KR20010097980A - Constant output channel power gain flattened optical amplifier - Google Patents

Abstract

A gain equalization optical amplifier is disclosed in which a channel output is fixed to equalize the gain so as to maintain a constant output optical signal. The gain equalization optical amplifier having a fixed channel output according to the present invention branches a control optical signal which is a control signal among the input optical signals, converts the control optical signal into an electrical signal, and outputs a control electrical signal, and branches a part of the optical signal which is a communication signal. A first amplifying unit converting the electrical signal into an electrical signal to generate an input electrical signal, and firstly amplifying the remaining optical signals other than the partially branched optical signals with a constant gain; An optical loss information extracting unit detecting optical loss information according to the control electrical signal of the first amplifying unit; A controller which attenuates the intensity of the optical signal output from the first amplifier according to the optical loss information of the optical loss information extracting unit; A second amplifying unit equalizing a gain constantly according to the optical loss information and secondly amplifying the optical signal of the controller with the equalized gain to maintain a second amplified optical signal constantly; And an output unit for generating a control optical signal and multiplexing the generated control optical signal and the optical signal of the second amplifying unit, and outputting a control optical signal to uniformly control the intensity of the optical signal output from the optical amplifier per channel using the control optical signal. Can be printed.

Description

Gain equalized optical amplifier with fixed channel output {CONSTANT OUTPUT CHANNEL POWER GAIN FLATTENED OPTICAL AMPLIFIER}

The present invention relates to an optical amplifier of a wavelength division optical transmission system, and more particularly, by adjusting a variable attenuator using optical loss information extracted from a control optical signal, thereby maintaining a constant optical signal per channel and increasing the intensity of the excitation light. It relates to a device that can be adjusted to equalize the gain.

Optical amplifiers for compensating for optical losses generated in optical fibers between nodes of a conventional wavelength division optical transmission system consist of an amplifier with a fixed gain and an optical amplifier with a fixed output intensity.

As shown in FIG. 1, the optical amplifier having the fixed gain includes an input optical signal branching unit 11, an optical amplifier 12, an output optical signal branching unit 13, an input monitor unit 14, and an output monitor. The unit 15 includes a gain comparison unit 16, a gain control unit 17, and an excitation light generation unit 18.

The optical amplifier 12 receiving the optical signal of the input optical signal branching part 11 which splits a part of the input optical signal amplifies the optical signal according to a predetermined gain, and outputs the optical signal receiving the amplified optical signal. The signal branching section 13 branches this amplified optical signal.

In addition, the input monitor 14 and the output monitor 15 which have received the optical signals of the input optical signal branching section 11 and the output optical signal branching section 14 convert the optical signal into an electrical signal to generate electricity. Each signal is outputted, and the gain comparator 16 receiving the input electric signal and the output electric signal calculates a gain.

The gain control unit 17 receiving the calculated gain difference generates a control signal such that the calculated gain value becomes constant, and the excitation light generation unit 18 receiving the control signal adjusts the intensity of the excitation light according to the control signal. The excitation light with this intensity adjusted is supplied to the optical amplifier 13. The optical amplifier 13 amplifies the optical signal of the input optical signal branch 11 according to the excitation light whose intensity is adjusted.

Such an optical amplifier is always amplified with a constant gain regardless of the magnitude of the input optical signal.

However, the optical amplifier having a fixed gain as described above, when the intensity of the optical signal changes in the optical transmission path or when the intensity of the optical signal changes more than the other, the intensity of the optical signal of the optical amplifier is also changed, so that the optical signal of the output optical signal branch The size of will change.

Recently, in order to prevent the magnitude of the optical signal from changing due to the change in the intensity of the optical signal, an optical amplifier having a fixed intensity of the output optical signal has been proposed. As shown in 2.

That is, in general, an optical amplifier having a fixed output intensity includes an input optical signal branching unit 21, an optical amplifier 22, an output optical signal branching unit 23, an output monitor unit 24, and an output control unit 25. And an excitation light generator 26.

The optical amplifier 22 which receives the optical signal of the input optical signal branch 21 which splits a part of the input optical signal amplifies the optical signal according to a predetermined gain, and outputs the received optical signal by receiving the amplified optical signal. The signal branching section 23 branches the amplified optical signal.

Then, the output signal monitor 23 receiving the optical signal partially branched by the output optical signal branching section 23 converts the branched optical signal into an electrical signal, and outputs the received output electrical signal. It is supplied to the control unit 24.

The output control unit 24 generates a control signal for keeping the intensity of the partially branched optical signal constant, and the excitation light generator 26 receiving the control signal sets the intensity of the optical signal according to the control signal. To generate an excitation light for maintaining the Therefore, the intensity of the optical signal output from the optical amplifier 22 receiving this excitation light is kept constant.

However, when the change in the magnitude of the optical signal input to the input optical signal branch 11 is minute, the magnitude of the optical signal per channel is constant while maintaining gain equalization, but when the magnitude of the optical signal is large or the number of channels is large. If changed, gain equalization between channels does not occur. In addition, when the number of channels changes, there is a problem that the size of the optical signal per channel is variable.

Accordingly, an object of the present invention is to provide an optical amplifier in which the gain per channel is equalized and the intensity of the optical signal per channel is constant.

A gain equalization optical amplifier having a fixed channel output according to the present invention for achieving the above object is, after branching the control optical signal of the input optical signal to convert it into an electrical signal to output a control electrical signal, which is a communication signal A first amplifying unit for branching a part of the optical signal and converting the electric signal into an electrical signal to generate an input electric signal, and first amplifying the remaining optical signals other than the partially branched signal with a constant gain;

An optical loss information extracting unit detecting optical loss information according to the control electrical signal of the first amplifying unit;

A controller which attenuates the intensity of the optical signal output from the first amplifier according to the optical loss information of the optical loss information extracting unit;

A second amplifier which equalizes a gain constantly according to the optical loss information, and secondly amplifies the optical signal of the controller with the equalized gain to maintain a second amplified optical signal constantly; And

And an output unit for generating a control optical signal and multiplexing and outputting the generated control optical signal and the optical signal of the second amplifying unit.

According to the present invention, when the loss of the optical fiber increases, the size of the optical loss information of the optical loss information extractor decreases, and the intensity of the optical signal output from the first amplification unit decreases according to the reduced amount of optical loss information. By reducing the loss of the optical fiber and amplifying the attenuated optical signal according to a fixed gain, a constant optical signal is output regardless of the intensity of the optical signal input for each optical communication node, even if the number of channels of the input optical signal changes. Output a fixed optical signal.

1 is a block diagram showing a configuration of an optical amplifier having a fixed general gain.

2 is a block diagram showing the configuration of a gain equalizing optical amplifier having a fixed channel output.

3 is a block diagram illustrating a configuration of a gain equalization optical amplifier having a fixed channel output according to the present invention.

4 is a diagram illustrating in detail the configuration of the gain equalizing optical amplifier of FIG. 3.

<Explanation of symbols for main parts of drawing>

110: first amplifier 111 111 control optical signal branch

112: control optical signal monitor 113: input signal branch

114: input monitor 115: first amplifier

116: first control signal generator 117: first excitation light generator

210: light loss information extraction unit 310: control unit

311 gain control unit 312 variable attenuator

313: gain equalizing optical filter 410: second amplifier

411: second amplifier 412: output signal branch

413: output monitor 414: multiplication unit

415: gain comparison unit 416: second control signal generator

417: second excitation light generator 510: output unit

511: control optical signal generator 512: control optical signal multiplexer

Hereinafter, the present invention will be described in more detail with reference to the following examples.

3 is a block diagram illustrating a gain equalization optical amplifier having a fixed channel output according to the present invention, wherein the first amplifier 110, the optical loss information extractor 210, the controller 310, and the second amplifier 410 are shown. And an output unit 510.

The first amplifier 110 is as shown in FIG. That is, the control signal output from the control optical signal branch 111 is electrically connected to the first output side of the control optical signal branch 111 that classifies the communication signal and the control signal using a conventional wavelength division optical multiplexing device. The control optical signal monitor 112 which outputs the control electric signal which converts into a signal is connected. Here, the control optical signal monitor 112 is made of a conventional photoelectric conversion element, the control electrical signal is inversely proportional to the loss of the optical fiber.

Then, the first branch of the input signal branch 112 for splitting a part of the optical signal of the communication signal by a constant ratio using a directional optical branch coupling element, the light branched at a predetermined ratio by the input signal branch 112 An input monitor 114 for converting a signal into an electrical signal and outputting an input electrical signal is connected.

A first amplifier 115 for first amplifying the optical signal output from the input signal branch 112 is connected to the second output side of the input signal branch 112.

Meanwhile, a first excitation light is generated at an output side of the first control signal generator 116 that generates a control signal having a predetermined value according to the first control signal of the first control signal generator 116, and the first The first excitation light generator 117 for supplying the excitation light to the first amplifier 115 is connected.

Here, the first amplifier 115 is provided to use the erbium-added optical fiber as a gain medium, and includes an optical isolator for blocking the light traveling in the reverse direction and a wavelength division optical multiplexer for coupling the signal light and the excitation light. do. In addition, the first control signal generator 116 generates a control signal for generating the first excitation light at a constant intensity.

The optical loss information extraction unit 210 is connected to an output side of the control optical signal monitor 112 for generating optical loss information, which is a loss value on an optical fiber, from the control electrical signal. To the first output side of the unit 210, a gain control unit 311 of the control unit 310 for generating a gain for compensating for this optical loss is connected.

A variable attenuator 312 for attenuating the intensity of the optical signal of the first amplifier 115 according to the gain of the gain controller 311 is connected to the output side of the gain controller 311. The variable attenuator 312 is provided to adjust the amount of attenuation applied to the optical signal according to the gain signal of the gain control unit 311. The gain signal may be a DC voltage magnitude, a pulse width, an amount of current, and an AC voltage (or current) magnitude.

A gain equalization optical filter 313 is connected to an output side of the variable attenuator 312 to remove an optical signal other than a predetermined band among the optical signals of the variable attenuator 312. Here, the gain equalizing optical filter 313 is made of a conventional optical fiber grating element or an optical filter.

Further, a second amplifier 411 of the second amplifier 410 for second amplifying the optical signal of the gain equalizing optical filter 313 is connected to the output side of the gain equalizing optical filter 313. An output signal branch section 412 for branching the amplified optical signal is connected to the output side of the two amplifier 411.

The output signal branching section 412 is connected to an output monitor section 413 which converts a partly branched optical signal of the amplified optical signal into an electrical signal to generate an output electrical signal. A multiplier 414 is connected to the output side of the output electrical signal and a multiplier 414 that calculates the output electrical signal by calculating the optical loss information of the optical loss information extraction unit 210.

The output side of the multiplier 414 generates a second gain for calculating the input electrical signal and the arithmetic electrical signal of the multiplier 414 to maintain a constant intensity of the optical signal of the second amplifier 411. The comparator 415 is connected.

On the output side of the gain comparator 415, a second control signal generator for generating a control signal for generating excitation light for keeping the intensity of the optical signal of the second amplifier 411 constant according to the second gain. 416 is connected, and on the output side of the second control signal generator 416, a second excitation light generator 417 for generating excitation light according to the control signal and supplying it to the second amplifier 411 is provided. Connected.

Herein, the second amplifier 411 adjusts the excitation light intensity according to the second control signal of the second control signal generator 416, and converts the energy of the adjusted second excitation light into the optical fiber to which the erbium is added. It is provided so that the energy of the optical signal is amplified. The second excitation light generator 417 may include one or more excitation light sources.

On the other hand, on the output side of the control optical signal generator 511 for generating control light and the output side of the output signal branching unit 412, a control optical signal multiplexing unit for coupling the control light and the optical signal of the output signal branching unit 412 ( 512 is connected.

In the gain equalization optical amplifier having a fixed channel output according to the present invention, the optical signal mixed with the communication signal and the control signal is supplied to the control optical signal branch 111 and branched, and this branched control optical signal is provided. Is supplied to the control optical signal monitor 112, and the control optical signal monitor 112 converts the control optical signal into an electrical signal and outputs the control electrical signal.

The light loss information extracting unit 210 receiving the control electric signal calculates an amount of light loss from the control electric signal. First, when the loss of optical fiber increases, the size of this optical loss information becomes small.

In addition, the input signal branching unit 113 that receives an optical signal, which is a communication signal other than the control optical signal branched from the control optical signal branching unit 111, branches the portion of the optical signal at a predetermined ratio to input the monitor unit 114. The input monitor unit 114, which receives the partially branched optical signal, converts the optical signal into an electrical signal and outputs the input electrical signal.

The optical signal output from the input signal branch 113 is supplied to the first amplifier 115, and the first amplifier 115 is generated according to the control signal of the first control signal generator 116, which is a fixed value. According to the first excitation light of the first excitation light generator 117, the intensity of the optical signal output from the input signal branch 113 is constantly amplified.

Meanwhile, the second control unit 311 receiving the optical loss information supplied from the optical loss information extracting unit 210 adjusts a first gain according to the optical loss information, and the variable attenuator 312 receives the adjusted first gain. The size of the first amplified optical signal is adjusted. That is, the control unit 311 reduces the amount of attenuation applied to the first amplified optical signal by controlling the variable attenuator 312 to be inversely proportional to the light loss information reduced due to the increased optical fiber loss.

The optical signal output from the variable attenuator 312 is supplied to a gain equalizing optical filter 313, and the gain equalizing optical filter 313 is equal to or greater than or equal to a predetermined band in order to remove an unbalance of gain of the optical signal. Eliminate the optical signal.

The optical signal of the gain equalizing optical filter 313 is supplied to the second amplifier 411 for second amplification, and the second amplified optical signal is supplied to the output signal branch 412, and this output signal branch ( 412 divides a part of the second amplified optical signal and supplies it to the output monitor 413.

In addition, the output monitor 413 converts the partially branched optical signal into an electrical signal and outputs an output electrical signal. The multiplier 414 receiving the output electrical signal outputs the optical loss information and the output electrical signal. Multiply by

The gain comparator 415, which receives the computational electrical signal multiplied through the computation process and the input electrical signal of the input monitor 114, divides the input electrical signal into the computational electrical signal, and the calculated result is constant. Generate a second gain to maintain. The second gain of the gain comparison unit 415 is supplied to the second control signal generator 416, and the second control signal generator 416 that has received the second gain of the gain comparison unit 415 The second control signal is generated in accordance with the second gain, and the second excitation light generator 417 receiving the second control signal generates the second excitation light in accordance with the second control signal.

The second excitation light is supplied to the second amplifier 411, and the second amplifier 411 receiving the second excitation light amplifies the optical signal input according to the second excitation light. Since the second gain is equalized, the intensity of the optical signal output from the second amplifier 411 is increased at a constant rate.

On the other hand, the remaining part of the branched optical signal of the output signal branching unit 412 is supplied to the control signal multiplexer 512, the control signal multiplexer 512 is the control light generated from the control optical signal generator 511 The optical signal supplied from the signal and the output signal branching unit 412 is multiplexed and output.

That is, when the loss of the optical fiber increases, the magnitude of the input electrical signal and the magnitude of the optical loss information signal, which is an output signal of the optical loss information extracting unit 210, are inversely proportional to the increased optical fiber loss, and at the same time The magnitude of the computational electrical signal, which is the output signal of 414, becomes small in proportion to this optical loss information.

In addition, the gain controller 311 receiving the reduced optical loss information controls the variable attenuator 312 to operate in inverse proportion to reduce the amount of attenuation applied to the optical signal.

The gain comparison unit 415 receiving the arithmetic electrical signal and the input electrical signal of the multiplier 414 divides the input electrical signal by the arithmetic electrical signal, and the second control signal generator 416 receiving this output value outputs the output electrical signal. A second control signal is generated to keep the value constant.

Since the arithmetic electrical signal of the multiplier 414 decreases in inverse proportion to the increase in the loss of the optical fiber, the output value supplied to the second control signal generator 416 is kept constant, thereby the second amplifier 411. The intensity of the optical signal, which is the output signal of, is constant even when the loss of the optical fiber increases.

On the other hand, the loss of the optical fiber decreases, and inversely proportional to the reduced loss of the optical fiber, the optical loss information and the computational electrical signal of the multiplier 414 become large, and under the control of the gain control section 311, the variable attenuator 312 is reduced. The amount of attenuation is increased. In addition, the gain comparison unit 415 receiving the operation electrical signal and the input electrical signal of the multiplier 414 divides the operation electrical signal into an input electrical signal, and the second control signal generator 416 receiving the output value A second control signal is generated to keep this output value constant.

In addition, since the arithmetic electrical signal of the multiplier 414 increases in inverse proportion to the net loss of the optical fiber, and the output value output from the gain comparator 415 is constant, the optical signal output from the second amplifier 411. The intensity of is kept constant.

That is, the intensity of the optical signal output per channel is kept constant, and at the same time, the gain equalization can be maintained by linear control, and the intensity of the input and output optical signals is changed at the same rate even if the number of channels of the input optical signal is changed. Therefore, the gain is equalized regardless of the number of channels so that the intensity of the optical signal output per channel is kept constant.

As described above, according to the present invention, since the gain is equalized and the intensity of the optical signal output per channel is constant, the optical transmission system is absorbed by absorbing the loss of optical fiber generated when abnormal operation of the optical transmission system or abnormality occurs in the optical line. It operates stably, and it is easy to install and operate the optical transmission system because the intensity of the optical signal is constantly output regardless of the intensity of the optical signal input for each communication node, and even if the number of channels of the input optical signal is variable, The effect is to output a constant intensity.

In addition, although the present invention has been described in detail with reference to the embodiments described above, the present invention is not limited thereto, and modifications and improvements are possible within the scope of ordinary knowledge of those skilled in the art.

Claims (9)

Branching the control optical signal of the input optical signal and converting it into an electrical signal to output a control electrical signal, branching a part of the optical signal as a communication signal and converting into an electrical signal to generate an input electrical signal, the part A first amplifier which first amplifies the remaining optical signals other than the branched signal with a constant gain; An optical loss information extracting unit detecting optical loss information according to the control electrical signal of the first amplifying unit; A controller which attenuates the intensity of the optical signal output from the first amplifier according to the optical loss information of the optical loss information extracting unit; A second amplifying unit equalizing a gain consistently with the optical loss information and secondly amplifying the optical signal of the controller with the equalized gain to maintain a second amplified optical signal constantly; And And an output unit for generating a control optical signal and multiplexing and outputting the generated control optical signal and the optical signal of the second amplifying unit. The method of claim 1, wherein the first amplification unit A control optical signal branching unit for classifying a communication signal and a control signal using a conventional wavelength division optical multiplexing device; A control optical signal monitor connected to an output side of the control optical signal branch and outputting a control electrical signal for converting the control signal output from the control optical signal branch to an electrical signal; An input signal branching unit connected to an output side of the control optical signal branching unit and branching a part of the optical signal of the communication signal except for the branched control signal among the optical signals at a predetermined ratio; An input monitor (114) connected to an output side of the input signal branch part and converting an optical signal branched at a predetermined ratio from the input signal branch part into an electrical signal to output an input electric signal; A first amplifier (115) connected to an output side of the input signal branch section, for first amplifying the optical signal output from the input signal branch section; A first control signal generator for generating a first control signal having a predetermined value; And A first excitation light generation connected between the first control signal generator and the first amplifier, for generating a first excitation light according to the first control signal, and for supplying the first excitation light to the first amplifier; A gain equalizing optical amplifier, characterized in that it comprises a section (117). The method of claim 2, wherein the control unit A gain control unit connected to an output side of the light loss information extracting unit and generating a gain for compensating light loss; A variable attenuator connected to the output side of the gain control unit for attenuating the optical signal of the first amplifier; And And a gain equalization optical filter connected to an output side of said variable attenuator and configured to remove a predetermined band or more of an optical signal of said variable attenuator. The method of claim 3, wherein the second amplification unit A second amplifier connected to an output side of said gain equalizing optical filter for second amplifying an optical signal of said gain equalizing optical filter; An output signal branch connected to an output side of the second amplifier and for branching a portion of the amplified optical signal; An output monitor connected to an output side of the output signal branching unit and converting a partly branched optical signal of the amplified optical signal into an electrical signal to generate an output electrical signal; A multiplier connected to an output side of the output monitor unit to calculate an output electrical signal and light loss information of the optical loss information extracting unit to output a computational electrical signal; A gain comparison unit connected to an output side of the multiplier to calculate the input electrical signal and the arithmetic electrical signal of the multiplier, and adjust a gain of the second amplifier so that the calculated result value is constant; A second control signal generator connected to an output side of the gain comparator and generating a control signal for generating excitation light such that the intensity of the optical signal of the second amplifier is kept constant according to the gain; And A gain equalization optical amplifier having a fixed output channel, the second excitation light generator being connected to an output side of the second control signal generator and configured to generate excitation light and supply it to a second amplifier according to the control signal; . The optical fiber according to claim 4, wherein the second amplifier adjusts the excitation light intensity according to the second control signal of the second control signal generator, and uses the erbium-doped optical fiber as the medium of the adjusted second excitation light. A gain equalization optical amplifier with a fixed output channel, characterized in that the energy of the optical signal is amplified. 5. The fixed gain equalization optical amplifier of claim 4, wherein the second excitation light generator comprises one or more excitation light sources. The method of claim 4, wherein The output unit A control optical signal generator for generating a control optical signal; And And a control optical signal multiplexing unit configured to multiplex and transmit the control light and the optical signal of the output signal branching unit on the output side of the control optical signal generating unit and the output side of the output signal branching unit. The method of claim 1, wherein the first amplification unit A control optical signal branching unit for classifying a communication signal and a control signal using a conventional wavelength division optical multiplexing device; A control optical signal monitor connected to an output side of the control optical signal branch and outputting a control electrical signal for converting the control signal output from the control optical signal branch to an electrical signal; A first amplifier connected to an output side of the input signal branch, and primarily amplifying the optical signal output from the input signal branch; A first control signal generator for generating a first control signal having a predetermined value; A first excitation light generation connected between the first control signal generator and the first amplifier, for generating a first excitation light according to the first control signal, and for supplying the first excitation light to the first amplifier; Part 117; An input signal branching unit connected to an output side of the control optical signal branching unit and branching a part of the optical signal of the communication signal except for the branched control signal among the optical signals at a predetermined ratio; And And an input monitor (114) connected to the output side of the input signal branching portion and converting an optical signal branched at a predetermined ratio from the input signal branching portion into an electrical signal to output an input electrical signal. Fixed gain equalization optical amplifier. 2. The channel output of claim 1, wherein a plurality of amplifiers for amplifying an optical signal except for a partially branched optical signal of the second amplified optical signal are connected in series to an output side of the second amplifying unit. Gain equalization optical amplifier.