KR200307450Y1 - Optical Power Measuring Apparatus - Google Patents

Abstract

An object of the present invention is to measure the magnitude of an optical signal transmitted between optical transmission apparatuses of an optical transmission system, and to automatically and easily measure the optical signal strength without interrupting the optical transmission service, so that the user can easily understand it. An object of the present invention is to provide an optical signal intensity measuring apparatus.

The configuration of the present invention, in the device for measuring the magnitude of the optical signal transmitted from the first optical transmission device 100 to the second optical transmission device 200, receives the optical signal transmitted from the first optical transmission device 100 A photoelectric conversion unit 10 converting and outputting an electrical signal; An optical signal extraction unit 20 which receives an electric signal output from the photoelectric conversion unit 10, extracts a part of the electrical signal, and amplifies and outputs a signal having a predetermined size; A unit converter 30 which receives the signal output from the optical signal extractor 20 and converts the measured value into decibel units and outputs the converted signal; An analog-to-digital converter 40 for receiving a signal output from the unit converter 30 and converting the signal into a digital signal and outputting the digital signal; It includes an address encoder 50 for receiving a signal output from the analog-to-digital converter 40 to express a value that is easy for the user to recognize.

Description

Optical signal strength measuring device {Optical Power Measuring Apparatus}

The present invention relates to an optical signal intensity measuring apparatus, and more specifically, in measuring the magnitude of an optical signal transmitted between optical transmission apparatuses of an optical transmission system, the optical signal strength is not changed without interrupting the optical transmission service. The present invention relates to an optical signal strength measuring apparatus that informs a user by easily and accurately measuring.

Of the transmitters, STM-1, STM-4, and STM-16 grades, which handle more than 155 megabits (Mbps), use data modules to transmit data. send.

In this case, digital transmitters transmit digital signals within the respective transmitters, but each transmitter transmits an optical signal, and the signal must be at least a certain size to transmit a long distance without loss or distortion of data. .

At this time, in checking the normal state of the data, the intensity of the optical signal input and output is the most important check factor, because the normal value can be output even if the signal is converted to a digital signal when the power is properly output. .

Therefore, the operator of the optical transmission system should check the state of the transmission service by measuring the strength of the optical signal from time to time.

Hereinafter, an optical signal intensity measuring method according to the related art will be described with reference to the accompanying drawings.

As shown in Fig. 1, in the prior art, a separate optical power measuring device is mounted to measure an optical signal between the optical transmission devices.

That is, to measure the magnitude of an optical signal transmitted from the first optical transmission device 1 to the second optical transmission device 2 or an optical signal transmitted from the second optical transmission device 2 to the first optical transmission device 1. In this case, the optical transmission is stopped and the optical signal transmitted in the middle of the line is pulled, and a method of measuring the intensity of the optical signal using the separate optical power measuring device 3 is used.

By the way, the measurement method as described above has to stop and perform the optical transmission service, there is a problem that reduces the quality of the service.

Accordingly, instead of measuring the intensity of the optical signal transmitted while the optical transmission is in progress, the optical signal transmitted from one optical transmission device of the optical transmission system is all received and the magnitude thereof is measured, thus the size of the optical signal transmitted from the optical transmission system. Can not measure accurately, it only measures the transmission status of one optical transmitter.

In addition, the optical signal measuring method of the prior art as described above requires an expensive optical power measuring device, and because it requires a separate optical connector for connecting in order to pull the optical signal on the transmission line, the optical signal There is a problem that the cost of measuring the intensity is expensive.

In addition, in the optical signal measuring method of the prior art as described above, the measurement preparation work is cumbersome and inconvenient because it must be performed by disconnecting and connecting the transmission line manually whenever measurement is required.

In addition, in connecting the optical power measuring device to the optical transmission device, it is necessary to adjust the characteristics of the equipment so that accurate measurement values are obtained. This task is also cumbersome and inconvenient, and if the adjustment is incorrect, the reliability of the measured values There is a problem falling.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, in measuring the size of the optical signal transmitted between the optical transmission apparatus of the optical transmission system, without stopping the optical transmission service, the optical automatically An object of the present invention is to provide an optical signal strength measuring apparatus that easily and accurately measures signal strength to inform a user.

1 is a block diagram applying the optical signal strength measuring method according to the prior art,

2 is a block diagram to which an optical signal intensity measuring apparatus according to an embodiment of the present invention is applied.

Explanation of symbols on the main parts of the drawings

10: photoelectric conversion unit 20: optical signal extraction unit

30: unit converter 40: analog-to-digital converter

50: address encoder

The configuration of the present invention for achieving the above object is made as follows.

An apparatus for measuring the magnitude of an optical signal transmitted from a first optical transmission device to a second optical transmission device,

Photoelectric conversion means for receiving an optical signal transmitted from the first optical transmission device and converting the optical signal into an electrical signal;

Optical signal extraction means for receiving an electric signal outputted from the photoelectric conversion means, extracting a part, and amplifying and outputting a signal having a predetermined size;

Unit conversion means for receiving a signal output from the amplifying means and converting the measured value into decibel units and outputting the measured signal;

An analog-digital converting means for receiving a signal output from the unit converting means and converting the signal into a digital signal;

And an encoding means for receiving a signal output from the analog-digital conversion means and expressing the signal as a value easily understood by the user.

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

As shown in Figure 2, the configuration of the optical signal strength measuring apparatus according to an embodiment of the present invention is made as follows.

In the device for measuring the magnitude of the optical signal transmitted from the first optical transmission device 100 to the second optical transmission device 200,

A photoelectric conversion unit 10 which receives an optical signal transmitted from the first optical transmission device 100 and converts the optical signal into an electrical signal and outputs the electrical signal;

An optical signal extraction unit 20 which receives an electric signal output from the photoelectric conversion unit 10, extracts a part of the electrical signal, and amplifies and outputs a signal having a predetermined size;

A unit converter 30 which receives the signal output from the optical signal extractor 20 and converts the measured value into decibel units and outputs the converted signal;

An analog-to-digital converter 40 for receiving a signal output from the unit converter 30 and converting the signal into a digital signal and outputting the digital signal;

It includes an address encoder (50) to receive the signal output from the analog-to-digital converter 40 to represent a value that the user can easily recognize.

The photoelectric converter 10 includes a photodetector CV11 that receives an optical signal transmitted from the first optical transmission apparatus 100, converts the optical signal into an electrical signal, and outputs the electrical signal, and is output from the photodetector CV11. And a first diode D12 that receives a signal and removes and outputs an unnecessary component.

The optical signal extracting unit 20 includes a first operation of receiving and amplifying a portion of a signal output from the photoelectric conversion unit 10 and transmitted to the second optical transmission device through an inverting input terminal and outputting the result as a voltage signal. And an amplifier OP21 and a first resistor R31 for feeding back the signal output from the first operational amplifier OP21 by a predetermined amount and outputting the signal to the inverting input terminal of the first operational amplifier OP21.

The unit converter 30 may include a second resistor R31 through which the signal output from the optical signal extractor 20 is input to one terminal, and a signal through the other terminal of the first resistor R31. The second operation amplifier (OP32) for receiving and amplifying and outputting the input, the input terminal of the second operation amplifier (OP32) is connected to the anode (anode) and the output terminal of the second operation amplifier (OP32) is a cathode (cathode) It comprises a second diode (D33) connected to.

The operation of the embodiment of the present invention made as described above is as follows.

In the optical transmission system, in order to measure the magnitude of the optical signal transmitted from the first optical transmission device 100 to the second optical transmission device 200, the photoelectric conversion unit 10 is a light transmitted from the first optical transmission device 100 It receives a signal and converts it into an electrical signal and outputs it.

That is, the photodetector CV11 of the photoelectric conversion unit 10 is a communication indium gallium arsenide (InGaAs) photodetector that is pigtailed with an optical transmission optical fiber, and is transmitted from the first optical transmission apparatus 100. It receives an optical signal from the line and converts it into an electrical signal, which is a voltage signal or a current signal, and outputs it.

That is, when the optical signal is converted into a current signal in the photoelectric conversion unit 10, the output terminal of the photodetector CV11 is expressed in ampere, which is a current unit. As the intensity of the optical signal decreases, the intensity of the current also decreases.

The first diode D12 receives the signal output from the photodetector CV11 and removes unnecessary components and outputs the unnecessary components to the optical signal extracting unit 20.

The optical signal extraction unit 20 receives an electric signal output from the photoelectric conversion unit 10, extracts a part of the signal, and amplifies the signal into a signal having a predetermined size.

The first operational amplifier OP21 of the optical signal extractor 20 receives and amplifies some of the signals output from the photoelectric converter 10 and transmitted to the second optical transmitter 200 through the inverting input terminal. Outputs a voltage signal, the current output from the photoelectric conversion unit 10 by being fed back to the input signal from the first operational amplifier OP21 through a first resistor (R22) by a predetermined amount and input again to the input Even if the signal is saturated, the change can be detected.

That is, when the intensity of the transmitted optical signal becomes larger than a certain range, the value of the current output from the photoelectric conversion unit 10 does not follow the range and becomes saturated, and if so, the change of the intensity of the optical signal is changed. The result is not accurately detected. By changing the first resistor R22 to feedback, the amount of change is controlled so that the current value does not become saturated.

The first operational amplifier OP21 amplifies the input current signal and converts the current signal into a voltage signal. The operation is expressed as in Equation 1 below.

Vi = IinR22

The unit converter 30 receives a signal output from the optical signal extractor 20 by using a second resistor R31 and measures the result by using a second operational amplifier OP32 and a second diode D33. Converted values are converted into decibel units, that is, log scale.

Preferred processing of the unit converter 30 is expressed by Equation 2 below.

_{Vo = -n · V T · LN} (ViIs · R)

Is and n are parameters of the second diode D33, V _T is a thermal voltage, and kT / q is about 25 milli volts.

At this time, the current flowing through the second diode is expressed by Equation 3 below, where Is is expressed as a constant at a given temperature.

i = Is (e ^{Vo / nVT} -1)

As shown above, the unit converter 30 converts an input signal into a log scale signal and outputs the converted signal, thereby expressing a unit of measurement of the intensity of the optical signal in units of power. As shown in

Power = 10log (P2 / P1)

Here, P2 is the target power and P1 is a reference power, wherein P1 is there is to have a fixed value of 10 ^-3, since it is one of the indicators indicating the 10 ^-3 mm.

The analog-to-digital converter 40 receives a signal output from the unit converter 30 and converts the signal into a digital signal that can be processed by a computer. The address encoder 50 converts the analog-to-digital converter 40. By receiving the signal output from the encoded by the user, it is expressed as a value that the user can easily recognize.

By connecting the signal output from the address encoder 50 to a computer, the user can easily monitor.

By configuring the device as described above, the intensity of the optical signal transmitted from the first transmission device 100 to the second transmission device 200 can be measured without interruption of service. Should be matched to the second optical transmission device 200.

Since the intensity of the optical signal must be measured during the optical transmission service, when the impedance of the optical signal intensity measuring apparatus is set to 99 times that of the second optical transmission apparatus in order to extract only a portion of the optical signal so that the quality of the transmission signal is not degraded, the photoelectric conversion 99% of the current signal output from the unit 10 is transmitted to the second optical transmission device 200, and only the remaining 1% is introduced into the optical signal intensity measuring device.

That is, since 99% of all transmission signals are transmitted to the destination, accurate measurement can be performed without degrading the reliability of the transmission service.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, conversions, and modifications are possible within the scope without departing from the technical spirit of the present invention. It will be apparent to those who have knowledge.

Therefore, the present invention operating as described above, in measuring the magnitude of the optical signal transmitted between the optical transmission device of the optical transmission system, without interrupting the optical transmission service, the user can easily and accurately measure the optical signal strength automatically It's easy to understand.

In addition, since it is not necessary to provide an expensive optical power measuring device separately, the above-described method can reduce the cost of checking the transmission state of the optical transmission system and at the same time, make an accurate inspection.

Claims (4)

An apparatus for measuring the magnitude of an optical signal transmitted from a first optical transmission device to a second optical transmission device, Photoelectric conversion means for receiving an optical signal transmitted from the first optical transmission device and converting the optical signal into an electrical signal; Amplifying means for receiving an electric signal output from the photoelectric conversion means, extracting a part of the amplified signal and outputting the amplified signal to a predetermined size; Unit conversion means for receiving a signal output from the amplifying means and converting the measured value into decibel units and outputting the measured signal; An analog-digital converting means for receiving a signal output from the unit converting means and converting the signal into a digital signal; And an encoding means for receiving a signal output from the analog-digital converting means and expressing the signal as a value easily understood by the user. The method of claim 1, wherein the photoelectric conversion means, A photodetector that receives an optical signal transmitted from the first optical transmission device and converts the optical signal into an electrical signal; And a first diode which receives the signal output from the photodetector and removes and outputs unnecessary components. The method of claim 1, wherein the optical signal extraction means, A first operational amplifier configured to receive and amplify a portion of a signal output from the photoelectric conversion means and transmitted to a second optical transmission device through an inverting input terminal and output a voltage signal; And a first resistor for feedbacking the signal output from the first operational amplifier to a predetermined level and outputting the signal to the inverting input terminal of the first operational amplifier. The method of claim 1, wherein the unit conversion means, A second resistor in which a signal output from the optical signal extracting means is input to one terminal; A second operational amplifier for receiving and amplifying and outputting a signal through the other terminal of the first resistor; And an input terminal of the second operational amplifier connected to the anode and a second diode (D33) connected to the output terminal of the second operational amplifier (OP32) as a cathode.