RU222407U1 - DEVICE FOR FORMING AND MONITORING GROUP DWDM SIGNAL - Google Patents

Abstract

The utility model relates to communication technology, namely to DWDM (Dense Wavelength-Division Multiplexing) technology. The technical result is to ensure control and regulation of the power level of each component DWDM signal without interruption of communication. This result is achieved through the introduction of measuring and signal-correcting means, namely through the introduction of optical splitters into the transmitting and receiving parts of the device, a selective power meter, as well as a control circuit that controls the attenuators of the device, allowing you to change the power level in each channel. 1 ill.

Description

The proposed utility model relates to communication technology, namely to the technology of dense spectral multiplexing DWDM (Dense Wavelength-Division Multiplexing) and can operate in equipment intended for use on a public communication network with access to integrated communication networks.

Known RF patent for invention No. 2537794, IPC H04J 14/00, publ. 01/10/2015 “Optical multiplexer-demultiplexer with separation of propagation directions”, which contains a wave multiplexing and separation unit, a device for separating the directions of propagation of the light flux, as well as a group of external connectors.

The disadvantage of this technical solution is that the device does not contain built-in measuring and signal-correcting means that will eliminate the interaction of wavelengths with each other and thereby improve the quality of the transmitted signal.

The closest to the claimed technical solution is patent for invention No. 2361365, IPC N04B 10/00, publ. 07/10/2009 “Device for centralized monitoring of wavelengths in a DWDM system and a method for its implementation,” which includes many optical emitters with different wavelengths, a multiplexer, a sampler, a tunable bandpass filter, a broadband wavelength synchronization device, a processing processor signals and controller.

The disadvantage of this technical solution is that only the shift of the central wavelength is corrected without adjusting the signal power level. In practice, the transceiver module itself is responsible for the frequency offset, which already has all the necessary means for monitoring the frequency offset.

The task to be solved by the claimed utility model is the implementation of a device for generating a group DWDM signal, which can include up to 80 component DWDM signals, with continuous monitoring and correction of each of them without interruption of communication.

This problem is solved due to the fact that the claimed device for generating and monitoring a group DWDM signal consists of an optical multiplexer, which is a thin-film filter with a waveguide grating with a periodic structure, a tunable bandpass filter, a wavelength synchronization device, a signal processor, an optical demultiplexer, and two interleavers , four optical splitters and a control circuit. A tunable bandpass filter, a wavelength synchronization device, and a signal processing processor are combined into a selective power meter unit. The device is conventionally divided into transmitting and receiving parts. In the transmitting part, N input odd component DWDM signals are supplied to the inputs of the multiplexer, the output of the multiplexer is connected to the first input of the first interleader, the second input of which receives a group signal formed from M even component DWDM signals. In this case, the output of the first interleaver is connected to the input of the first optical splitter, the first output of which is connected to the communication line, the second output of which is connected to the input of the second optical splitter. The first output of the second optical splitter is connected to a connector for connecting optical signal monitoring devices in the transmitting part, and the second output is connected to a selective power meter. At the same time, in the receiving part, the communication line is connected to the first input of the third optical splitter, the first output of which is connected to the input of the fourth optical splitter. The first output of the fourth optical splitter is connected to a connector for connecting devices for monitoring optical signals of the receiving part, the second output is connected to a selective power meter. The second output of the third optical splitter is connected to the input of the second interleaver. The first output of the second interleaver is connected to an optical demultiplexer, and from the second output there is a group signal consisting of M even component DWDM signals, in addition, N output odd component signals are generated at the output of the optical demultiplexer. The selective power meter is connected to a control circuit, which in turn is connected to a multiplexer, the multiplexer including attenuators for each wavelength. From the first output of the first optical splitter, 95% of the group optical signal goes into the communication line, and the remaining 5% goes to the input of the second optical splitter. At the output of the second optical splitter, 50% of the input signal goes to the connector for connecting optical signal monitoring devices, and 50% to the selective power meter. At the output of the third optical splitter, 95% of the optical signal coming from the communication line goes to the second interleader, and 5% goes to the input of the fourth optical splitter, while at the output of the fourth optical splitter, 50% goes to the selective power meter, and 50% goes to the connector for connecting optical signal monitoring devices. The number of input/output odd DWDM component signals is N, where N can be from 1 to 40. The number of input/output even DWDM component signals is M, where M can be from 1 to 40.

The technical result provided by the above set of features is to ensure control and regulation of the power level of each component DWDM signal without interruption of communication.

The essence of the utility model is illustrated by a drawing that shows a block diagram of the device.

The device for forming and monitoring a group DWDM signal consists of an optical multiplexer 1, which is a thin-film filter with a waveguide grating with a periodic structure, a demultiplexer 2, a selective power meter 3, an output interleaver 4, an input interleaver 5, two optical splitters 5/95 6, two optical splitters 50/50 7, control circuits 8.

In the transmitting part, N input odd component DWDM signals are supplied to the inputs of the multiplexer 1, the output of the multiplexer 1 is connected to the first input of the first interleaver 4, the output of the interleaver 4 is connected to the input of the first optical splitter 6, the first output of which is connected to the communication line, the second output of which is connected to the input of the second optical splitter 7, the first output of which is connected to a connector for connecting devices for monitoring optical signals of the transmitting part, and the second output is connected to a selective power meter 3. The second input of the first interleaver 4 receives a group signal formed from M even component DWDM signals.

At the same time, in the receiving part, the communication line is connected to the first input of the third optical splitter 6, the first output of which is connected to the input of the fourth optical splitter 7, the first output of which is connected to the connector for connecting optical signal monitoring devices of the receiving part, the second output is connected to the selective power meter 3, the second output of the third optical splitter 6 is connected to the input of the second interleaver 5. The first output of the second interleaver 5 is connected to the optical demultiplexer 2, and a group signal consisting of M even component DWDM signals comes out from the second output. At the output of the optical demultiplexer 2, N output odd component DWDM signals are generated.

Selective power meter 3 is connected to control circuit 8, which in turn is connected to multiplexer 1, and multiplexer 1 includes attenuators for each wavelength.

In addition, optical splitters 6 are designed to split the signal coming to them at the input in a ratio of 95% to 5%, and optical splitters 7 are designed to split the signal coming to them at the input in a ratio of 50% to 50%.

The number of input/output odd DWDM component signals is N, where N can be from 1 to 40. The number of input/output even DWDM component signals is M, where M can be from 1 to 40.

This utility model is illustrated by a specific example of execution and demonstrates the possibility of achieving a technical result.

We will demonstrate the operation of the claimed utility model using a specific example of the operation of a device as part of optical transport and packet switching equipment.

The number of input odd component DWDM signals and even component DWDM signals does not affect the performance of the device. Let's consider an example of device operation in which odd component DWDM signals N is equal to 40 and even component DWDM signals M is equal to 40. The wavelength of each input component DWDM signal is determined by the requirement for the application characteristics of dense wavelength division multiplexing technology DWDM is determined by the recommendation of the ITU-T standard G.694.1(MC3-T G.694.1).

The table shows the wavelength distribution of even component DWDM signals and odd component DWDM signals.

When the power is turned on, the device is checked by control circuit 8 for operability

The odd-numbered DWDM component signals are supplied to the input of multiplexer 1. In the multiplexer, each signal is fed to its own attenuator (not shown in the figure). All attenuators are controlled by control circuit 8 and allow you to change the power level in each channel.

The formed group channel from odd DWDM signals is supplied to the first input of interleaver 4.

The second input of interleaver 4 receives an already generated group signal from even component DWDM signals. At the output of interleaver 4 we obtain a formed group channel with a maximum number of component DWDM signals - 80, which go to the input of the first optical splitter 6. Optical splitter 6 divides the input signal in a ratio of 95% to 5%, where 95% is supplied to the communication line, and 5 % is supplied to the input of the second optical splitter 7, in which the input signal is divided in a ratio of 50% to 50%. From the first output of the second optical splitter 7, the selected 50% of the signal is supplied to the connector for connecting optical signal monitoring devices of the transmitting part, and the remaining 50% from the second output of the second optical splitter 7 is supplied to the selective power meter 3.

The selective power meter 3 receives the entire spectrum of the group signal. Selective Power Meter 3 analyzes and measures the power in each channel. The measurement results are fed to control circuit 8. If the power level in one of the channels has changed relative to other channels, the control circuit sends a signal to the attenuator of this channel to multiplexer 1, where the attenuator corrects the signal.

The connector for connecting optical signal monitoring devices is designed to connect, for example, a spectrum analyzer, which allows you to additionally analyze the group signal without interrupting communication.

In the receiving part, a linear optical signal comes from the communication line to the input of the third optical splitter 6, which is divided in a ratio of 95% to 5%, then 5% of the selected signal goes to the input of the fourth optical splitter 7, in which it is divided 50% to 50%. From the first output of the fourth optical splitter 7, 50% of the signal goes to the connector for connecting devices for monitoring optical signals of the receiving part, the remaining 50% of the input signal from the second output of the fourth optical splitter 7 goes to the selective power meter 3. In the selective power meter 3, all component signals are analyzed group signal and a notification is generated about an accident or change in the power level of incoming component signals. Notifications are received by control circuit 8, which sends these notifications to a computer (not shown in the figure) with a special program for monitoring the operation of all optical transport and packet switching equipment.

From the second output of the third optical splitter 6, 95% of the signal is supplied to the input of the second interleaver 5. At the first output of the second interleaver 5, connected to the optical demultiplexer 2, we obtain a group signal consisting of 40 odd component DWDM signals, and from the second output of the second interleaver 5 we obtain a group signal consisting of 40 even-numbered DWDM component signals. Optical demultiplexer 2 divides the baseband signal into 40 component odd DWDM signals. Allocating only 5% of the power from the group signal to study component signals allows you to form a balance where, at the same time, without distorting the group signal, there is enough power to study component signals. A further division of the allocated power in the ratio of 50% to 50% is sufficient for the operation of the selective power meter 3 and for additional measuring instruments that can be connected to the connector for connecting optical signal monitoring devices. The operation of the proposed utility model was examined using a specific example of execution and with specific optical splitters. This does not deny the possibility of the proposed solution working with optical splitters with other percentages.

Thus, the device allows simultaneous transmission and reception of up to 80 optical signals with control of the power of each optical component signal and regulation of the power level of each optical component signal during transmission without interruption of communication.

Claims (7)

1. A device for generating and monitoring a group DWDM signal, consisting of: an optical multiplexer, which is a thin-film filter with a waveguide grating with a periodic structure, a tunable bandpass filter, a wavelength synchronization device, a signal processor, characterized in that an optical demultiplexer is additionally introduced, two interleavers, four optical splitters, a control circuit, with a tunable bandpass filter, a wavelength synchronization device, a signal processing processor combined into a selective power meter block, in the transmitting part N input odd component DWDM signals are supplied to the multiplexer inputs, the multiplexer output is connected to the first input the first interleaver, the output of the interleaver is connected to the input of the first optical splitter, the first output of which is connected to the communication line, the second output of which is connected to the input of the second optical splitter, the first output of which is connected to the connector for connecting optical signal monitoring devices, and the second output is connected to selective power meter, in addition, a group signal formed from M even component DWDM signals is received at the second input of the first interleaver, while in the receiving part the communication line is connected to the first input of the third optical splitter, the first output of which is connected to the input of the fourth optical splitter, the first the output of which is connected to the connector for connecting devices for monitoring optical signals of the receiving part, the second output is connected to a selective power meter, and the second output of the third optical splitter is connected to the input of the second interleaver, while the first output of the second interleaver is connected to an optical demultiplexer, and from the second output M even component DWDM signals, in addition, at the output of the optical demultiplexer, N output odd component DWDM signals are generated, in addition, a selective power meter is connected to a control circuit, which in turn is connected to a multiplexer, and the multiplexer includes attenuators for each wavelength . 2. The device for generating and monitoring a group DWDM signal according to claim 1, characterized in that 95% of the group optical signal from the first output of the first optical splitter goes to the communication line, and the remaining 5% goes to the input of the second optical splitter. 3. The device for generating and monitoring a group DWDM signal according to claim 1, characterized in that at the output of the second optical splitter, 50% of the input signal goes to the connector for connecting optical signal monitoring devices, and 50% to a selective power meter. 4. The device for generating and monitoring a group DWDM signal according to claim 1, characterized in that at the output of the third optical splitter, 95% of the optical signal coming from the communication line goes to the second interleader, and 5% goes to the input of the fourth optical splitter. 5. The device for generating and monitoring a group DWDM signal according to claim 1, characterized in that at the output of the fourth optical splitter, 50% goes to the selective power meter, and 50% goes to the connector for connecting optical signal monitoring devices. 6. A device for generating and monitoring a group DWDM signal according to claim 1, characterized in that N can be from 1 to 40. 7. A device for generating and monitoring a group DWDM signal according to claim 1, characterized in that M can be from 1 to 40.

Images