KR200284994Y1 - optical output control device of the optical interface board - Google Patents

Abstract

The present invention receives an optical signal transmitted from an opposing unit connected to another region through an optical cable and converts and outputs the optical signal into an electrical signal, and provides an optical interface with an electrical signal according to the optical signal input from the optical transmitter and receiver. In addition, an optical driver for determining an input optical signal detection signal and controlling the optical signal output according to the result, an optical output unit for photoelectric conversion and outputting the optical signal according to the optical signal control signal of the optical driver, and the optical output A three-port circulator for transmitting the optical signal outputted from the unit to the opposing device portion through an optical cable, receiving the reflected and returned optical signal, and outputting it to another port; and the light reflected from the opposing device portion through the three-port circulator. Provided is an optical output control apparatus for an optical interface board including a light detector for detecting a signal and outputting the signal to an optical driver.

The present invention as described above, by mounting a three-port circulator on the optical signal interface to detect that the optical signal other than the normal optical signal output to the outside, thereby minimizing the risk of the operator due to abnormal optical signal output accordingly It significantly improves operational stability, and selectively detects and blocks only abnormal optical signal outputs exposed to the outside through a simple circuit configuration, thereby improving the functionality of the optical interface board.

Description

Optical output control device of the optical interface board

The present invention relates to an optical output control apparatus of an optical interface board, and in particular, by mounting a three-port circulator on the optical signal interface, the optical output board of the optical interface board that detects that an optical signal other than the normal optical signal output is blocked to the outside. Relates to a device.

In general, the optical communication method is a technology that has been rapidly used in the field of the transmission network or international communication lines due to the rapid development of the technology and advantages such as low loss, broadband, light weight, induction of optical fiber. In particular, the optical communication method as described above uses an optical cable composed of an optical fiber. In this case, an optical transmission system is required to transmit a signal through the optical cable. Such an optical transmission system typically uses any one of wavelength division (WD), space division (SD), time division (TD), and free space division (FD), depending on the implementation method. For example, such an optical transmission system may be configured with, for example, an Asynchronous Transfer Mode (ATM) Passive Optical Network (PON) network using a time division scheme.

By the way, such an optical transmission system usually includes an optical interface board for interfacing the optical signal to transmit and receive the optical signal through the optical cable. Such an optical interface device is limited to prevent the optical signal output from being unnecessarily exposed to the outside. Regulations are established (see Standards 21CFR 1040.10 and 1040.11).

Then, referring to the optical output control device of the conventional optical interface board as described above with reference to Figure 1, the optical transmission and reception unit 71 for receiving and converting the optical signal transmitted from the opposing device unit 70 into an electrical signal, An optical driver 72 for controlling the optical interface function of the electrical signal according to the optical signal input from the optical transmitter / receiver 71 and photoelectric conversion according to the optical interface control signal of the optical driver 72 to output an optical signal. The light output unit 73 outputs to the counter device unit 70.

Here, the light output unit 73 uses a laser diode (LD).

On the other hand, referring to the operation of the optical output control device of the conventional optical interface board as described above, when the optical signal is input from the counter device unit 70 to perform the optical interface, the optical transmitter / receiver 71 receives the input optical signal. The signal is converted into an electrical signal and output to the optical driver 72. Then, the optical driver 72 controls the optical output unit 73 by an electric signal according to the optical input signal input from the optical transmitter / receiver 3 to transmit the corresponding optical signal output to the counter device unit 70. Drive.

At this time, when there is no optical signal input from the counter device 70 during the process, the optical driver 72 of the conventional optical output control device 74 is blocked so that the optical output unit 73 does not generate the optical signal output ( Shut-down) makes the operator stable.

However, since the optical driver shuts down the optical output unit, that is, the LD only when there is no optical signal input in the conventional optical interface board, the optical signal output is not connected to the opposing unit. In this case, for example, the 2.5Gbps optical signal output is exposed to the outside, which poses a serious threat to the stability of the operator. In addition, the optical signal output cannot be properly controlled as needed in the optical interface. There was also a problem that is considerably degraded.

Therefore, the present invention is designed to solve the conventional problems as described above, and by mounting a three-port circulator on the optical signal interface to detect that an optical signal other than the normal optical signal output is output to the outside, thereby preventing abnormal optical signal output. The purpose of the present invention is to provide a light output control apparatus of an optical interface board, which minimizes the risk of the operator, thereby significantly improving the operational stability of the operator.

Another object of the present invention is to provide a light output control apparatus for an optical interface board, which selectively detects and blocks only an abnormal optical signal output exposed to the outside with a simple circuit configuration, thereby improving the functionality of the optical interface board.

The present invention for achieving the above object is an optical transmission and reception unit for receiving and converting the optical signal transmitted from the opposing unit connected to the other region via an optical cable to the electrical signal, and the optical signal input from the optical transmission and reception unit And an optical driver for controlling the optical signal output based on the result of the determination of the input optical signal detection signal along with the optical interface of the electrical signal, and outputting the optical signal by photoelectric conversion according to the optical signal control signal of the optical driver. An optical output unit, a three-port circulator for transmitting the optical signal output from the optical output unit to the opposing unit through an optical cable, receiving the reflected and returned optical signal, and outputting it to another port; Light of the optical interface board including a light detection unit for detecting the optical signal reflected from the opposing unit through the output to the optical driver It provides a power control apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS Explanatory drawing explaining the optical output control apparatus of the conventional optical interface board.

2 is an explanatory diagram illustrating an optical output control device of the present invention.

<Detailed Description of Codes>

1: optical cable 2: counter device

3: optical transmitter and receiver 4: optical driver

5: light output unit 6: 3 port circulator

7: light detection unit 8: light output control device

port1: Input port port2: Output port port3: 3 port port

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

The apparatus of the present invention receives an optical signal transmitted from the opposing device unit 2 connected to the other region via the optical cable 1 as shown in FIG. 2 and converts and outputs the electrical signal into an electrical signal. An optical driver 4 for interfacing the electrical signal according to the optical signal input from the optical transmitter / receiver 3 and determining the input optical signal detection signal and controlling the output of the optical signal according to the result; and the optical driver An optical output unit 5 for photoelectric conversion in accordance with the optical signal control signal of (4) and outputting an optical signal, and transmitting the optical signal output from the optical output unit 5 to the opposing device unit 2 via an optical cable; And a three-port circulator 6 that receives the reflected and returned optical signal and outputs it to another port, and detects the optical signal reflected from the opposing unit 2 through the three-port circulator 6 And a photodetector 7 for outputting to the driver 4.

Here, the light output unit 5 uses a laser diode (LD). The photodetector 7 is composed of a photo diode (PD). In addition, the three-port circulator is composed of an input port (port1), an output port (port2) and a three-port port (port3) for outputting the optical signal received by being reflected through the output terminal (7).

Next, the operation and effects of the present invention as described above will be described.

The apparatus of the present invention, when the optical signal is input through the optical cable (1) from the opposing device portion (2) installed at a predetermined distance for the optical interface, the optical signal is the optical transmission and reception part (3) of the optical output control device (8) Is received. The optical transmitter / receiver 3 converts the optical signal input from the counter device 2 into an electrical signal and outputs the electrical signal to the optical driver 4. Then, the optical driver 4 controls the optical output unit 5 by an electric signal according to the optical input signal input from the optical transmitter / receiver 3 to output the corresponding optical signal output to the three-port circulator 6. To drive. Here, in the optical interface process as described above, since the optical transmitter / receiver 3 receives the optical signal input from the counter device 2, the optical detector 7 is ignored even if the optical detection signal of the optical detector 7 becomes “low”. 5). However, when there is no optical signal input from the counter device 2 during the process, the optical driver 4 shuts down the optical output unit 5 so as not to generate an optical signal output as in the related art. .

In addition, in addition to the above process, the optical output control device 8 according to the present invention has a three-port circulator 6 when the optical output unit 5 outputs an optical signal output to the counter device unit 2. Will be entered. Then, the three-port circulator 6 transmits the optical signal output input through the input terminal prot1 to the counter device unit 2 through the output terminal port2 and the optical cable 1.

At this time, when the opposing device unit 2 receives the optical signal, the optical device 1 reflects the optical signal according to the reception back to the transmission partner through the optical cable 1, and the three-port circulator 6 reflects the reflected optical signal. ) Is received and output to the photodetector 7 through three ports. Then, the photodetector 7 outputs a high signal high to the optical driver 4 according to the photodetection signal input from the three-port circulator 6.

Accordingly, the optical driver 4 determines that a normal optical signal is being output to the counter device unit 2 according to the light detection signal of the "high signal" input from the current light detection unit 7 and continues to the light output unit 5. ).

However, during the above process, if there is no optical signal input from the optical transmitter / receiver 3 and no optical signal is output to the counter device 2, the three-port circulator 6 reflects the reflected light from the counter device 2. Since no signal is received, the detection signal is not output to the photodetector 7. Therefore, the photodetector 7 outputs a "low signal" to the optical driver 4. Then, the optical driver 4 determines that there is no light output signal currently in operation according to the input low signal of the photodetector 7 to shut down the driving of the light output unit 5. Therefore, the optical output section 5 does not output any optical signal when the system is not in operation.

As described above, the present invention is equipped with a three-port circulator on the optical signal interface to block the detection of optical signals other than the normal optical signal output, thereby minimizing the operator's risk due to abnormal optical signal output. It has the advantage of significantly improving the operational stability of the operator.

In addition, according to the present invention, since only the abnormal optical signal output exposed to the outside is selectively detected and blocked by a simple circuit configuration, there is also an effect of improving the functionality of the optical interface board.

Claims (2)

Optical transmission and reception unit for receiving and converting the optical signal transmitted from the opposing unit connected to the other region through the optical cable to the electrical signal, and the optical signal input along with the optical interface according to the optical signal input from the optical transmission and reception unit An optical driver for determining an optical signal detection signal and controlling an optical signal output according to the result, an optical output unit for photoelectric conversion and outputting an optical signal according to the optical signal control signal of the optical driver, and outputting from the optical output unit A three-port circulator for transmitting the received optical signal to the opposing unit through an optical cable and receiving the reflected and returned optical signal to another port; and detecting the optical signal reflected from the opposing unit through the three-port circulator And an optical detector for outputting the optical driver to the optical driver. The apparatus of claim 1, wherein the photodetector comprises a photodiode.