KR101871431B1 - Method and apparatus for synchronizing time between nodes - Google Patents

Abstract

A method and apparatus for time synchronization between nodes in a network composed of a plurality of nodes is disclosed. The inter-node time synchronization apparatus according to an embodiment of the present invention distinguishes a synchronous optical signal for inter-node synchronization from a data optical signal for data transmission and synchronizes the nodes using the separated synchronous optical signal.

Description

[0001] The present invention relates to a method and apparatus for synchronizing time between nodes,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a network composed of a plurality of nodes, and more particularly to an inter-node synchronization technique.

Various methods are used to synchronize terminals away from each other. When a global positioning system (GPS) is used, the terminals perform synchronization so that they have the same reference time. To this end, APs (Access Points) receive and synchronize timing information from a global navigation satellite system (GNSS) satellite and then synchronize network devices connected to the AP using pseudo-ranging . Also, there is a method in which a mobile terminal having a GPS receiving function receives time information and transmits the received time information to a device connected to the mobile terminal, and synchronizes the devices as they update the time.

There is a method of synchronizing the clocks by determining the transport time between the master node and the slave node through the synchronization packet in the Packet Switched Data Network so that the transport time between the nodes becomes the same. In addition, there is a method of synchronizing time using a standard time transmission protocol, such as a synchronization node (synch) message and a delay request (delay request) message between a master node clock, a bridge node clock, and a slave node clock.

However, the synchronization method using the GPS has a problem that all the nodes must receive the GPS signal because the GPS has to serve as the reference clock. In order to increase the accuracy of time, the synchronization method using the synchronization packet must synchronize with consideration of the physical layer (OSI layer 1) and the data link layer (OSI layer 2) May occur.

According to one embodiment, a method and apparatus for synchronizing time between nodes in a network composed of a plurality of nodes without time delay and synchronization error is proposed.

A method for time synchronization between nodes in a network composed of a plurality of nodes according to an exemplary embodiment is characterized in that a synchronous optical signal for inter-node synchronization is distinguished from a data optical signal for data transmission, And synchronizing.

In the step of synchronizing the nodes, the data optical signal is transmitted through the data path, and the synchronous optical signal can be transmitted through the optical path in a separate path separate from the data path. Alternatively, in the step of synchronizing the nodes, the data optical signal may be transmitted through the data path, and the synchronous optical signal may be transmitted through the photoelectric conversion and the electrooptic conversion in a separate path separately from the data path. The synchronization optical signal may have a wavelength different from that of the data optical signal. Each node can be connected via fiber optic cable.

A method of synchronizing an inter-node time according to another embodiment includes a step of generating a synchronous optical signal by the master node, multiplexing the synchronous optical signal and the data optical signal, and transmitting the synchronous optical signal and the data optical signal, Demultiplexing the multiplexed optical signal, demultiplexing the demultiplexed optical signal to demultiplex the demultiplexed optical signal into a plurality of demultiplexed optical signals, multiplexing the demultiplexed optical signal, and transmitting the demultiplexed optical signal to the slave node. And a synchronization optical signal processing step of extracting a synchronization signal in the form of an electrical signal from the separated synchronization optical signal.

The generating of the synchronizing optical signal according to an exemplary embodiment includes generating a synchronizing optical signal, distributing the generated synchronizing optical signal into a plurality of synchronizing optical signals, And multiplexing and transmitting. At this time, each of the divided synchronizing optical signals has the same characteristics and can have light intensity according to the distribution ratio.

The step of distributing a synchronous optical signal according to an embodiment may include a step in which a relay node receives an optical signal multiplexed from an upper node, a step of demultiplexing the multiplexed optical signal to separate a data optical signal into a synchronous optical signal, Dividing the synchronized optical signal into a plurality of synchronous optical signals, processing the separated data optical signals, and multiplexing the divided synchronous optical signals with each data optical signal processed and transmitting do. At this time, each of the divided synchronizing optical signals has the same characteristics and can have light intensity according to the distribution ratio.

The step of processing the synchronous optical signal according to an exemplary embodiment may include a step in which each slave node receives an optical signal multiplexed from an upper node, demultiplexing the multiplexed optical signal into a data optical signal and a synchronous optical signal, And extracting a synchronizing optical signal in the form of an electrical signal by photoelectrically converting the separated synchronizing optical signal.

According to another aspect of the present invention, there is provided a method of synchronizing an inter-node time, comprising: generating a synchronous optical signal by a master node, multiplexing and transmitting a synchronous optical signal and a data optical signal, A synchronous optical signal distributing step of multiplexing and transmitting a plurality of electro-optic-converted synchronous optical signals after the demultiplexing and demultiplexing of the separated synchronous optical signals by photoelectric conversion and electro-optical conversion, And a synchronization optical signal processing step of extracting a synchronization signal in the form of an electric signal from the separated synchronization optical signal through demultiplexing.

The step of generating a synchronous optical signal according to an embodiment includes the steps of generating a synchronous optical signal, distributing the generated synchronous optical signal into a plurality of synchronous optical signals, And multiplexing and transmitting. At this time, each of the divided synchronizing optical signals has the same characteristics and can have light intensity according to the distribution ratio.

The step of distributing a synchronous optical signal according to an embodiment may include a step in which a relay node receives an optical signal multiplexed from an upper node, a step of demultiplexing the multiplexed optical signal to separate a data optical signal into a synchronous optical signal, Converting the converted synchronous optical signal into an electrical signal and converting the electrical signal into a plurality of synchronous optical signals; processing the separated data optical signal; And multiplexing the optical signal with each data optical signal processed and transmitting the multiplexed optical signal. At this time, multiplexing and transmitting includes the steps of distributing one synchronized signal converted into all-optical signals into a plurality of synchronous optical signals, and multiplexing the distributed synchronous optical signals with each data optical signal processed and transmitting can do.

The step of processing the synchronous optical signal according to an exemplary embodiment may include a step in which each slave node receives an optical signal multiplexed from an upper node, demultiplexing the multiplexed optical signal into a data optical signal and a synchronous optical signal, And extracting a synchronizing optical signal in the form of an electrical signal by photoelectrically converting the separated synchronizing optical signal.

According to another aspect of the present invention, there is provided an apparatus for time synchronization between nodes in a network composed of a plurality of nodes, comprising: a synchronization optical signal generator for generating a synchronization optical signal and multiplexing the synchronization optical signal and the data optical signal; A synchronous optical signal distributor for demultiplexing the multiplexed optical signals and demultiplexing the multiplexed optical signals into a plurality of synchronous optical signals and demultiplexing the multiplexed optical signals and demultiplexing the multiplexed optical signals from the synchronous optical signal distributor And a synchronization optical signal processing unit for extracting a synchronization signal in the form of an electric signal from the separated synchronization optical signal through demultiplexing.

The synchronization optical signal generating unit may include a synchronization optical signal generator for generating a synchronization optical signal, an optical splitter for distributing the synchronization optical signal generated from the synchronization optical signal generator to a plurality of synchronization optical signals, And at least one multiplexer for multiplexing and transmitting each synchronous optical signal with each data optical signal.

The synchronizing optical signal distributor according to an exemplary embodiment includes a multiplexer for receiving an optical signal multiplexed from an upper node and demultiplexing the multiplexed optical signal and separating the multiplexed optical signal into a data optical signal and a synchronous optical signal, And at least one multiplexer for multiplexing each of the synchronous optical signals distributed in the optical distributor with each data optical signal processed and transmitting the synchronous optical signals.

The synchronous optical signal processing unit according to an exemplary embodiment includes a multiplexer that receives an optical signal multiplexed from an upper node and demultiplexes the multiplexed optical signal into a data optical signal and a synchronous optical signal, And extracts a synchronizing optical signal in the form of an electric signal.

According to another aspect of the present invention, there is provided an apparatus for time synchronization between nodes in a network composed of a plurality of nodes, comprising: a synchronization optical signal generator for generating a synchronization optical signal and multiplexing the synchronization optical signal and the data optical signal; A synchronous optical signal distributor for demultiplexing the multiplexed optical signals and demultiplexing the multiplexed optical signals, and for multiplexing the plurality of optical signals, which have undergone electrooptical conversion and electrooptic conversion, from the synchronous optical signal distributor, And a synchronization optical signal processing unit for extracting a synchronization signal in the form of an electric signal from the separated synchronization optical signal through demultiplexing.

The synchronization optical signal generating unit may include a synchronization optical signal generator for generating a synchronization optical signal, an optical splitter for distributing the synchronization optical signal generated from the synchronization optical signal generator to a plurality of synchronization optical signals, And at least one multiplexer for multiplexing and transmitting each synchronous optical signal with each data optical signal.

The synchronizing optical signal distributor according to an exemplary embodiment includes a multiplexer for receiving an optical signal multiplexed from an upper node and demultiplexing the multiplexed optical signal and separating the multiplexed optical signal into a data optical signal and a synchronous optical signal, An electro-optical converter for electro-optically converting the electrical signal converted by the photoelectric converter into a plurality of synchronous optical signals, And at least one multiplexer for multiplexing and transmitting the processed data optical signals.

The synchronous optical signal processing unit according to an exemplary embodiment includes a multiplexer that receives an optical signal multiplexed from an upper node and demultiplexes the multiplexed optical signal into a data optical signal and a synchronous optical signal, And extracts a synchronizing optical signal in the form of an electric signal.

According to an embodiment, in a network composed of a plurality of nodes, a master node distributes and transmits a synchronous optical signal in the form of an optical signal to a plurality of slave nodes, so that the same synchronization signal is transmitted to each slave node at the same speed, Thereby achieving synchronization without synchronization error.

Further, in an environment where the photoelectric conversion and the light conversion are inevitably required at the relay node, the photoelectric conversion and the light conversion are performed so as to minimize the time delay, so that the synchronization packet generated at the master node is transmitted to the plurality of slave nodes And can synchronize each slave node.

FIG. 1 is a configuration diagram of a network system including a plurality of nodes to which the present invention is applied,
FIG. 2 is a network configuration diagram for time synchronization between nodes according to an embodiment of the present invention; FIG.
3 is a network configuration diagram for synchronous optical signal processing according to an exemplary embodiment of the present invention,
4 is a network configuration diagram including a plurality of relay nodes according to an embodiment of the present invention.
5 is a detailed configuration diagram of a synchronization optical signal generator according to an embodiment of the present invention,
6 is a detailed configuration diagram of a synchronization optical signal distributor according to an embodiment of the present invention,
7 is a detailed configuration diagram of a synchronization optical signal distributor according to another embodiment of the present invention,
8 is a configuration diagram of a synchronization optical signal processing unit according to an embodiment of the present invention,
9 is a flowchart illustrating a method of time synchronization between nodes according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention of the user, the operator, or the custom. Therefore, the definition should be based on the contents throughout this specification.

1 is a configuration diagram of a network system including a plurality of nodes to which the present invention is applied.

1, the network system includes a master node 1 for providing a synchronization clock, a relay node 2, 3 for receiving and delivering a synchronization clock from the master node 1, And a slave node 5 for receiving and synchronizing the clock.

The nodes 1, 2, 3, and 5 are connected to each other through a transmission medium for transmitting optical signals. The transmission medium may be an optical cable composed of an optical fiber. For example, the master node 1 and the first relay node 2, the first relay node 2 and the second relay node 3, the second relay node 3 and the slave node 5 are respectively connected to the optical cable Lt; / RTI >

The master node 1 transmits and receives data to and from a lower node through an optical transceiver. The first relay node 2 transmits and receives data to and from the master node 1 via an optical transceiver and is connected to the lower nodes through another optical transceiver port.

The second relay node 3 transmits and receives data to and from the upper node through the optical transceiver. The ancestor node may be a master node and may be a first relay node (2). The second relay node 3 performs photoelectric conversion and electro-optical conversion in order to multiplex or demultiplex the data. The second relay node 3 converts the demultiplexed signal into an electric signal and transmits it to the slave node 5.

The second relay node 3 receives and processes optical signals from the upper node, demultiplexes the processed data, and electrically transmits the optical signals to a line card on a shelf through a backplane. The second relay node 3 may each include a plurality of line cards. The line card can electrically receive signals from the backplane, convert them into a plurality of optical signals, and transmit them to each slave node 5.

1, the network system may include both the first relay node 2 and the second relay node 3, but may include only the first relay node 2 and the second relay node 2 3). Further, the number of the first relay node 2 and the number of the second relay node 3 may be plural.

The slave node 5 receives an optical signal from an upper node. The upper node may be the first relay node (2) or the second relay node (3). The slave node 5 can forward the data to the upper node in the opposite echo of the above-described process. For example, the slave node 5 can send and receive data to and from the second relay node 3. The slave node 5 can use an optical transceiver for data transmission / reception.

2 is a network configuration diagram for inter-node time synchronization according to an embodiment of the present invention.

2, a network according to an embodiment includes a master node 1, a first relay node 2, a second relay node 3, and a slave node 5. [

The master node 1 generates a synchronization optical signal for synchronization. The synchronizing optical signal may be generated through an electro-optical converter. The synchronization optical signal may have a wavelength different from that of the data optical signal for data transmission. For example, when the wavelength of the data optical signal is? ₁ , the wavelength of the synchronizing optical signal is? ₂ . This is because the data optical signal and the synchronous optical signal are distinguished from each other and the transmission path is different.

The master node 1 performs electro-optical conversion (E / O) on the data optical signal and the synchronizing optical signal. The E / O converted data optical signal and the synchronizing optical signal are multiplexed by the multiplexer 124. In the present invention, a multiplexer is described mainly with respect to a wavelength division multiplexer (WDM), but the type of the multiplexer is not limited thereto. The master node 1 multiplexes the optical signal through the multiplexer 124 and then transmits it to the lower node, for example, the first relay node 2 through the optical cable.

The first relay node 2 receives the multiplexed optical signal and demultiplexes the multiplexed optical signal into a data optical signal and a synchronous optical signal. The synchronizing optical signal is divided into a plurality of identical synchronizing optical signals via an optical distributor 222, such as an optical coupler, without photoelectric conversion. The synchronized optical signal distributed through the optical distributor 222 has the same physical characteristics as the input optical signal, but is only weakened as the optical intensity is distributed. The number of optical distributions may vary depending on the number of connections to the lower node.

The first relay node 2 photoelectrically converts (O / E) the data optical signal, processes the data optical signal, and performs E / O conversion on the data optical signal to transmit it to the multiplexer 224. The multiplexer 224 receives and multiplexes the synchronized optical signal distributed through the optical splitter 222 and the data optical signal E / O converted after data processing, and transmits the multiplexed optical signal to the lower node.

The second relay node 3 receives the optical signal from the first relay node 2 through the multiplexer 320 and demultiplexes the optical signal to separate the data optical signal and the synchronous optical signal. The separated data optical signal is photoelectrically converted (O / E), data-processed, and then converted into E / O through one or two or more E / O converters and output as a data optical signal. At this time, the number of all-optical converters may vary depending on the number of lower nodes. On the other hand, the synchronous optical signal separated by the multiplexer 320 is photoelectrically converted (O / E), converted into a synchronous signal in the form of an electric signal, and converted into a plurality of synchronous optical signals through a plurality of electric converters. Each data optical signal and all the synchronous optical signals that have undergone the E / O conversion are multiplexed through a multiplexer 326 and transmitted to the slave node 5.

As shown in FIG. 2, the second relay node 3 describes a concept that a synchronous optical signal is connected to a lower node through photoelectric conversion (O / E) and electro-optical conversion (E / O) .

The slave node 5 demultiplexes the optical signal transmitted from the second relay node 3 through the multiplexer 520 to separate the data optical signal and the synchronous optical signal. At this time, the data optical signal is converted into an electric signal and used in the slave node 5. The synchronization optical signal is also converted into an electrical signal and used as a synchronization signal for data processing.

As described above with reference to Fig. 2, the synchronous optical signal is transmitted through a separate transmission path separate from the data path from the master node 1 to the slave node 5. [ At this time, the transmission path of the synchronous optical signal is divided into optical signals without data processing or simple optical and electrical conversion. Accordingly, the synchronization signal received by each slave node has a very small time delay or error. That is, a time delay or an error occurring in the network occurs while processing data in the physical layer, the data link layer, and the network layer. However, the synchronization signal of the present invention uses optical distribution and sometimes performs simple photoelectric conversion and electric conversion use. Accordingly, the time delay and error between the synchronization signals can be minimized compared with the case of using the data path requiring data processing.

When the slave node 5 transmits the data to the master node 1 in accordance with the synchronization signal, the master node 1 can receive the data with the minimum time delay and error from the slave node 5. The process of transmitting data from the slave node 5 to the master node 1 is the same as that in the case of data being transmitted downward from the master node 1 to the slave node 5, .

3 is a network configuration diagram for synchronous optical signal processing according to an embodiment of the present invention.

Referring to FIG. 3, the master node 1 includes a data optical signal processing unit 10 and a synchronization optical signal generating unit 12. The synchronous optical signal generating unit 12 generates a synchronous optical signal, receives the data optical signal from the data optical signal processing unit 10, multiplexes the optical data signal together with the synchronous optical signal, and outputs the multiplexed optical signal to the output And outputs it to the relay node 4 through the port. The synchronizing optical signal generating unit 12 may include an electro-optical converter for generating a synchronizing optical signal in itself.

The relay node 4 may be a plurality of nodes 4-1, 4-2, ..., 4-n, and each relay node 4-1, 4-2, ..., 4- (40) and a synchronization optical signal distributor (42). The synchronous optical signal distributor 42 receives an optical signal input from an upper node, for example, the master node 1, and separates the optical signal into a data optical signal and a synchronous optical signal. The separated data optical signal is transmitted to the data optical signal processing unit 40. The separated synchronous optical signal is replicated through one or more synchronization optical signals through the distribution. The thus-synchronized synchronous optical signal is multiplexed with the data optical signal processed by the data optical signal processing unit 40 and then transmitted to the slave node 5 at a lower level. At this time, the output of the data optical signal processing unit 40 is one or a plurality of data optical signals. Each of the data optical signals and each of the divided synchronization optical signals may be multiplexed and then transmitted to the slave node 5.

The slave nodes 5-1 to 5-2 are connected to the slave nodes 5-1 and 5-2, , ..., 5-n, 6-1, 6-2, ..., 6-n include a data optical signal processing unit 50 and a synchronous optical signal processing unit 52. The synchronization optical signal processing unit 52 receives an optical signal from an upper node, for example, the relay node 4-n, and separates the optical signal into a data optical signal and a synchronization optical signal. The separated data optical signal is transmitted to the data optical signal processing unit 50. The synchronous optical signal processing unit 52 processes the separated synchronous optical signal into an electrical synchronous signal.

The use of the synchronization optical signal generating unit 12, the synchronization optical signal distributing unit 42 and the synchronization optical signal processing unit 52 as described above allows the slave node 5 The synchronization signal can be transmitted while minimizing the error of the delay time.

4 is a network configuration diagram including a plurality of relay nodes according to an embodiment of the present invention.

Referring to FIG. 4, the relay nodes 4 have a vertical relationship and have a horizontal relationship with each other at the same level. For example, the relay node 1-1 located at the same level, the relay node 1-2, ... , And the relay node 1-K have a horizontal relationship with each other.

Since the slave nodes 5 receive the same synchronous optical signal from the master node 1, the slave nodes 5 can utilize the synchronization signal while minimizing the delay time. In this structure, the slave nodes 5 can provide isochronism when collecting data or collecting the state at substantially the same time at the same time.

5 is a detailed configuration diagram of a synchronization optical signal generator according to an embodiment of the present invention.

Referring to FIG. 5, the master node 1 includes a data optical signal processing unit 10 and a synchronization optical signal generating unit 12. The synchronization optical signal generating unit 12 includes a synchronization optical signal generator 120, a light distribution unit 122, and a multiplexer 124-1, 124-2, ..., 124-n. The synchronization optical signal generating unit 12 is connected to the data optical signal processing unit 10 through one or more optical cables.

The synchronization optical signal generator 120 generates a synchronization optical signal. The optical distributor 122 distributes the synchronization optical signal generated by the synchronization optical signal generator 120 into a plurality of synchronization optical signals. The optical distributor 122 may be an optical coupler. The distributed synchronous optical signals have the same characteristics as each other, only the light intensity is reduced by the distribution ratio.

Each of the multiplexers 124-1, 124-2, ..., 124-n receives the respective data optical signals from the data optical signal processing unit 10 and receives the respective synchronous optical signals distributed through the optical distributor 122. Then, each input optical data signal and each synchronization optical signal are multiplexed and then output. Each of the multiplexers 124-1, 124-2, ..., 124-n is connected to a lower connection point of the master node, and this connection point can be a point where the master node is connected to the relay node.

6 is a detailed configuration diagram of a synchronous optical signal distributor according to an embodiment of the present invention.

6, the first relay node 2 includes a data optical signal processing unit 20 and a synchronous optical signal distributor 22, and the synchronous optical signal distributor 22 processes the synchronous optical signal And includes a multiplexer 220, a multiplexer 222, and multiplexers 224-1, 224-2, ..., 224-n.

The multiplexer 220 connected to an upper node, for example, a master node or another relay node receives an optical signal from an upper node and demultiplexes the optical signal into a data optical signal and a synchronization optical signal. The multiplexer 220 is connected to the data optical signal processing unit 20 and inputs the separated data optical signal to the data optical signal processing unit 20. The data optical signal processing unit 20 determines a node to which the data optical signal is to be transmitted through a data processing process, and then inputs the data optical signal to the synchronous optical signal distribution unit 22. At this time, the data optical signal processing unit 20 converts the data optical signal into an electric signal through photoelectric conversion, processes the data, converts it into an optical signal through forward conversion, and transmits the optical signal to the synchronizing optical signal distributor 22.

The optical distributor 222 distributes the synchronized optical signal separated through the multiplexer 220 to a plurality of optical signals. At this time, the distributed synchronous optical signal has the same characteristics and only the light intensity decreases by the distribution ratio.

Each of the multiplexers 224-1, 224-2, ..., and 224-n multiplexes the respective synchronous optical signals distributed through the optical distributor 222 and the respective data optical signals received from the data optical signal processing unit 20. [ Each of the multiplexers 224-1, 224-2, ..., 224-n is connected to a lower node connection point, for example, to the next relay node or a slave node.

7 is a detailed configuration diagram of a synchronization optical signal distributor according to another embodiment of the present invention.

Referring to FIG. 7, the second relay node 3 includes a data optical signal processing unit 30 and a synchronization optical signal distribution unit 32. The synchronizing optical signal distributing unit 32 has a multiplexer 320, a photoelectric converting unit 322, all-optical converting units 324-1, 324-2, ..., 324-n And multiplexers 326-1, 326-2, ..., 326-n.

Referring to FIG. 6, the synchronous optical signal distributor 32, which is different from the synchronous optical signal distributor 22 described above with reference to FIG. 7, performs photoelectric conversion and electro-optical conversion on the synchronous optical signal. The structure is connected to one shelf in a line card format and the data optical signal is transmitted to each line card through the backplane. Dispensing Synchronizing the optical signal and connecting it to a line card using fiber optic cables complicates the system. Therefore, in the above-described structure, it may be advantageous to transmit the synchronization signal through simple photoelectric conversion and electro-optical conversion from the inside. This structure can be a way to overcome the light intensity reduction of the synchronous optical signal when the relay node is connected over several stages.

7, the synchronous optical signal distributor 32 receives an optical signal from an upper node and demultiplexes the optical signal into a data optical signal and a synchronous optical signal through a multiplexer 320. [ The separated data optical signal is input to the data optical signal processing unit 30 and the data optical signal processing unit 30 processes the data and then inputs the data optical signal to the synchronous optical signal distributor 32 in the form of a plurality of data optical signals. The separated synchronized optical signal is converted into an electrical signal via a photoelectric conversion unit 322. The electrical signal is converted into a synchronous optical signal by being connected to each of the all-optical converters 324-1, 324-2, ..., and 324-n .

Each of the multiplexers 326-1, 326-2, ..., and 326-n receives the synchronization optical signal from each of the all-optical converters 324-1, 324-2, ..., and 324-n, And receives the respective data optical signals. Then, each input optical signal and each data signal are multiplexed. A plurality of optical signals multiplexed in this manner are connected to the lower node connection point and transmitted to the lower node. 326-2, ..., and 326-n according to one embodiment and a multiplexer 326-1, 326-2, ..., and 326-n, It may be controlled to be connected to a plurality of multiplexers.

8 is a configuration diagram of a synchronization optical signal processing unit according to an embodiment of the present invention.

Referring to FIG. 8, the slave node 5 includes a data optical signal processing unit 50 and a synchronization optical signal processing unit 52. The synchronization optical signal processing unit 52 includes a multiplexer 520 and an all-optical conversion unit 522. [

The multiplexer 520 demultiplexes the optical signal received from the upper node into a data optical signal and a synchronous optical signal. The separated data optical signal is connected to the connection point so as to be connected to the data optical signal processing unit 50. The separated synchronous optical signal is input to the electric-to-optical converter 522, the electric-optical converter 522 converts the synchronous optical signal into an electric signal, extracts the synchronous signal, and provides the electric signal to the slave node 5 for use.

5 to 8, the number (? ₁ ,? ₂ ) of optical signal wavelengths used in the above-described network is merely indicated to distinguish between a data optical signal and a synchronous optical signal. A third wavelength may be used in a particular section or in a particular module. That is, when the same optical cable is used, the wavelength of the data optical signal and the wavelength of the synchronous optical signal need to be different from each other.

The synchronizing optical signal has a unidirectional flow from the master to the slave. The data optical signal is also transmitted in the reverse direction from the slave node to the master node. That is, only the synchronous optical signal has a unidirectional flow, and the data has a bi-directional data flow like a normal network.

9 is a flowchart illustrating a method of time synchronization between nodes according to an embodiment of the present invention.

Referring to FIG. 9, in a network including a plurality of nodes, a time synchronization apparatus according to an embodiment generates a synchronization optical signal, and multiplexes the synchronization optical signal and the data optical signal (900). The process can be performed at the master node. At this time, the time synchronization apparatus generates a synchronization optical signal, distributes the generated synchronization optical signal into a plurality of synchronization optical signals, and multiplexes the distributed synchronization optical signals with each data optical signal.

Then, the time synchronization apparatus demultiplexes the multiplexed optical signals, demultiplexes the multiplexed optical signals, distributes the separated optical signals into a plurality of synchronous optical signals, and multiplexes the multiplexed optical signals (910). The process can be performed at each relay node. At this time, the time synchronization apparatus receives the multiplexed optical signal from the upper node, demultiplexes the multiplexed optical signal into a data optical signal and a synchronous optical signal, and distributes the separated synchronous optical signal into a plurality of synchronous optical signals. Then, the distributed synchronization optical signals can be multiplexed with the data optical signals processed and transmitted.

The time synchronization apparatus according to another embodiment demultiplexes multiplexed optical signals, demultiplexes the separated optical signals, and multiplexes the plurality of all-optical converted optical signals. At this time, the time synchronization apparatus receives the multiplexed optical signal from the upper node, demultiplexes the multiplexed optical signal into a data optical signal and a synchronous optical signal, and converts the separated synchronous optical signal into an electric signal by photoelectric conversion. Then, the converted electrical signal can be converted into a plurality of synchronous optical signals, and then the electro-optically converted synchronous optical signals can be multiplexed with each data optical signal processed and transmitted.

Next, the time synchronization apparatus according to an exemplary embodiment demultiplexes the multiplexed optical signals and demultiplexes the multiplexed optical signals to extract a synchronization signal in the form of an electrical signal from the separated optical signals (920). The process can be performed at each slave node. At this time, the time synchronization apparatus receives the multiplexed optical signal from the upper node and demultiplexes the multiplexed optical signal into a data optical signal and a synchronous optical signal. Then, the separated synchronous optical signal can be photoelectrically converted to extract the synchronous optical signal in the form of an electric signal.

The embodiments of the present invention have been described above. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

Claims (25)

A method for performing time synchronization between a master node and a plurality of slave nodes included in a network,
Separating a synchronous optical signal for node synchronization of the optical signal and a data optical signal for data transmission;
Transmitting the data optical signal through a data path;
Transmitting a synchronization optical signal through a separate path separate from the data path; And
Processing time synchronization between the master node and the plurality of slave nodes using a synchronization signal in the form of an electrical signal detected from the synchronization optical signal;
To-node time synchronization. 2. The method of claim 1, wherein the step of transmitting the synchronization optical signal comprises:
And transmitting the synchronous optical signal through an optical path in a separate path separate from the data path. 2. The method of claim 1, wherein the step of transmitting the synchronization optical signal comprises:
And transmitting the synchronous optical signal through a photoelectric conversion and an electro-optical conversion in a separate path separate from the data path. The method according to claim 1,
Wherein the synchronization optical signal has a wavelength different from that of the data optical signal. The method according to claim 1,
Wherein at least one node included in the network is connected through an optical cable. Generating a synchronization optical signal by the master node, multiplexing the synchronization optical signal and the data optical signal, and transmitting the first optical signal;
A relay node receives the first multiplexed optical signal to perform a first demultiplexing, distributes the separated optical signal separated through the first demultiplexing to a plurality of synchronous optical signals, step; And
A slave node receiving and demultiplexing the second multiplexed optical signal and extracting a synchronization signal in the form of an electric signal from the separated synchronization optical signal through the second demultiplexing;
To-node time synchronization. 7. The method of claim 6, wherein the generating the synchronization optical signal comprises:
Generating a synchronization light signal;
Distributing the generated synchronization optical signal to a plurality of synchronization optical signals; And
Multiplexing each of the split synchronous optical signals with each data optical signal and transmitting the first multiplexed optical signal;
To-node time synchronization. 8. The method of claim 7,
Wherein each of the distributed synchronous optical signals has the same characteristics and has an optical intensity according to a distribution ratio. 7. The method of claim 6, wherein the synchronizing optical signal distribution step
The relay node receiving the first multiplexed optical signal from an upper node;
Demultiplexing the first multiplexed optical signal into a data optical signal and a synchronous optical signal;
Dividing the separated synchronous optical signal into a plurality of synchronous optical signals;
Processing the separated data optical signal; And
Multiplexing each of the distributed synchronous optical signals with each data optical signal processed and transmitting the second multiplexed optical signals;
To-node time synchronization. 10. The method of claim 9,
Wherein each of the distributed synchronous optical signals has the same characteristics and has an optical intensity according to a distribution ratio. 7. The method of claim 6,
Each slave node receiving the second multiplexed optical signal from an upper node;
Demultiplexing the second multiplexed optical signal into a second optical signal and a second optical signal; And
Extracting a synchronizing signal in the form of an electric signal by photoelectrically converting the separated synchronizing optical signal;
To-node time synchronization. Generating a synchronization optical signal by the master node, multiplexing the synchronization optical signal and the data optical signal, and transmitting the first optical signal;
The relay node receives the first multiplexed optical signal to perform first demultiplexing, and performs photoelectric conversion and electro-optical conversion on the separated synchronized optical signal through the first demultiplexing, and then multiplexes the plurality of electro- A synchronization optical signal distribution step of transmitting the synchronization optical signal; And
A slave node receiving and demultiplexing the second multiplexed optical signal and extracting a synchronization signal in the form of an electric signal from the separated synchronization optical signal through the second demultiplexing;
To-node time synchronization. 13. The method of claim 12, wherein the generating the synchronization optical signal comprises:
Generating a synchronization light signal;
Distributing the generated synchronization optical signal to a plurality of synchronization optical signals; And
Multiplexing each of the divided optical signals with the first multiplexed optical data signal;
To-node time synchronization. 14. The method of claim 13,
Wherein each of the distributed synchronous optical signals has the same characteristics and has an optical intensity according to a distribution ratio. 13. The method of claim 12, wherein the synchronizing optical signal distribution step
The relay node receiving the first multiplexed optical signal from an upper node;
Demultiplexing the first multiplexed optical signal into a first optical signal and a second optical signal;
Converting the separated synchronous optical signal into electrical signals, converting the electrical signals into electrical signals,
Processing the separated data optical signal; And
Multiplexing each of the synchronous optical signals converted by the all-optical conversion into the data optical signals processed by the data multiplexing and transmitting the second multiplexed optical signals;
To-node time synchronization. 16. The method of claim 15, wherein the second multiplexing and transmitting comprises:
Dividing one synchronizing signal into a plurality of synchronizing optical signals; And
Multiplexing each of the distributed synchronous optical signals with the data-processed data optical signals, and transmitting the second multiplexed optical signals;
To-node time synchronization. 13. The method of claim 12, wherein the synchronizing optical signal processing step
Each slave node receiving the second multiplexed optical signal from an upper node;
Demultiplexing the second multiplexed optical signal into a second optical signal and a second optical signal; And
Extracting a synchronizing signal in the form of an electric signal by photoelectrically converting the separated synchronizing optical signal;
To-node time synchronization. An apparatus for time synchronization between nodes in a network composed of a plurality of nodes,
A synchronization optical signal generator for generating a synchronization optical signal and multiplexing the synchronization optical signal and the data optical signal;
A synchronous optical signal distributor for demultiplexing the multiplexed optical signal from the synchronous optical signal generator, demultiplexing the separated optical signal into a plurality of synchronous optical signals, and multiplexing the multiplexed optical signals; And
A synchronous optical signal processing unit for demultiplexing the multiplexed optical signal from the synchronous optical signal distributor and extracting a synchronous signal in the form of an electric signal from the separated synchronous optical signal through demultiplexing;
To-node time synchronization device. 19. The apparatus of claim 18, wherein the synchronization optical signal generator
A synchronization optical signal generator for generating a synchronization optical signal;
A light splitting unit for splitting a synchronization light signal generated by the synchronization light signal generator into a plurality of synchronization light signals; And
At least one multiplexer for multiplexing each of the synchronous optical signals distributed by the optical distributor with each data optical signal and transmitting the multiplexed optical signal;
To-node time synchronization device. 19. The apparatus as claimed in claim 18, wherein the synchronization optical signal distributing unit
A multiplexer for receiving an optical signal multiplexed from an upper node and demultiplexing the multiplexed optical signal into a data optical signal and a synchronous optical signal;
A multiplexer for multiplexing the synchronous optical signal separated by the multiplexer into a plurality of synchronous optical signals;
At least one multiplexer for multiplexing each synchronous optical signal distributed from the optical distributor with each data optical signal processed and transmitting the data;
To-node time synchronization device. 19. The apparatus of claim 18, wherein the synchronization optical signal processor
A multiplexer for receiving an optical signal multiplexed from an upper node and demultiplexing the multiplexed optical signal into a data optical signal and a synchronous optical signal; And
A photoelectric conversion unit for photoelectrically converting the synchronizing optical signal separated by the multiplexer and extracting a synchronizing signal in the form of an electric signal;
To-node time synchronization device. An apparatus for time synchronization between nodes in a network composed of a plurality of nodes,
A synchronization optical signal generator for generating a synchronization optical signal and multiplexing the synchronization optical signal and the data optical signal;
A synchronous optical signal distributor for demultiplexing the multiplexed optical signal from the synchronous optical signal generator and for multiplexing the plurality of synchronous optical signals converted after electrooptical conversion and electrooptic conversion of the synchronous optical signal separated through demultiplexing; And
A synchronous optical signal processing unit for demultiplexing the multiplexed optical signal from the synchronous optical signal distributor and extracting a synchronous signal in the form of an electric signal from the separated synchronous optical signal through demultiplexing;
To-node time synchronization device. 23. The apparatus of claim 22, wherein the synchronization optical signal generator
A synchronization optical signal generator for generating a synchronization optical signal;
A light splitting unit for splitting a synchronization light signal generated by the synchronization light signal generator into a plurality of synchronization light signals; And
At least one multiplexer for multiplexing each of the synchronous optical signals distributed by the optical distributor with each data optical signal and transmitting the multiplexed optical signal;
To-node time synchronization device. 23. The apparatus of claim 22, wherein the synchronizing optical signal distributor comprises:
A multiplexer for receiving an optical signal multiplexed from an upper node and demultiplexing the multiplexed optical signal into a data optical signal and a synchronous optical signal;
A photoelectric conversion unit for photoelectrically converting the synchronizing optical signal separated by the multiplexer and converting the synchronizing optical signal into an electrical signal;
An all-optical converter for converting the electric signal converted by the photoelectric converter into a plurality of synchronous optical signals; And
At least one multiplexer for multiplexing each of the synchronous optical signals converted in the electro-optical conversion unit by the data-processed data optical signals and transmitting the multiplexed optical signals;
To-node time synchronization device. 23. The apparatus of claim 22, wherein the synchronization optical signal processing unit
A multiplexer for receiving an optical signal multiplexed from an upper node and demultiplexing the multiplexed optical signal into a data optical signal and a synchronous optical signal; And
A photoelectric conversion unit for photoelectrically converting the synchronizing optical signal separated by the multiplexer and extracting a synchronizing signal in the form of an electric signal;
To-node time synchronization device.

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