WO2013176314A1 - Simplified optical fiber identifier - Google Patents

Abstract

According to the present invention, a simplified optical fiber identifier for measuring optical signals includes: an insertion unit into which an optical cable or an optical connector is inserted; a receiving unit that receives the wavelength of the optical signal from the optical cable or the optical connector inserted into the insertion unit; a conversion unit that converts the optical signal wavelength received from the receiving unit into an electrical signal; a control unit that processes the electrical signal converted in the conversion unit; an output unit that outputs the results processed in the control unit; and an electrical power supply unit that supplies electrical power.

Description

Simple optical core contraster

The present invention relates to a simple optical core contraster, and more particularly, to a simple optical core contraster that can secure the reliability of optical communication by simply measuring the optical signal transmitted and received through the optical cable.

As optical communication technology develops, FTTH (Fiber to the home), which is more advanced than fiber to the office (FTTO), is being commercialized. FTTH is a technology that makes all the services including super-high speed by connecting all the wires to the optical network by building the optical cable to the last terminal device, also called home optical cable or home optical cable. FTTH is more than 100 times faster than ADSL by connecting optical cables to homes. There is a feature that can provide a stable quality service.

Since the optical cable used in the configuration of the FTTH network has good reception to ensure the reliability of the network, it is essential to measure the reception to ensure the reliability of the optical cable when installing and maintaining the FTTH network.

At this time, the optical fiber collimator for measuring the reception of the optical cable has a disadvantage that most of the equipment developed and produced by overseas AFL Telecommunication (NOYES), Fujikura, etc. and expensive.

In addition, the conventional optical core collimator has a disadvantage in that the thickness of the optical cable that can be measured is limited, and thus the optical signal measurement of the thick optical cable is limited. In order to remedy the above disadvantages, there was an optical core contraster that provides an adapter capable of measuring a thick optical cable, but in this case, it was inconvenient because an additional adapter was taken.

In addition, the conventional optical fiber collimator has a disadvantage in that the optical connector cannot be measured.

Since the introduction of optical cables in Korea, laser (LD), photoreceptor (PD) technology, photoelectric conversion technology, etc., which are the core technologies of optical measuring equipment, have become common in Korea. I can't do it.

An object of the present invention is to provide a simple optical core contraster that can measure the signal for a variety of thickness and low-cost optical cable in order to compensate for the above-mentioned disadvantages.

Simple optical core line contraster of the present invention for solving the above-mentioned conventional problems and to achieve the above object,

An insertion unit to insert an optical cable or an optical connector; A receiver which receives an optical signal wavelength of an optical cable and an optical connector inserted into the insertion unit; A converting unit converting the optical signal wavelength received by the receiving unit into an electrical signal; A controller which processes the electric signal converted by the converter; An output unit for outputting a result processed by the control unit; And a power supply for supplying power; characterized in that it comprises a.

Here, the insertion portion is characterized in that it comprises grooves for inserting the optical cable having various thicknesses in the range of 0.3mm ~ 3.0mm.

In addition, the receiver is characterized in that for receiving an optical signal wavelength of 1250nm ~ 1650nm.

According to such a feature of the present invention, the simple optical core collimator of the present invention measures the optical signal and wavelength flowing through the optical cable, and there is an effect that it is possible to measure the optical signal of optical cables and optical connectors of various thicknesses.

1 is a hardware block diagram of a simplified optical fiber contraster according to the present invention.

2 is a perspective view of a simplified optical fiber contraster according to the present invention.

Figure 3 is a perspective view of the insertion portion of the simple optical fiber collimator according to the present invention.

4 is a flowchart for measuring an optical signal wavelength of an optical cable using the simplified optical fiber contraster of the present invention.

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

1 is a block diagram illustrating the hardware configuration of a simplified optical fiber contraster according to the present invention.

As shown in FIG. 1, the hardware of the simple optical fiber collimator of the present invention includes a receiver 10, a converter 20, a controller 40, a power supply unit 30, and an output unit 50.

The receiver 10 is an optional filter for receiving an optical signal wavelength flowing through the optical cable to be measured, and the receiver 10 receives an optical signal wavelength in the range of 1250 nm to 1650 nm flowing through the optical cable.

The conversion unit 20 is an optical / electric conversion unit that receives an optical signal wavelength received by the reception unit 10 and converts the optical signal wavelength into an electrical signal.

The control unit 40 processes an electrical signal converted into an electrical signal by the conversion unit 20, and performs and manages a power management and a process according to an input (Micro Controller Unit; MCU). to be.

The power supply unit 30 supplies power to the conversion unit 20 and the control unit 40. In the present invention, two batteries of 1.5V are used. It is obvious that the circuit configuration may be changed by supplying power using other power sources.

The output unit 50 outputs the information processed by the control unit 40 to the LCD substrate.

2 is a perspective view of a simplified optical fiber collimator according to the present invention, and FIG. 3 is an insertion portion of the simplified optical fiber collimator according to the present invention.

As shown in FIG. 2, the simplified optical fiber collimator of the present invention includes an insertion unit 60, an output unit 50, and an input unit 70.

The insertion unit 60 is configured in various grooves to measure the optical cable and optical connector of various thicknesses as shown in FIG. At this time, the thickness (diameter) of the optical cable that can be inserted and measured in the insertion unit 60 ranges from 0.3 mm to 3.0 mm, and a rectangular optical connector and a circular optical connector may be inserted, but are not limited thereto.

As shown in FIG. 3, the optical cable is measured by inserting the optical cable diagonally into the first grooves 60a and 60a ', the second grooves 60b and 60b', and the third grooves 60c and 60c '. The rectangular optical connector and the circular optical connector are inserted into the fourth groove 60d to measure the optical signal wavelength.

Here, the output unit 50 outputs a result of the optical signal wavelength received from the optical cable inserted into the insertion unit 60 is converted into an electrical signal in the conversion unit 20 is processed by the control unit 40. In an exemplary embodiment of the present invention, the LCD is configured as an output unit, but is not limited thereto. In this case, the output unit 50 displays transmission power, traffic, and the like of an optical signal flowing through the received optical cable.

In addition, the input unit 70 is configured to include one or more buttons that can be selected and manipulated by the user, the input is processed by the control unit 40 by pressing the button to perform a corresponding operation corresponding to the input The result of the execution is output to the output unit 50.

In the present invention, a power button, an output unit backlight button and the like are taken as examples, but the buttons are not limited and additionally necessary buttons and operations may be additionally configured.

4 is a flowchart for measuring an optical signal wavelength of an optical cable using the simplified optical fiber contraster of the present invention.

As shown in FIG. 4, the simple optical fiber collimator of the present invention controls the flow of the optical signal wavelength until it is received by the receiver 10 and output to the output unit 50. The process flow chart includes the start (S1), the step of receiving / measuring a signal wavelength (S2), the step of converting it into an electrical signal (S3), the step of checking whether an electric current is input (S4), and the calculating of a measured value (S5). , Comparing with a reference value (S6), and outputting to an output unit (S7).

First, the process starts by inserting the measurement target optical cable or optical connector into the insertion unit 60 of the simplified optical fiber contraster of the present invention (S1).

Subsequently, in the step of receiving / measuring the signal wavelength (S2), the receiver 10 receives the optical signal wavelength flowing through the measurement target optical cable or the optical connector inserted into the inserter 60, and the value received by the receiver 10. The process of handing over to the conversion unit 20 is performed.

Subsequently, in the step S3 of converting to an electrical signal, a process of converting an optical signal wavelength received by the receiver 10 and transmitted to the converter 20 into an electrical signal is performed.

Next, in step S4 of checking whether or not the current is input, it is checked whether or not the current is input. In this case, when the power is turned on, the process moves to the step S6 of comparing with the reference value, and when the power is turned off, the process goes to the step S7 of outputting to the output unit 50.

When the input of the current is confirmed while the power is turned on and the process moves to step S5 of comparing with the reference value, step S5 of calculating a measured value is first performed, and then step S6 of comparing with the reference value is performed. Done. At this time, in calculating the measured value (S5) is a step of calculating the value of the signal received by the receiver 10 and converted into an electrical signal. In this step, the measured electrical signal is mathematically calculated and calculated.

Next, in the step S6 of comparing with the reference value, the value calculated in the step S5 of calculating the measured value is compared with the reference value stored in the controller 40 to determine whether an appropriate optical signal wavelength is flowing. Check it.

Finally, in step S7 of outputting to the output unit, the value determined in step S6 of comparing with the reference value is output. In addition, when it is confirmed that the power is turned off in the step S4 of checking whether the current is inputted, the flow of the software is completed by outputting nothing to the output unit 50.

As described above, in the detailed description of the present invention has been described with respect to preferred embodiments of the present invention, those skilled in the art to which the present invention pertains various modifications without departing from the scope of the present invention Of course this is possible. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents thereof, as well as the following claims.

Claims (3)

1. In the simple optical core contraster for measuring the optical signal,

   An insertion unit to insert an optical cable or an optical connector;

   A receiver which receives an optical signal wavelength of an optical cable and an optical connector inserted into the insertion unit;

   A converting unit converting the optical signal wavelength received by the receiving unit into an electrical signal;

   A controller which processes the electric signal converted by the converter;

   An output unit for outputting a result processed by the control unit; And

   And a power supply unit for supplying power.
2. The method of claim 1,

   And the insertion part includes grooves for inserting optical cables having various thicknesses in a range of 0.3 mm to 3.0 mm.
3. The method of claim 1,

   The receiver is a simple optical core contraster, characterized in that for receiving an optical signal wavelength of 1250nm ~ 1650nm.

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