KR100628838B1 - Optical signal detector - Google Patents

Abstract

The present invention relates to an optical signal detection device that detects and visually displays an optical signal transmitted through an optical cable while interconnecting optical cables, and includes a left end portion of the first optical cable 311 from the left external optical cable 10 '. The optical signal input through (A) is detected by the second optical signal detection sensor 332 and visually displayed to the outside through the second output unit 342, and the first optical cable (from the right external optical cable 10 " Since the optical signal input through the right front end portion B of 312 is detected by the first optical signal detection sensor 331 and visually displayed to the outside through the first output unit 341, separate optical equipment is used. Even if not, anyone can easily grasp the failure of the optical line in real time quickly, and the location of the abnormality can be quickly and conveniently.

Description

Optical signal detector

1 is a view showing a state in which an optical signal detection apparatus according to the present invention is applied,

2 is a view showing an optical signal detection apparatus according to the present invention;

3 is a front sectional view showing an enlarged optical cable coupler shown in FIG.

Figure 4 is an enlarged side cross-sectional view of the junction shown in Figure 3,

5 is a view showing another example of the optical signal detection apparatus according to the present invention.

-Explanation of terms for the main parts of the accompanying drawings-

10,10 ', 10 "; optical cable, 21,22,23,24; electrical signal communication line,

100; Optical network units (ONUs),

210,220,230,240; Communication device, 300; Optical signal detection device,

310; Optical cable couplers, 311; First optical cable,

312; Second optical cables 311a and 312a; core,

311b, 312b; Clad, 311c, 312c; jacket,

313; Junction protection, 313a; First cover,

313b; Second cover, 321,322; Optical cable adapter,

331,332; Optical signal detection sensors, 341,342; Output unit,

351,352; Optical filter.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical signal detection device, and more particularly, to an optical signal detection device that detects and visually displays an optical signal transmitted through an optical cable.

As is well known, various multimedia services such as Internet traffic, VOD, EOD, etc. are increasing, and the demand for ultra-high speed and large capacity optical transmission network is increasing.

The optical transmission network is divided into a hybrid network using coaxial and optical cables, and an FTTH (Fiber-To-The-Home), which constructs a network by embedding optical cables in each home.

In the optical transmission network, a large amount of data signals are transmitted at high speed through an optical cable, so that an obstacle in the optical line causes huge loss.

Therefore, in order to minimize the damage caused by the optical line failure in the high-speed transmission network, it is necessary to quickly identify the facts and locations of the optical line failure and recover quickly.

To this end, conventionally, an optical power meter is used to grasp an abnormality of optical signal transmission and an optical time domain reflectometer (OTDR) is used to grasp the position of an abnormal occurrence part.

However, according to this conventional method, when an optical line failure occurs, an expensive specific equipment (optical equipment such as an optical power meter, an optical fiber tester, etc.) must be used to identify the optical line failure. The problem of finding the location of anomaly was quite cumbersome and difficult.

Moreover, since users or ordinary people using the optical transmission network cannot grasp the optical line failure facts, it is virtually impossible to quickly cope with the optical line failure, resulting in a huge loss.

Accordingly, the present invention has been invented to solve the above problems, and an object of the present invention is to provide an optical signal detection apparatus that allows anyone to easily visually recognize the state of optical signal transmission through the optical cable while interconnecting the optical cables.

According to the present invention for achieving the above object, the clad exposed portions of the first and second optical cables from which the jacket has been removed are bonded in parallel to each other, and the bonded portions are enclosed and sealed by the joint portion protection material, so that the jacket is clad. An optical cable coupler in which both ends of the first and second optical cables surrounding the cable are exposed to the outside from the joint protection material, respectively; A pair of optical cable adapters respectively provided at both ends of the first optical cable constituting the optical cable coupler and interconnecting the first optical cable and the external optical cable; A pair of optical signal detection sensors which are respectively provided at both front end portions of the second optical cable constituting the optical cable coupler, converting the optical signal input from the front end portion into an electrical signal and outputting the electrical signal to the output unit; Operation is controlled by the optical signal detection sensor, and has a structure characterized in that it consists of a pair of output units for visually outputting the optical signal detection state of the optical signal detection sensor to the outside.

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

1 is a view showing a state in which the optical signal detection apparatus 300 according to the present invention is applied to the optical transmission network, accordingly, the optical signal detection device (a) in the optical cable 10 connected to the optical network termination device 100 ( 300 is installed, and various communication devices 210, 220, 230, and 240 are connected to the optical network termination device 100 through electrical signal communication lines 21, 22, 23, and 24, such as copper cables.

The optical network termination device 100 converts an optical signal from the optical cable 10 into an electrical signal and transmits the electrical signal to the electrical signal communication lines 21, 22, 23, and 24, and the electrical signal communication lines 21, 22, and 23. And a signal conversion device for converting an electrical signal from the signal 24 into an optical signal and transmitting the optical signal to the optical cable 10.

The optical signal detecting apparatus 300 according to the present invention includes a clad exposed portion C of the first and second optical cables 311 and 312 from which the jackets 311c and 312c have been removed, as shown in FIGS. C ′) are bonded in parallel to each other, and the joint portion is sealed by being bonded by the joint portion protection material 313, so that the jacket 311c; 312c wraps the cladding 311b; 312b to the first and second optical cables 311 An optical cable coupler 310 in which both front end portions A, B; A ', B' of the 312 are respectively exposed to the outside from the joint protection material 313; It is provided at both front end portions (A, B) of the first optical cable 311 constituting the optical cable coupler 310, and interconnects the first optical cable 311 and the external optical cable (10; 10 ', 10 ") A pair of optical cable adapters 321 and 322, which are respectively provided at both front end portions A 'and B' of the second optical cable 312 constituting the optical cable coupler 310, from the corresponding front end portions A 'and B'. A pair of optical signal detection sensors 331 and 332 for converting an input optical signal into an electrical signal and outputting the electrical signal to the output units 341 and 342, and controlled by the optical signal detection sensors 331 and 332, and corresponding optical signal detection sensors ( And a pair of output units 341 and 342 for visually outputting the optical signal detection state of the devices 331 and 332 to the outside.

The optical cable coupler 310 is a component for distributing an optical signal from one place to several places or assembling an optical signal from several places into one place. In this embodiment, a coupler manufacturing apparatus having a micro heater is used. The optical cable coupler 310 as shown in FIG. 3 was used.

The manufacturing method thereof is outlined in the order of process as follows.

1. After cutting the first optical cable 311 and the second optical cable 312 to an appropriate length, the jacket 311c (312c) of the clad exposed portion (C; C ') is removed using a coupler stripper.

2. Fix both ends of the first optical cable 311 and the second optical cable 312 to the coupler manufacturing apparatus, and inspect whether the optical fiber is properly fixed through the microscope.

3. Cut both ends of the first and second optical cables 311 and 312 by the cleave method.

4. Couple a light source to the input tip (A) and a photodetector to the two output tips (B, B ').

5. The coupler manufacturing apparatus is operated so that the clad exposed portions C and C 'of the first and second optical cables 311 and 312 are joined in parallel to each other by a micro heater.

6. The first and second optical cables 311 and 312 having the clad exposed portions C and C 'fused to each other are introduced into the cylindrical first cover 313a made of quartz, and then the first and second optical cables are connected to the first and second optical cables. Both front end portions of the optical cables 311 and 312 and the first cover 313a are sealed.

7. After inserting the first cover 313a into the second metal cover 313b made of metal, sealing the tip openings between the second cover 313b and the first cover 313a through epoxy, The optical cable coupler 310 is completed.

Note that in the present invention, since the first optical cable 311 is used for the optical signal transmission and the second optical cable 312 is used for the optical signal detection, the left side of the first optical cable 311 is used. When the optical signal is input to the front end portion (A), most of the optical signal is output to the right front end portion (B) of the first optical cable 311, only a very small portion of the optical signal for detecting the optical signal of the second optical cable 312 It should be output to the right end part (B ') of. At this time, since the optical signal lost to the left end portion A 'of the second optical cable 312 is extremely small compared to the optical signal outputted to the right end portion B' of the second optical cable 312, Will be ignored. Conversely, when an optical signal is input to the right front end portion B of the first optical cable 311, most of the optical signals are output to the left front end portion A of the first optical cable 311, and are extremely used for optical signal detection. Only a part of the optical signal should be output to the left front end portion A 'of the second optical cable 312. In this case, too, the slight optical signal loss lost to the right front end portion B 'of the second optical cable 312 will be ignored.

On the other hand, in the present embodiment, although the bonding portion protection material 313 consisting of the first cover 313a and the second cover 313b is used, the bonding portion protection material 313 used in the present invention is not limited thereto. Any known material that can safely protect the junction of the first and second optical cables 311 and 312 can be applied without affecting the transmission of the optical signal.

According to the present invention, the optical signal input from the left external optical cable 10 'through the left front end portion A of the first optical cable 311 is detected by the second optical signal detection sensor 332 and the second output unit ( 342 is visually displayed to the outside and the optical signal input from the right external optical cable 10 "through the right front end portion B of the first optical cable 312 is detected by the first optical signal detection sensor 331. Since it is visible to the outside through the first output unit (341), even if no separate optical equipment, anyone can easily grasp the failure of the optical line in real time quickly, and the location of the abnormality is also quick and convenient I can figure it out.

On the other hand, when the optical signal is input to the left end portion (A) of the first optical cable 311, the first optical signal detection sensor due to the optical signal loss to the left end portion (A ') of the second optical cable 312 When 331 and the first output unit 341 malfunction or an optical signal is input to the right front end portion B of the first optical cable 311, the first front unit 341 goes to the right front end portion B 'of the second optical cable 312. There is a risk that the problem of malfunction of the second optical signal detection sensor 332 and the second output unit 342 due to the optical signal loss of may occur.

However, in this case, as shown in FIG. 5, between the front end portions A 'and B' of the second optical cable 312 constituting the optical cable coupler 310 and the corresponding optical signal detection sensors 331 and 332. When the optical filters 351 and 352 selectively transmit only a predetermined wavelength band, the optical signal detection sensors 331 and 332 and the output units 341 and 342 may be easily solved due to the optical signal loss.

For reference, the optical signal input to the left front end portion A of the first optical cable 311 and the optical signal input to the right front end portion B of the first optical cable 311 may be bidirectional optical signal transmission. Their wavelength bands are different. For example, when the optical signal input to the left front end portion A of the first optical cable 311 is 1310 nm, an optical signal of 1550 nm is input to the right front end portion B of the first optical cable 311, Two-way optical signal transmission is smoothly performed. Therefore, in this case, the first optical filter 351 passes only the optical signal in the 1550 nm wavelength band, and the second optical filter 352 passes only the 1310 nm wavelength band, resulting in the loss of the optical signal transmitted in the reverse direction. The optical signal detection sensors 331 and 332 should not be malfunctioned.

The present invention is not limited to the above embodiments, and of course, various modifications can be made without departing from the scope of the following claims.

For example, using the optical cable coupler 310, a pair of optical signal detection sensors (331, 332) and a pair of output units (341, 342) as a unit unit, two or more unit units in both optical cable adapters (321, 322) By installing and correspondingly connecting the optical cables (10; 10 ', 10 "), it is possible to grasp the transmission state of a plurality of optical lines.

According to the present invention as described above, the optical signal input through the left end portion (A) of the first optical cable 311 from the left external optical cable 10 'is detected by the second optical signal detection sensor 332 The optical signal, which is visually displayed to the outside through the second output unit 342, and is input from the right external optical cable 10 ″ through the right front end portion B of the first optical cable 312, is detected by the first optical signal detection sensor ( 331 is detected and visible to the outside through the first output unit 341, so that anyone can easily determine in real time whether or not the failure of the optical line, even if no separate optical equipment, The location of occurrence can also be quickly and conveniently identified.

Therefore, when the optical line failure occurs, it is possible to quickly recover it, thereby greatly reducing the loss due to the optical line failure.

Claims (2)

The clad exposed portions C and C 'of the first and second optical cables 311 and 312 from which the jackets 311c and 312c have been removed are joined in parallel to each other, and the bonding portions are wrapped through the joint portion protection material 313. Both ends of the first and second optical cables 311 and 312 in which the jackets 311c and 312c surround the clads 311b and 312b are sealed to each other at the joint portions protective material (A, B; A ', B'). An optical cable coupler 310 exposed to the outside from 313; It is provided at both front end portions (A, B) of the first optical cable 311 constituting the optical cable coupler 310, and interconnects the first optical cable 311 and the external optical cable (10; 10 ', 10 ") A pair of optical cable adapters 321 and 322; It is provided at both front end portions A 'and B' of the second optical cable 312 constituting the optical cable coupler 310, and the optical signals inputted from the front end portions A 'and B' are converted into electrical signals. A pair of optical signal detection sensors 331 and 332 which are converted and output to the output units 341 and 342; The optical signal detection sensor (331,332) by the operation control, characterized in that composed of a pair of output unit (341,342) for visually outputting the optical signal detection state of the optical signal detection sensor (331; 332) Signal detection device. The method according to claim 1, wherein only a predetermined wavelength band is selected between both front end portions A 'and B' of the second optical cable 312 constituting the optical cable coupler 310 and the optical signal detection sensors 331 and 332. Optical signal detection device, characterized in that the optical filter (351,352) for transmitting through.

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