical signal, a light receiving element 152, an amplifier 154 for amplifying the magnitude of the converted electrical signal, and the amplified electrical signal as a digital signal. An A / D converter 156 for converting to. In this case, in FIG. 2, the leakage light detector 150 outputs a digital signal corresponding to the optical power of the leaked light. However, when the controller 180 is configured to process the analog signal, the leakage light detector 150 is configured to process the analog signal. It may be configured to immediately output the analog signal to the controller 180.

The memory 160 stores a reference value for measuring optical power according to the present invention. In this case, the reference value stored in the memory 160 may vary according to the type of the light source 110. That is, when visible light is used as the light source 110, the leakage light power value measured in advance with respect to the optical connector of the fusion splicing method generally used as a reference value is used. That is, the optical fiber bending guide 130 of the present invention is used to form an optical connector for the optical connector (reference optical connector) in which the optical fiber is normally connected as a fusion splicing type optical connector that is not a field-assembled optical connector. After that, the visible light from the light source 110 is incident on the optical fiber, and the power of the leaked light is measured in advance, and the value is stored in the memory 160 as a reference value (hereinafter referred to as 'first reference value'). However, when the light source 110 is a communication light, in order to obtain not only the defects of the optical connectors 18 and 19 but also the actual loss values of the optical connectors 18 and 19 together, the optical connector to which the optical fiber is normally connected (the reference optical connector). When the optical fiber bending guide 130 is used, the measured loss value is obtained beforehand as well as the optical power leaking when the bending guide 130 is not used. In this case, in order to determine whether the optical connectors 18 and 19 are defective, the optical fiber bending guide 130 is bent and the leaked optical power measured in advance using communication light is referred to as a reference value (hereinafter, 'second reference value'). To be stored). In order to calculate the loss value of the optical connector 19, the reference value is a proportional value between the loss value of the reference optical connector measured by injecting communication light without the bending guide 130 and the second reference value obtained above. (Hereinafter referred to as 'third reference value').

The setting switch 170 receives the allowable value of the optical connector according to the site environment from the user and outputs it to the controller 180. The setting switch 170 includes a plurality of button keys to allow the user to input a desired value arbitrarily, or includes a plurality of buttons to which a fixed value such as 1 dB, 2 dB, or 3 dB is assigned. You can select a button.

The controller 180 uses the output value of the leakage light detector 150 (hereinafter referred to as a measurement target leakage optical power value) to the measurement target optical connector 19 and the reference values stored in the memory 16 to determine the measurement target. It is determined whether the optical connector 19 is defective and calculates a loss value. That is, the controller 180 compares the measured leakage light power with the first reference value or the second reference value, and if the difference is larger than the allowable value set by the user using the setting switch 170, the display unit 190 is defective. If the LED is on and less than the allowed value, the good LED is on. In particular, when communication light is used as the light source 110, the controller 180 calculates a loss value of the measurement target optical connectors 18 and 19 by using the leakage target optical power and the third reference value (proportional value). Inform the user. On the display unit 190 of FIG. 2, only a bad LED and a good LED are displayed to indicate whether the optical connectors 18 and 19 are defective, but a window (not shown) for displaying a loss value of the optical connectors 18 and 19 is provided. It may be further provided.

3 is a flowchart for explaining a method for measuring the loss and failure of an optical connector using the measuring apparatus of the present invention having the above-described configuration.

The user (field worker) first pushes the cover 140 in the form of a slider of the measuring device and mounts the field-assembled optical connector 18 or 19 with the optical fiber to be measured to the optical adapter 120 inside the measuring device. (Step 310).

At this time, the optical fiber is fixed to the optical fiber by using the optical fiber fixing rubber (132, 134) on both sides of the optical fiber bend guide 130 as shown in Figure 4 so that the optical fiber does not move right after introducing the proper length as necessary for the measurement. .

Next, the user bends the optical fiber bend guide 130 sufficiently until the optical fiber reaches the end of the optical fiber bend guide 130 as shown in FIG. In this embodiment, an elliptic bend guide 130a or a steeple bend guide 130b as shown in FIG. 4 is used as the optical fiber bend guide 130, but is not limited thereto.

Next, when the user turns on the measuring device, visible light or communication light output from the light source 110 is incident on the optical fiber through the optical adapter 120 and the field-assembled optical connector 19, and the incident light beam is the optical fiber. Proceeds along the leakage from the optical fiber bending guide 130 is input to the light receiving element 152 (step 330).

The light receiving element 152 converts the input light into an electrical signal, and the converted electrical signal is amplified by the gain amplifier 154 and then converted into a digital signal by the A / D converter 156 and output.

The controller 180 may store the value output from the A / D converter 156, that is, the measured leakage optical power value, in the memory 160 in the first reference value (when visible light is used) or in the second reference value (communication light is used). The difference is calculated (step 340).

Next, the controller 180 compares the difference value in step 340 with the allowable value set by the user through the setting switch 170 again, and if the difference value is larger than the allowable value, the controller 180 turns on the defective LED of the display unit 190 and makes a difference. If the value is smaller than the allowable value, the good LED of the display unit 190 is turned on (step 350).

In this case, if the measurement device uses the communication light as the light source 110, the controller 180 further calculates the loss value of the optical connector 19 by using the leakage target optical power value and the third reference value. Display the value to the user. The loss value of the optical connector 19 can be obtained through a simple proportional expression.

For example, assuming that the reference optical connector and the measurement target optical connector are substantially the same manufactured through the same process, the third reference value (loss value of the reference optical connector / second reference value) = measurement loss value / measurement leakage light Power value '. Therefore, the loss value of the optical connector 19, that is, the measurement target loss value, can be obtained as 'measurement leakage optical power value × third reference value'.

As described above, the present invention artificially bends the optical fiber connected to the field-assembled optical connector so that light leaks from the optical fiber, and by measuring the power of the leakage light, the field operator can more easily and accurately connect the optical connector to the optical fiber. It allows you to judge.

Claims (14)

Light source; An optical adapter connected to the light source and equipped with a field assembly optical connector to be measured; An optical fiber bending guide for forming a bend in the optical fiber connected to the field assembly type optical connector to be measured; A leakage light detector which receives light leaked from the optical fiber bent by the optical fiber bend guide and outputs a value corresponding to the power of the leakage light; And And a control unit for determining whether the optical connector is defective by using the output value of the leakage light detector and at least one preset reference value. The method of claim 1, wherein the light source Loss and defect measuring device of the field assembly optical connector, characterized in that the visible light. The method of claim 2, wherein the control unit The difference between the first reference value and the output value corresponding to the optical power value leaked by incident the visible light after forming a bend using the optical fiber bend guide on the optical fiber of the reference optical connector to which the optical fiber is normally connected is set by the user. Device for measuring the loss and failure of the field-assembled optical connector, characterized in that for determining whether the measurement target optical connector is defective compared to the allowable value. The method of claim 3, wherein the control unit When the difference between the output value and the first reference value is larger than the allowable value, the measurement target optical connector is determined to be defective, characterized in that for measuring the loss and failure of the on-site assembled optical connector. The method of claim 1, wherein the light source Device for measuring the loss and failure of the field assembly type optical connector, characterized in that the communication light of a specific wavelength. The method of claim 5, wherein the control unit The difference between the second reference value and the output value corresponding to the optical power value leaked by injecting the communication light after forming a bend using the optical fiber bending guide to the optical fiber of the reference optical connector to which the optical fiber is normally connected is set by the user. Device for measuring the loss and failure of the field-assembled optical connector, characterized in that it is determined whether or not the measurement target optical connector is compared with the allowable value. The method of claim 6, wherein the control unit When the difference between the output value and the second reference value is larger than the allowable value, the measurement target optical connector is determined to be a failure, and the presence or failure measurement device of the field assembly optical connector, characterized in that. The method of claim 6, wherein the control unit The loss value of the measurement target optical connector is calculated by using a proportional value between the loss value of the reference optical connector and the second reference value measured by injecting the communication light into the optical fiber of the reference optical connector to which the optical fiber is normally connected. Device for measuring the loss and failure of the field assembly optical connector, characterized in that further calculating. A first step of forming a bend in the optical fiber connected to the field assembly optical connector to be measured according to a user's operation, and then applying a light source to the bent optical fiber through the field assembly optical connector to be measured; A second step of detecting a measurement target leakage optical power value leaked from the curved optical fiber by the incidence of the light source; And And a third step of determining whether the measurement target optical connector is defective by comparing the measured leakage optical power value with a preset reference value. The method of claim 9, wherein the light source Method for measuring the loss and failure of the field assembly optical connector, characterized in that the visible light. The method of claim 10, wherein the third step The difference between the first reference value, which is an optical power value leaked by incidence of the visible light, and then the leakage target optical power value measured by the user after forming the bend in the optical fiber of the reference optical connector to which the optical fiber is normally connected; The method for measuring the loss and failure of the field-mounted optical connector, characterized in that for determining whether the measurement of the optical connector is defective. The method of claim 9, wherein the light source Method for measuring the loss and failure of the field-assembled optical connector, characterized in that the communication light of a specific wavelength. The method of claim 12, wherein the third step The difference between the second reference value, which is an optical power value leaked by injecting the communication light, and then the leakage target optical power value after the formation of the bend in the optical fiber of the reference optical connector to which the optical fiber is normally connected; The method for measuring the loss and failure of the field-mounted optical connector, characterized in that for determining whether the measurement of the optical connector is defective. The method of claim 13, The loss value of the measurement target optical connector is calculated by using a proportional value between the loss value of the reference optical connector and the second reference value measured by injecting the communication light into the optical fiber of the reference optical connector to which the optical fiber is normally connected. The method of measuring the loss and failure of the field assembly optical connector, characterized in that it further comprises a fourth step of calculating.

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