KR20210006298A - Apparatus and method for setting optical transceiver wavelength - Google Patents

Abstract

The present invention relates to a method for setting an optical transceiver wavelength using an optical transceiver management device. The method includes: a first step of setting a wavelength-tunable subcarrier signal transmission unit output wavelength of the optical transceiver management device as a first wavelength; and a second step of transmitting wavelength information on the first wavelength to an optical transceiver. The first and second steps can be repeated by the number of wavelengths used in an optical communication network.

Description

TECHNICAL FIELD [Apparatus and method for setting optical transceiver wavelength]

The present invention relates to an apparatus and method for setting a wavelength of an optical transceiver using an optical branch coupler.

An optical transceiver is an essential component of an optical communication network. Specifically, an optical transceiver is a compound word of a transmitter meaning an optical transmitter and a receiver meaning a receiver. An electrical signal is converted into a light signal between an optical cable connecting the optical communication network and a transmission equipment responsible for data transmission. Plays the role of converting into electric signals and exchanges data.

The demand for these optical transceivers is exploding due to the development of communication technology and the rapid increase in data traffic.

Meanwhile, in the case of a WDM optical transmission network, AWG or TFF is used for wavelength multiplexing. In these multiplexing/demultiplexing devices, the light wavelength that can pass through each port is determined. Therefore, the optical transceiver connected to the multiplexing/demultiplexing device must output the appropriate optical wavelength for the corresponding port in order to communicate accurately.

On the other hand, optical transceivers include a fixed-wavelength optical transceiver and a tunable optical transceiver.

In the case of a fixed-wavelength optical transceiver, the wavelength should be set according to the wavelength multiplexing/demultiplexing port when the network is installed, and the wavelength tunable optical transceiver should be set according to the multiplexing/demultiplexing port after the network is installed.

Conventionally, there are various methods for setting the wavelength of the tunable optical transceiver.

The first method of the related art has a method of inputting information on a wavelength to be output to a nonvolatile memory of an optical transceiver. This first method requires a separate wavelength setting tool and takes a long time.

The conventional second method is a method of setting using a host device, and has an advantage of automatically setting a wavelength using communication with the host device, but it was not possible when the host device did not provide the corresponding function.

In the third conventional method, as shown in FIG. 1, there is a method of automatically setting the wavelength by finding the connected port information by using subcarrier communication between the COT optical transceiver and the RT optical transceiver, but this third method takes a long time and This was not possible without a connection between the optical transceiver and the RT transceiver.

That is, in the third conventional method, the wavelength could not be set unless the network was completely established.

Accordingly, in order to solve the problems of these conventional methods, the present invention proposes an apparatus and method for quickly and accurately setting the wavelength of an optical transceiver using an optical transceiver management device using an optical branch combiner even if a network is not completely established.

The present invention provides an apparatus and method for quickly and accurately setting a wavelength of an optical transceiver using an optical transceiver management device using an optical branch combiner, even if a network is not completely established.

A method of setting a wavelength of an optical transceiver using an optical transceiver management apparatus according to an embodiment of the present invention includes a first step of setting an output wavelength of a variable wavelength subcarrier signal transmission unit of the optical transceiver management apparatus as a first wavelength, the first And a second step of transmitting wavelength information of a wavelength to the optical transceiver, and the first and second steps may be repeatedly performed as many as the number of wavelengths of the optical communication network.

In addition, the present invention provides a method of setting the wavelength of an optical transceiver connected to an optical transmission line and performing carrier and subcarrier communication. The method includes a wavelength setting information transmission step of transmitting wavelength setting information of a first wavelength to an optical transceiver in an optical transceiver management device connected to an optical transmission line, and the wavelength of an optical signal to be generated by the optical transceiver receiving the wavelength setting information. And a wavelength setting step of setting a first wavelength contained in the wavelength setting information, and the transmitting of the wavelength setting information comprises: a first wavelength subcarrier generating the wavelength setting information of the first wavelength as a subcarrier having a first wavelength The generating step includes a wavelength setting information optical transceiver transmitting step of transmitting the generated first wavelength subcarrier to an optical branch combiner and an optical transceiver connected to a terminal of the MUX/DeMuX passing the first wavelength.

The present invention provides an optical transceiver management apparatus in order to achieve such a wavelength setting method. The optical transceiver management apparatus according to the present invention is connected to an optical transmission line through an optical branch combiner to transmit a subcarrier signal to an optical transceiver on the optical transmission line, and a control unit for generating wavelength setting information to be transmitted to the optical transceiver, the generated A subcarrier receiver configured to include a subcarrier transmitter configured to transmit the wavelength setting information to the subcarrier to an optical transceiver, and to receive a subcarrier received from the optical transmission line through an optical branch combiner; In addition, a DeMux or a wavelength variable optical filter having a predetermined pass wavelength for each terminal is connected to a front end of the subcarrier receiving unit, and may be configured to receive a subcarrier signal from a plurality of optical transceivers using different wavelengths. .

The present invention can set the wavelength of an optical transceiver even if the network is not completely established.

In addition, the present invention can quickly and accurately set the wavelength of the optical transceiver.

1 is a diagram showing a method of setting a wavelength of a conventional optical transceiver.
2 is a diagram showing the configuration of a communication network including an optical transceiver management apparatus using an optical branch combiner according to an embodiment of the present invention.
3 is a diagram showing in detail an optical transceiver management apparatus according to an embodiment of the present invention.
4 is a diagram showing in detail an optical transceiver management apparatus according to another embodiment of the present invention.
5 is a diagram showing in detail an optical transceiver management apparatus according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. However, the present invention may be implemented in various forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and similar reference numerals are attached to similar parts throughout the specification.

Terms including ordinal numbers, such as first and second, may be used to describe various elements, but the elements are not limited by the terms. These terms are used only for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element. The terms used in the present application are used only to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Throughout the specification, when a part is said to be “connected” to another part, this includes not only the case that it is “directly connected”, but also the case that it is “electrically connected” with another element in between. . In addition, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless specifically stated to the contrary. As used throughout the specification of the present application, the term "step (to)" or "step of" does not mean "step for".

The terms used in the present invention have been selected from general terms that are currently widely used while considering functions in the present invention, but this may vary depending on the intention or precedent of a technician working in the field, the emergence of new technologies, and the like. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning of the terms will be described in detail in the description of the corresponding invention. Therefore, the terms used in the present invention should be defined based on the meaning of the term and the overall contents of the present invention, not a simple name of the term.

2 is a diagram showing the configuration of a communication network including an optical transceiver management apparatus using an optical branch combiner according to an embodiment of the present invention.

3 is a diagram showing in detail an optical transceiver management apparatus according to an embodiment of the present invention.

Hereinafter, a method of setting a wavelength using an optical transceiver management apparatus and an optical transceiver management apparatus according to an embodiment of the present invention will be described with reference to FIGS. 2 and 3.

1. Optical communication network according to the present invention

A communication network including an optical transceiver management apparatus using an optical branch combiner according to an embodiment of the present invention includes a first optical transceiver, a first host, a second optical transceiver, a second host, a multiplexer/de-multiplxer (MUX/DeMUX), and an optical device. It may be configured to include a branch combiner and an optical transceiver management device. The first optical transceiver, the first host may be a COT (Central Office Terminal) side, the second optical transceiver, the second host may be a RT (Remote Terminal) side, MUX/DeMUX (multiplexer/de-multiplxer) N terminals And COT-side and RT-side optical transceivers (first and second optical transceivers) are connected to an optical transmission line, and optical transceivers connected to MUX/DeMUX (multiplexer/de-multiplxer) may be composed of N or less pairs. have.

1.1. Connection between optical transceiver and optical transmission line

In the optical communication network of the present invention, the first and second optical transceivers are each connected to a predetermined terminal of a MUX/DeMUX (multiplexer/demultiplxer) and connected to an optical transmission line, and N (N=1, 2, 3) to one MUX/DeMUX. , …, n) optical transceivers are connected, and the optical transmission line connects N optical transceiver pairs.

1 (a) is a diagram of the prior art, but the connection state of the optical transceiver, the mux/demux, and the optical transmission line is the same as in the present invention.

2 is a diagram showing a central office terminal (COT) side of a communication network of the present invention. On the right side of the diagram of the optical transceiver management apparatus, a remote treminal (RT) side MUX/DeMux, an optical transceiver, and a host may be connected to an optical transmission line (not shown).

1.2. MUX/DeMUX

The MUX/DeMux of the present invention is connected to an optical transceiver. Each input terminal Dn receives the output of the optical transmitter of the optical transceiver, and the terminal Un outputs the signal received from the optical transmission line to the optical receiver of the optical transceiver.

Each terminal Dn of MUX/DeMUX functions as a wavelength filter. That is, it is configured to pass only a predetermined predetermined wavelength.

COT side MUX/DeMUX and RT side MUX/DeMUX each have N MUX side input terminals (N × 1) and operate as MUX/DeMUX, and MUX side input terminal has N or less first and second optical transceivers. Connected. In the drawing, when referring to the COT side, terminal Dn denotes a downstream terminal and Un denotes an upstream terminal.

1.3. Optical transceiver

Meanwhile, the first and second optical transceivers may be the same optical transceiver. Specifically, each of the first and second optical transceivers may include a host interface, a CPU (TRx) subcarrier transmitting unit, a subcarrier receiving unit, a wavelength adjusting unit, an optical transmitter, an optical receiver, and an amplifying unit.

The optical transceiver of the present invention can receive a wavelength control signal (set wavelength information) through a subcarrier receiver, and accordingly, the wavelength control unit adjusts (sets) the transmission wavelength of the optical transmitter. That is, if the optical transceiver 200n is tied to the Dn terminal of the MUX/DeMUX and the pass wavelength set to the Dn terminal is λn, the optical transceiver 200n connected to the Dn terminal must transmit a signal at a wavelength of λn. The signal passes through the Dn terminal of the MUX/DeMUX and reaches the optical transceiver on the receiving side. At this time, if the optical transmitter does not transmit a signal having a wavelength of λn, the wavelength control unit may generate a wavelength control signal and cause the optical transmitter to transmit a signal of a wavelength of λn. The wavelength control signal (set wavelength information) may be transmitted by the optical transceiver management device to the optical transceiver.

That is, the optical transceiver of the present invention receives the wavelength setting information from the optical transceiver management device through the subcarrier receiving unit, and sets the wavelength of the transmitted optical signal to the wavelength included in the received wavelength setting information through the wavelength adjusting unit.

1.4. Optical transceiver management device

The optical transceiver management apparatus of the present invention transmits predetermined wavelength information to the optical transceiver so that the wavelength control unit of the optical transceiver sets the wavelength of the signal transmitted by the optical transmitter to a wavelength corresponding to predetermined wavelength information received.

The optical transceiver management device is an optical transceiver that inputs a signal to the terminal Dn of the MUX/DeMUX, and transmits wavelength information to set the wavelength to λn, and the optical transceiver receives the wavelength information signal transmitted by the optical transceiver management device and the optical transmitter The wavelength of the transmitted signal is set to λn.

To this end, the optical transceiver management apparatus of the present invention may be configured to include a variable wavelength subcarrier transmission unit 410, a control unit (CPU, EMS), the wavelength variable subcarrier transmission unit 410, the subcarrier transmission unit 411 and It may be configured to include a tunable optical transmitter 412.

1.4.1. Configuration of optical transceiver management device: Example 1

The optical transceiver management apparatus according to the first embodiment is shown in FIG. 2. The optical transceiver management apparatus loads the wavelength setting information on the subcarrier in the subcarrier transmitter and transmits it to the optical transceiver, and the optical transceiver receives it and sets the wavelength of the optical signal transmitted by the optical transceiver as the wavelength included in the wavelength setting information. The wavelength setting information is generated by the control unit of the optical transceiver management device.

The subcarrier transmission unit may include a wavelength variable subcarrier transmission unit 410. The wavelength variable subcarrier transmitter transmits the wavelength setting information to the optical transceiver by varying the wavelength of the subcarrier containing the wavelength setting information into a preset wavelength under control of the controller. For example, the wavelength setting information of the wavelength λn is transmitted to the optical transceiver as a subcarrier signal corresponding to the wavelength λn passing through the terminal Dn of the MUX/DeMUX. The optical transceiver receiving this sets the transmission wavelength to the wavelength λn. In the optical transceiver management apparatus, the setting for the wavelength λn is set by the control unit. This may be preset in the control unit or may be input from the outside through EMS.

1.4.2. Configuration of optical transceiver management device: Example 2

The optical transceiver management apparatus according to the first embodiment is shown in FIG. 3. The optical transceiver management device is a DeMUX 450 having N (N = 1, 2, ... n) terminals in addition to the subcarrier transmission unit 410 composed of a variable wavelength subcarrier transmission unit 411 and a variable wavelength optical transmitter 412. ) Can be provided. Each terminal (D1, D2, ... Dn) of the DeMUX 450 is connected to an optical receiver 412 and a subcarrier receiver 414, respectively, to receive a subcarrier received through the optical branch combiner 610 and the control unit 420 Transfer to. Optical receivers connected to each of the terminals D1, D2, ... Dn of the DeMUX 450 receive an optical signal having a wavelength set to each terminal. Through this, the optical transceiver management apparatus can receive subcarrier signals from a plurality of optical transceivers using different wavelengths connected to the optical transmission line.

The subcarrier transmission unit 410 composed of the variable wavelength subcarrier transmission unit 411 and the variable wavelength optical transmitter 412 varies the wavelength of the subcarrier transmission unit under the control of the control unit 420, and is a terminal of the MUX/DeMUX on the optical transceiver side. The wavelength setting information is transmitted to the optical transceiver as a subcarrier signal corresponding to the wavelength λn passing through Dn.

1.4.3. Configuration of optical transceiver management device: Example 3

The optical transceiver management apparatus of FIG. 4 includes a variable wavelength optical filter 460 instead of the DeMUX 450 in the optical transceiver management apparatus of the second embodiment. The tunable optical filter 460 changes the passing wavelength under the control of the controller 420, and the optical receiver 413 and the subcarrier receiver 414 receive an optical signal having a predetermined wavelength that has passed through the tunable optical filter 460. It is transmitted to the control unit 420.

1.4.3. Configuration of optical transceiver management device: Example 4

In the optical transceiver management apparatus of FIG. 5, an optical switch 440 having n terminals was added to the optical transceiver management apparatus of Examples 1, 2, and 3. Each terminal of the optical switch 440 is connected to each separate optical transmission line through an optical branch combiner, so that the optical transceiver management apparatus of Example 4 can manage optical transceivers connected to n optical transmission lines and set a transmission wavelength. .

The wavelength tunable subcarrier transmitter, DeMUX 450 / wavelength tunable filter, optical receiver, and subcarrier receiver of Examples 1, 2, and 3 are grouped together and represented as a tunable subcarrier transmitter/receiver 410 in FIG.

1.5. Optical branch combiner

The optical transceiver management apparatus transmits the wavelength setting information to the optical transceiver through the optical branch combiner 600 connected to the optical transmission line.

The optical branch combiner 600 splits a signal on the optical transmission line and transmits it to the optical transceiver management device, or combines the signal from the optical transceiver management device with the optical transmission line and transmits it to the optical transceiver.

The optical branch combiner 600 of FIG. 2 is coupled to a single-core optical transmission line and shows a configuration for branching/combining an optical signal to (from) an optical transceiver management device, but in the case of a dual-core optical transmission line, two optical branch combiners 600 is coupled to each optical transmission line, and branching/combining each uplink/downlink signal to/from the optical transmission line.

As shown in Figs. 3 and 4, by adding an additional optical branch combiner 610 to the optical transceiver management apparatus side, it is possible to smoothly set a path for transmission/reception.

In the case of adding an optical switch in FIG. 5, an additional optical branch combiner 610 is added to each terminal of the optical switch, so that it can be connected to the optical branch combiner 600 on each optical transmission line.

2. How to set the wavelength of an optical transceiver using an optical transceiver management device

2.1. Example 1

On the other hand, the method of setting the wavelength of the optical transceiver using the optical transceiver management apparatus according to an embodiment of the present invention comprises the steps of setting the output wavelength of the variable-wavelength subcarrier signal transmission unit of the optical transceiver management apparatus as a first wavelength, the first It may be configured to include the step of transmitting the wavelength information of the wavelength to the optical transceiver.

In this case, the wavelength information of the first wavelength (λ1) is transmitted from the optical transceiver management device to the optical transceiver. When the CPU (optical transceiver management device: controller) of the optical transceiver management device sets the first wavelength (λ1) information, The wavelength variable subcarrier transmission unit 410 transmits the first wavelength information to the subcarrier of the first wavelength ((λ1), and this information is output to the terminal U1 of the MUX/DeMUX through the optical branch combiner, and the optical receiver of the optical transceiver. At this time, the first wavelength information contains information for setting the wavelength of the output light generated by the optical transceiver that has received it to the first wavelength (λ1).

The optical transceiver may set the wavelength of the output light by adjusting the wavelength controller based on the wavelength information of the first wavelength transmitted in this order.

On the other hand, the optical transceiver management device, setting the output wavelength of the variable-wavelength subcarrier signal transmission unit of the optical transceiver management device as a first wavelength as the number of wavelengths used in the optical communication network and the wavelength information of the first wavelength to the optical transceiver. The step of transmitting to can be repeated.

Through this process, a wavelength corresponding to each port can be set in all optical transceivers connected to the optical communication network.

Meanwhile, setting of the wavelength corresponding to each port may be received or input from the outside through the EMS 430 of the optical transceiver management device.

In this way, the output wavelength information of each optical transceiver input from the outside using the optical transceiver management device of the present invention or previously stored in the optical transceiver management device is transmitted to each optical transceiver, and the optical transceiver connected to each optical transmission line is The output wavelength can be set.

Since each terminal of the MUX/DeMUX 800 can pass only an optical signal of a predetermined wavelength, the output wavelength information transmitted from the optical transceiver management device is set to have a wavelength corresponding to each terminal, and a variable wavelength optical transmitter Each wavelength information transmitted by changing the wavelength at 412 is output only to the corresponding wavelength terminal of the MUX/DeMUX 800, and only the optical transceiver connected to the corresponding terminal receives it and sets its own transmission wavelength.

For example, if the optical transceiver management device transmits the wavelength information of the wavelength λ1 to be set to the optical transceiver 200 (T1) connected to the terminals D1 and U1 of the MUX/DeMUX 800 to the MUX/DeMUX 800, the MUX/ The DeMUX 800 outputs a signal only to the terminal U1 corresponding to the wavelength λ1, and the optical transceiver T1 receiving the signal sets the transmission wavelength to λ1.

The optical transceiver management device performs such a process as λ2, λ3,… The wavelength is set for the optical transceiver Tn bitten by all terminals Dn and Un by repeatedly performing λn.

Meanwhile, the optical transceiver in which the wavelength is set through the above-described process can be continuously used by storing the set wavelength information in a nonvolatile memory of the optical transceiver.

2.2. Example 2

On the other hand, in the optical communication network of the present invention as in FIG. 2, the optical transceiver management apparatus of the present invention is configured as described above, as shown in FIGS. 3 to 4, thereby separating and receiving subcarriers from a plurality of optical transceivers connected to an optical transmission line. From there, each optical transceiver can be monitored and controlled by transmitting a subcarrier containing a control signal.

For example, of the optical transceiver management device receiving the subcarrier from the optical transceiver T1 on the COT side that inputs the subcarrier to the terminal D1 of the MUX/DeMUX 800 by the subcarrier receiving unit 414 configured as shown in FIGS. 3 and 4 The management device 420 controls the wavelength variable optical transmitter 412 with the wavelength information (λ1) carried on the corresponding subcarrier, transmits the wavelength information (λ1) to the optical transceiver (R1) on the RT side, and sets the corresponding wavelength to be used. have. In this manner, when the optical transceiver management device does not set the wavelengths used for all optical transceivers as in Example 1, but the host device on the COT side sets the wavelengths for use of the optical transceivers on the COT side, the used wavelength is It is useful when the optical transceiver management device transmits to the optical transceivers on the RT side and sets the wavelength of use of the optical transceivers paired on the RT side.

On the other hand, although the technical idea of the present invention has been described in detail according to the above embodiment, it should be noted that the above embodiment is for the purpose of explanation and not for the limitation thereof. In addition, those skilled in the art in the technical field of the present invention will be able to understand that various embodiments are possible within the scope of the spirit of the present invention.

100, 700: host equipment
200: optical transceiver of the first optical transceiver side
300: optical transceiver to the second optical transceiver
400: optical transceiver management device
500: optical transmission path
600: optical branch combiner
800: MUX/DeMUX

Claims (9)

A first optical transceiver on the COT side;
COT side MUX/DeMUX having an input terminal through which an output of the first optical transceiver is input;
A second optical transceiver on the RT side;
An RT-side MUX/DeMUX having an input terminal through which an output of the second optical transceiver is input;
An optical transmission line for transmitting an optical signal between a first optical transceiver and a second optical transceiver by interconnecting the outputs of the MUX/DeMUX of the COT and the MUX/DeMUX of the RT;
An optical branch combiner for branching or combining an optical signal from the optical transmission line or to the optical transmission line;
An optical transceiver management device for transmitting and receiving an optical signal from and to the optical transmission line through the optical branch combiner;
Consists of including,
The optical transceiver management device,
A subcarrier transmission unit for transmitting predetermined wavelength information to a first optical transceiver and/or a second optical transceiver through the optical branch combiner;
Consisting of including;
Optical communication network, characterized in that. The method of claim 1,
The COT side MUX/DeMUX and RT side MUX/DeMUX each have N MUX side input terminals,
N or less optical transceivers are connected to the MUX-side input terminal;
Optical communication network, characterized in that.
(N=1, 2, 3, …, n) The method of claim 2,
The optical transceiver management device
Transmitting wavelength setting information to optical transceivers connected to each terminal with a pass wavelength set at each terminal of the COT side MUX/DeMUX and/or RT side MUX/DeMUX;
Optical communication network, characterized in that. The method of claim 1,
The first optical transceiver and/or the second optical transceiver,
A subcarrier receiving unit for receiving setting wavelength information from the optical transceiver management device;
A wavelength adjusting unit for setting a wavelength using the set wavelength information received through the subcarrier receiving unit;
Optical communication network, characterized in that configured to include. As an optical transceiver management device that is connected to an optical transmission line through an optical branch combiner and transmits a subcarrier signal to an optical transceiver on the optical transmission line,
A control unit for generating wavelength setting information to be transmitted to the optical transceiver;
A subcarrier transmission unit for storing the generated wavelength setting information in a subcarrier and transmitting it to an optical transceiver;
Optical transceiver management device, characterized in that configured to include. The method of claim 5,
The subcarrier transmission unit,
A variable subcarrier transmission unit configured to set and transmit a subcarrier containing the wavelength setting information to a predetermined wavelength under the control of the control unit;
Optical transceiver management device, characterized in that. The method of claim 5,
A subcarrier receiver for receiving a subcarrier received from the optical transmission line through an optical branch combiner; And additionally,
A front end of the subcarrier receiving unit is connected to a DeMux or a wavelength variable optical filter whose pass wavelength is predetermined for each terminal to receive subcarrier signals from a plurality of optical transceivers using different wavelengths;
Optical transceiver management device, characterized in that. In the method of setting the wavelength of an optical transceiver connected to an optical transmission line and communicating with a carrier wave and a subcarrier,
A wavelength setting information transmission step of transmitting wavelength setting information of a first wavelength to an optical transceiver in an optical transceiver management apparatus connected to an optical transmission line;
A wavelength setting step of setting a wavelength of an optical signal to be generated by the optical transceiver receiving the wavelength setting information as a first wavelength contained in the wavelength setting information;
Optical transceiver wavelength setting method comprising a. The method of claim 8,
The wavelength setting information transmission step,
A first wavelength subcarrier generating step of generating the wavelength setting information of the first wavelength as a subcarrier having a first wavelength;
A wavelength setting information optical transceiver transmitting step of transmitting the generated first wavelength subcarrier to an optical branch combiner and an optical transceiver connected to a terminal of the MUX/DeMuX for passing the first wavelength;
Optical transceiver wavelength setting method comprising a.

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