KR102463303B1 - Auto Tunable Optical Transceiver Module And Optical Communication System Comprising The Same - Google Patents

Abstract

The present invention provides a method of operating a first variable optical module, comprising: transmitting, by the first variable optical module, first channel detection signals composed of optical signals corresponding to each of a plurality of channels to second variable optical modules; receiving a second channel detection signal from any one of the second variable optical modules, and a first channel response signal or the second channel detection signal received in response to the first channel detection signals and setting a channel to transmit/receive an optical signal through the same channel as the first channel response signal or the second channel response signal based on a second channel response signal transmitted in response to .

Description

Auto Tunable Optical Transceiver Module And Optical Communication System Comprising The Same

The present invention relates to a channel variable optical transceiver (hereinafter referred to as a variable optical module) and an optical communication system including the same, and more particularly, to a variable optical module capable of setting its own channel without a separate device such as a channel card. will be.

1 shows a configuration example of a 5G network (5G-PON).

Multiple RNs (Remote Nodes) (=RT, Remote Terminals) connected to multiple Internet subscribers or 5G wireless repeaters (AAU, Active Antena Unit) are connected to COT (Central Office Terminal) through one optical cable. Here, DWDM technology is used for multi-channel optical communication using one optical cable. One optical cable is connected to the optical transceiver module respectively corresponding to a plurality of channels through MUX/DeMUX. In an optical communication environment using DWDM technology, a variable channel (wavelength) optical transceiver module, that is, a tunable optical module (T-SFP) has already been used. The variable optical module is installed in the optical communication equipment or the channel is set when power is applied. In the existing optical communication system, a separate device such as a so-called channel card has been used to set the channel of the variable optical module.

Although such a channel card is a device used for a limited time, such as when an optical communication network including a variable optical module is first set up or when a variable optical module is replaced in the maintenance process, it takes a lot of cost and effort to install and maintain, Increases power consumption. In addition, due to the channel card, it is also a cause of inefficiency that requires one more photoelectric conversion between the optical module and the COT or RT equipment.

The present invention is to provide a variable optical module capable of setting a channel by itself when the variable optical module is mounted in an optical communication system or when the power is refreshed without a separate device for setting a channel such as a channel card. has its purpose in Another object of the present invention is to provide an optical communication system including such a variable optical module.

In order to solve the above problems, in an operating method of a first variable optical module according to the present invention, the first variable optical module converts first channel detection signals composed of optical signals corresponding to a plurality of channels to a second variable transmitting to optical modules, receiving a second channel detection signal from any one of the variable optical modules among the second variable optical modules, and a first channel response received in response to the first channel detection signals setting a channel to transmit and receive an optical signal on the same channel as the first channel response signal or the second channel response signal based on a signal or a second channel response signal transmitted in response to the second channel detection signal characterized by including.

Here, the operation of transmitting the first channel detection signal and the operation of receiving the second channel detection signal are performed in parallel with each other.

Here, when the first response signal is received while transmitting the first channel detection signals, the operation of transmitting the first channel detection signals is stopped and a channel is set based on the first response signal do it with

Here, when the second channel detection signal is received while transmitting the first channel detection signals, the second channel detection response signal is transmitted.

Here, when the second channel detection signal is received while the first channel detection signals are being transmitted, the reception operation of the first channel response signal is stopped.

Here, when the channel setting state recording is initialized, the first channel discovery signals are transmitted.

According to the present invention, in constructing an optical communication network using a variable optical module, the channel card or a device that assists the channel setting of the variable optical module is excluded and the variable optical module automatically performs the channel setting operation. It can greatly improve the efficiency of optical communication network construction and maintenance.

1 shows a configuration example of a 5G network (5G-PON).
2 illustrates the configuration of a variable optical module according to an embodiment of the present invention.
3 is a view showing a channel setting process of a variable optical module according to an embodiment of the present invention;
It is a flowchart.
4 shows a data flow of a channel setting process in an optical communication system including a variable optical module according to an embodiment of the present invention.
5 is a flowchart illustrating a channel setting process of a variable optical module according to another embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described with reference to the drawings. The technical spirit of the present invention may be more clearly understood through the embodiments. The present invention is not limited to the embodiments described below.

2 shows the configuration of a variable optical module according to an embodiment of the present invention.

The variable optical module 100 according to the present invention includes a main controller (MCU) 10, a transceiver optical subassembly (TOSA) 50 including an optical output terminal, and a receiver optical subassembly (ROSA) 40 including an optical input terminal. ) and is provided with a channel detection unit 60 in charge of transmitting and receiving signals in the channel setting step. The channel detector 60 can be viewed as a modem for channel setting (MODEM) in that it transmits/receives a signal for detecting and setting its own channel with respect to the optical communication system in which the variable optical module 100 is mounted. . For the modem for channel setting, Frequency Shift Keying (FSK), Amplitude Shift Keying (ASK), Phase Modulation (PM) FM, AM, and the like may be used.

The variable optical module 100 is also provided with an input/output terminal unit 30 , a data driver 20 , a channel (wavelength) setting unit 70 , and a TEC power driver 80 . The input/output terminal unit 30 is provided for exchanging electrical signals with equipment on which the variable optical module 100 is mounted. The data driver 20 is connected to the ROSA 40 and the TOSA 50 to perform an A/D D/A converter function. The TEC power driver 80 mainly performs a cooling control function for the TOSA 50 including a light source. The channel (wavelength) setting unit 70 may be configured to perform a function of setting the wavelength of the optical signal transmitted from the TOSA 50 according to the channel identified by the channel detection unit 60 .

The channel detection unit 60 includes a channel detection signal generator 61 . The channel detection signal generator 61 operates when the variable optical module 100 is mounted on the equipment of the communication network or when power is newly applied, and generates a plurality of channel detection signals for channel detection into the TOSA. (50) is configured to perform the function of transmitting through. Meanwhile, the channel detection unit 60 includes the channel response signal receiving unit 62 , and provides the channel response signal received from the communication network through the ROSA 40 to the main controller 10 . The channel response signal is returned in response to the channel detection signal from the tunable optical module 100C mounted as a counterpart of the tunable optical module 100 in the communication network. The main controller 10 controls the channel setting unit 70 according to the channel response signal to set the channel of the variable optical module 100 , that is, the transmission wavelength. The plurality of channel detection signals transmitted from the channel detection unit 60 to the outside through the TOSA 50 may include optical signals of all channels that the variable optical module 100 can transmit. For example, when it is assumed that the channels that the variable optical module 100 can transmit are from channel 1 to channel N (N is a natural number greater than 1) according to the wavelength of the optical signal, the plurality of channels is detected. The signal includes a signal that is physically composed of the wavelength of channel 1 (eg, 1289.985 nm) and has the meaning of 'I am channel 1', and a signal that is physically composed of the wavelength of channel 2 (eg, 1290.813 nm) and is composed of 'I am channel 1'. A signal having the meaning of 'I'm channel 2' and, in this way, a signal composed of the wavelengths of channel k (k is a natural number between 1 and N) and having the meaning of 'I'm channel k' can be included. . The channel detection signal does not necessarily include linguistic information, but preferably includes channel identification information indicating which channel the channel detection signal corresponds to.

The channel detection unit 60 changes the wavelength of the light source included in the TOSA 50 to a plurality of wavelengths respectively corresponding to the plurality of channels as described above, and a channel detection signal generator for transmitting the plurality of channel detection signals to the outside (61) may be included. The channel detection signal generator 61 may include, for example, a separate hardware configuration for adjusting the wavelength of the light source described above, but is not limited thereto. As another example, the channel detection signal generating unit 61 is configured as a functional unit in firmware, and substantially includes the main control unit 10 , the data driver 20 , and the channel (wavelength) setting unit 70 . It may be configured to perform the above-described channel detection signal generation function by utilizing the same hardware resource. The fact that it can be configured in hardware or software as described above can be equally applied to the channel response signal receiving unit 62 .

The channel detector 60 may have a channel setting necessity determination function for determining whether there is a need to set or reset a channel. As mentioned above, when the variable optical module 100 is initially driven after being mounted on the communication equipment or when its power is refreshed, the channel setting operation is performed even when a separate channel reset signal is received from the communication equipment. It may be configured to proceed. In addition, it may be configured to store the channel setting state in the memory, and to start the channel discovery operation when the channel setting state is initialized due to power loss or the like. Using volatile memory, channel settings can also be configured to automatically reset upon power loss.

Meanwhile, the channel response signal received by the variable optical module 100 from the communication network is generated by the channel response signal generator 61C of the variable optical module 100C, which is a counterpart of the variable optical module 100 . it has become For example, if the newly installed variable optical module 100 is inserted into the K channel port of the MUX/DeMUX and transmits the plurality of channel detection signals, the channel detection signal receiver 62C of the counterpart variable optical module 100C ( A channel response signal with the meaning of 'it's channel K' is transmitted. As a result, the channel response signal receiving unit 62 of the variable optical module 100 receives the aforementioned channel response signal from the communication network. The tunable optical module 100 sets the wavelength of the K-th channel of the light source according to the channel response signal when the channel response signal is checked through the channel detector 60 , thereby completing the channel setting process.

3 is a flowchart illustrating a channel setting process of a variable optical module according to an embodiment of the present invention.

The channel setting method of the tunable optical module (T-SFP) according to the present invention includes a channel setting necessity determination step (s9), a channel detection and setting process performed when it is determined that a channel setting is necessary (s10), and and a waiting and response process (s20) waiting for reception of a channel detection signal from a counterpart variable optical module.

The channel detection and setting process (s10) is performed in the channel setting necessity determination step (s9), for example, when a variable optical module is newly inserted into a communication device of an optical communication system or its power is refreshed. It is a process that is carried out when the judgment criteria are met. The channel detection and setting process (s10) may be configured to proceed even when a separate channel reset signal is received from the communication device, in addition to initial setup or power refresh. Further, in the variable optical module configured to store the channel setting state in the memory, the channel detection and setting process s10 may be configured to start when the channel setting state is initialized due to power loss or the like. The waiting and response process (s20) can be performed when the channel of the variable optical module is already set and there is no need to set it again, or regardless of whether there is a need to set the channel, and the channel detection and setting The process (s10) and the channel detection and setting process (s10) may be performed in parallel.

4 shows a data flow of a channel setting process in an optical communication system including a variable optical module according to an embodiment of the present invention.

Hereinafter, with reference to FIGS. 3 and 4 together, in an optical communication system including COT and RT, a channel of one of a plurality of variable optical modules 100G mounted on a COT-side optical communication equipment is newly set. The process will be described with an example. This situation occurs, for example, when a new power is applied to the variable optical module or a new variable optical module 100k is mounted to replace the existing variable optical module. More specifically, it is assumed that an abnormality is detected in channel 3 of the optical communication equipment on the COT side and the optical transmission/reception module is replaced with a new variable optical module 100k. Of course, it is assumed that the RT-side optical communication equipment is also equipped with a plurality of variable optical modules 100G according to the present invention. That is, the above-described new variable optical module 100k and the variable optical module 100C corresponding to a count part for transmitting and receiving optical signals are denoted by reference numeral 100C.

Here, if one group of variable optical modules 100G mounted on the COT-side optical communication equipment is the first group, the other group of variable optical modules 100G mounted on the RT-side optical communication equipment can be regarded as the second group. However, this is merely an example for convenience of description. A plurality of variable optical modules mounted on any one optical communication device are viewed as a first group, and a plurality of variable optical modules mounted on other optical communication devices that are in a relationship of transmitting and receiving optical signals of multiple channels with the optical communication device are classified as a second group. can see.

First, when the variable optical module 100k according to the present invention is newly inserted into the No. 3 port of the COT side equipment, the variable optical module 100k in a state in which the channel is not yet set in the channel setting necessity determination step (s9) is It is determined that the channel setting is necessary, and the channel detection and setting process (s10) is entered. On the other hand, in the case of the counterpart variable optical module 100C mounted on port 3 of the RT-side equipment, it is determined that the channel setting is not necessary in the channel setting necessity determination step (s9) because it is operating normally, so that the channel detection and setting is performed. Without entering the process (s10), the standby and response process (s20) proceeds unless an event such as a power refresh (refresh) occurs.

The tunable optical module 100k, which has entered the channel detection and setting process (s10), continuously changes channels (wavelengths) between channels 1 to k, and transmits a plurality of channel detection signals to optical signals corresponding to each channel. (T _x11-1 , T _x11-2 , T _x11-3 , …, T _x11-N )

A transmission channel adjustment and channel detection signal transmission step (s11) is performed.

Looking at this process in more detail, the tunable optical module 100k transmits an optical signal meaning 'I am the k channel' in a state where the wavelength output from the TOSA is set to the wavelength of the k channel, From k=1 to N, iterate sequentially or alternately in any other order. As a more specific example, the tunable optical module 100k transmits a channel detection signal (T _x11-1 ) saying 'I'm channel 1' in a state where the output wavelength is adjusted to channel 1, 1289.985 nm, and outputs After adjusting the wavelength to _1290.813nm , which is channel 2, the channel (Ch k) adjustment and channel detection signal (T _x11-k ) A transmission step (s11) is performed.

However, since the variable optical module 100k is inserted into the 3rd channel port of the COT side equipment as shown in FIG. 4, it is connected to the communication network through the optical filter F3 corresponding to the 3rd channel in the MUX/DeMUX. . Therefore, among the plurality of channel detection signals (T _x11-1 , T _x11-2 , T _x11-3 , ..., T _x11-N ), the optical signal transmitted to the communication network through the MUX/DeMUX is the third channel wavelength. It is defined by the configured channel detection signal (T _x11-3 ). That is, only the signal 'I am channel 3' composed of the wavelength of channel 3 among the plurality of channel detection signals described above can be transmitted to the communication network through the MUX, and the remaining signals are blocked by the optical filter F3. do. A counterpart of the variable optical module that has received the channel detection signal (T _x11-3 ) transmitted through the communication network, that is, the variable optical module 100C mounted on the 3rd channel port on the RT side, waits for receiving the channel detection signal When the channel detection signal T _x11-3 is received during (s21), as a reply, it is physically composed of the same wavelength of channel 3 and has the meaning of 'Yes, you are channel 3'. The signal R _x22-3 is transmitted (s22).

Here, if the channel of the variable optical module 100C is set to the third channel according to the aforementioned situation setting, the channel response signal R _x22-3 may be transmitted according to the already set channel. If the channel of the tunable optical module 100C is not yet set, the tunable optical module 100C transmits the optical signal to be transmitted according to the channel identification information included in the received channel detection signal T _x11-3 . After matching the channels of , the channel response signal R _x22-3 may be transmitted.

The replaced variable optical module 100k waits (s12) to receive a channel response signal in parallel with the above-described channel adjustment and channel detection signal transmission step (s11). Since the channel response signal R _x22-3 has a wavelength of channel 3, it passes through the optical filter F3 of the MUX/DeMUX and is transmitted to the variable optical module 100k. When this channel response signal (R _x22-3 ), that is, a signal meaning 'Yes, you are channel 3' is received from the communication network, the variable optical module 100k performs the task of transmitting another channel detection signal. It stops and sets its own channel according to the received channel response signal (R _x22-3 ) (s13). In the case of this embodiment, channel 3 is set. With this, the channel setting operation is finished, and the variable optical module 100k operates as an optical module for transmitting and receiving optical signals of channel 3 thereafter.

In the above description, it is assumed that the variable optical module on the COT side is replaced, but even if the COT side and the RT side are changed, the channel setting method can be applied in the same way. In addition, the channel setting operation of a plurality of variable optical modules may be performed simultaneously. Even in this case, the channel detection signal that does not fit the channel of the port on which the variable optical module is mounted due to the physical optical filtering of the MUX/DeMUX cannot be transmitted to the communication network in the end, so the channel setting operation of a plurality of variable optical modules is also without confusion. can proceed simultaneously. As described above, since the waiting and response process (s20) can proceed in parallel regardless of whether the channel detection and setting process (s10) is progressed, in the present embodiment, the COT-side variable optical module 100k and its counter Even when the RT-side variable optical module 100C, which is a part, is replaced at the same time, the channel detection signal and the channel response signal are exchanged between the two parties, and the channel setting operation can be performed substantially simultaneously. Even when several pairs of variable optical modules that are in a counterpart relationship are replaced at the same time or the entire system is set up or reset, all variable optical modules automatically set channels according to the port they are inserted into. work can be completed.

5 is a flowchart illustrating a channel setting process of a variable optical module according to another embodiment of the present invention.

The channel setting method of the variable optical module (T-SFP) according to the present embodiment also includes a channel setting necessity determination step (s9), and a channel detection and setting process (s10a), which is performed when it is determined that the channel setting is necessary, and a waiting and response process (s20a) waiting for reception of a channel detection signal from a counterpart variable optical module. This embodiment will also be described with reference to FIG. 4 together with FIG. 5 .

The channel detection and setting process (s10a) is similar to the embodiment of Fig. 3 described above, but when a channel response signal is received (s12), a channel confirmation signal is generated along with the channel setting operation of setting the wavelength of the light source. It is different from the above-described embodiment in that it transmits (s14). The channel confirmation signal (not shown) is transmitted with the same wavelength as the above-described channel response signal R _x22-3 . The channel confirmation signal (not shown) is 'Yes. You are also channel 3'. In addition, when the RT-side counterpart variable optical module 100C receives the channel confirmation signal (s23), it confirms that the channel of the COT-side variable optical module 100k is confirmed to be the third channel, and responds to it again. It may also be (s24).

On the other hand, when the channel confirmation signal is received (s23) by the variable optical module 100C on the RT side, the channel setting of the variable optical module 100C is not completed. In this state, it may be configured to set the channel of the variable optical module 100C based on the channel confirmation signal.

In the above description, the channel detection signal, the channel response signal, and the channel confirmation signal may be optical signals modulated with different waveforms or intensities. 'I'm channel k', 'Yes. The description that may include meanings such as 'you are channel k' and 'you are also channel k' is amplified to help understand the configuration of the invention, and a pair of tunable optical modules in a counterpart relationship with each other It is not necessary to be a sufficient, linguistically interpretable signal that contains identification information of a channel corresponding to the nature of each signal in between.

100, 100k, 100C: variable optical module
10: main control unit 20: data driver
30: input/output terminal unit 40: ROSA
50: TOSA 60, 60C: Channel detector

Claims (6)

A method of operating a first variable optical module, comprising:
transmitting, by the first variable optical module, first channel detection signals composed of optical signals corresponding to each of the plurality of channels to second variable optical modules;
receiving a second channel detection signal from any one of the second variable optical modules; and
The first channel response signal or the second channel based on a first channel response signal received in response to the first channel detection signals or a second channel response signal transmitted in response to the second channel detection signal The method of operating the first variable optical module, comprising the step of setting a channel to transmit and receive an optical signal on the same channel as the response signal. The method according to claim 1,
The operation of transmitting the first channel detection signal and the operation of receiving the second channel detection signal are performed in parallel with each other, the operating method of the first optical module. The method according to claim 1,
When the first channel response signal is received while transmitting the first channel detection signals, the operation of transmitting the first channel detection signals is stopped, and a channel is set based on the first channel response signal to the method of operation of the first optical module. The method according to claim 1,
When the second channel detection signal is received while transmitting the first channel detection signals, the method of operating the first optical module, characterized in that the second channel detection signal is transmitted. 5. The method according to claim 4,
When the second channel detection signal is received while transmitting the first channel detection signals, the method of operating the first optical module, characterized in that the receiving operation of the first channel response signal is stopped. The method according to claim 1,
When the channel setting state recording is initialized, the method of operating the first optical module, characterized in that transmitting the first channel detection signals.

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