KR101939835B1 - Power distribution system based on ring network and network operation method thereof - Google Patents

Abstract

A ring network based distribution system comprises a mastering communication device; Ring communication devices coupled with the mastering communication device via an optical communication line to form a signal path in the form of multiple rings; And optical splitters installed at each branch point where the ring communication devices are coupled to a signal path in the form of a multiple ring. Each of the optical distributors includes one port and a plurality of other ports, and is directed to emit an optical signal to an arbitrary port of the other port to the port without signal flow between the other ports.
According to this, both the advantages of the PON using the passive element in the communication branch and the advantage of the ring network which is less restricted by the communication loss can be accommodated. In addition, it is possible to realize efficient communication in a distribution section without communication crosstalk without using expensive active communication equipment separately.

Description

TECHNICAL FIELD [0001] The present invention relates to a distribution network based on a ring network and a network operating method thereof. BACKGROUND OF THE INVENTION [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a distribution system and a network operating method thereof, and more particularly, to a ring network-based distribution system and a network operating method thereof.

In general, a passive optical network (PON) is a point-to-multipoint (PTM) network in which a plurality of ONTs share an optical line terminal (OLT) through optical lines.

1 is a view for explaining a conventional PON (Passive Optical Network) topology.

In the PON system, a communication device called an OLT 10 is located at a communication end, and an optical splitter or an optical coupler type optical distributor 20 is located at nodes requiring communication, Branch. An ONT 30 is installed near the branch point so that a plurality of nodes can communicate with each other.

Thus, the plurality of ONTs 30 share the optical line through the optical distributor 20 as a passive element.

The OLT 10 performs time division or frequency division on communication signals in order to prevent crosstalk of communication signals transmitted from the respective ONTs 30. Each of the ONTs 30 communicates with each other in accordance with a control signal of the OLT 10. [

2 is a diagram comparing a conventional PON topology and a PON topology in a power distribution system.

The advantage of the PON method described above is that it is advantageous to maintain the line by using the optical distributor 10 which is a passive element instead of using the active communication equipment in the communication branching part. Especially, when the PON topology is applied to the power distribution system, the passive elements are used instead of the separate equipment for branching in places such as a manhole which is likely to be submerged and where it is difficult for a person to maintain, Thereby eliminating the need for separate maintenance for the branch.

The general PON topology has a point-to-multipoint structure sharing one OLT 10 through an optical splitter 20 branching the optical line, as shown in (a).

In contrast, a power distribution system, particularly a power distribution system using a light-power composite cable, has a configuration in which a power cable is laid long only on one side along a direction from a starting substation to a next substation, . Then, the optical distributor 20 is installed at every intermediate point of the distribution section requiring communication.

In this case, since loss of communication power increases toward the rear end of the optical line, there is a problem that the optical line can not be installed / used any more when the optical line becomes longer than a certain length. Also, when the PON topology is applied to the power distribution system, there is a problem that the OLT 10, which is an expensive active communication device, must be used to control the entire communication.

Korean Patent No. 10-0683246 Korean Patent No. 10-0606419

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art as described above, and its object is to provide a PON capable of accommodating both the advantages of a PON using a passive element in a communication branch and the advantages of a ring network, A ring network based distribution system and a network operating method thereof.

It is another object of the present invention to provide a ring network-based distribution system and a network operating method thereof, which are capable of communicating without communication confusion without using an OLT which is an expensive active communication equipment.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not to be construed as limiting the invention as defined by the appended art. It will be possible.

According to an aspect of the present invention, there is provided a distribution system based on a ring network, the distribution system comprising: a mastering communication device; Ring communication devices coupled with the mastering communication device through an optical communication line to form a multi-ring signal path; And optical distributors installed at each branch point where the ring communication devices are coupled to the signal path of the multiple ring type. Each of the optical splitters includes one port and a plurality of other ports, and is directed to output an optical signal to an arbitrary port of the other port to the port without signal flow between the other ports.
The optical distributor includes first to fourth optical distributors for transmitting a signal flow when communicating in one direction of the ring network, wherein the first optical splitter transmits a signal at a first interface transmission end of the mastering communication apparatus, And a second optical splitter for receiving the signal transmitted to the second interface receiving terminal of the first ring communication apparatus, 1 interface, the signal transmitted from the first interface transmission terminal of the first ring communication apparatus is received by the other port and transmitted through the one port, and the third optical splitter transmits the signal transmitted by the first interface transmission terminal of the first ring communication apparatus to the second port A signal transmitted from one port of the optical distributor is received by the other port and transmitted to the second interface receiving terminal of the second ring communication device through one port, The fourth optical splitter transmits a signal transmitted from the first interface transmission end of the second ring communication apparatus to the second interface transmission end of the second ring communication apparatus when the signal transmitted to the second interface reception end of the second ring communication apparatus is transmitted again through the transmission end of the first interface To the second port of the mastering communication device through one port.

A network operating method of a distribution system according to an aspect of the present invention includes a mastering communication device, ring communication devices coupled with the mastering communication device through an optical communication line to form a multi-ring signal path, Ring communication apparatuses are connected to a signal path of a multiple ring type, the method comprising the steps of: (a) selecting one port and a plurality of other ports included in each of the optical distributors, A step of limiting the signal flow between the other ports and giving directionality so as to enable only a signal flow between one port and the other port; When an optical signal is input to one of the other ports of the optical splitter communicating in one direction, transmitting an optical signal received at the other port to the one port in accordance with the direction imparted by the optical splitter; And outputting the optical signal received at the other port to the one port in accordance with the direction imparted by the optical splitter when the optical signal enters the other port of one of the other ports of the optical splitter communicating in the other direction.

According to another aspect of the present invention, there is provided a network operating method for a distribution system comprising a mastering communication device, ring communication devices coupled to the mastering communication device through an optical communication line to form a multi-ring signal path, Ring communication apparatuses are installed at each branching point to be coupled to the signal path of the multiple ring type and are provided with directivity so as to allow only signal flow between one port and the other port without signal flow between the other ports. The method comprising: receiving a signal transmitted from a first interface transmission end of the mastering communication apparatus to the other port of a first optical splitter; The signal received at the other port of the first optical splitter is transmitted to the second interface receiver of the first ring communication device through the one port; The signal transmitted to the second interface receiving end of the first ring communication apparatus is transmitted through the transmitting end of the first interface; A signal transmitted from a first interface transmission terminal of the first ring communication device is received through a port of the second optical splitter and then transmitted through a port and transmitted to the other port of the third optical splitter; The signal received at the other port of the third optical splitter is transmitted to the second interface receiving end of the second ring communication device through the first port; The signal transmitted to the second interface receiving end of the second ring communication apparatus is transmitted through the transmitting end of the first interface; And the signal transmitted at the first interface transmission end of the second ring communication apparatus is received at the other port of the fourth optical splitter and then transmitted to the second interface receiving end of the mastering communication apparatus through the one port .

According to the power distribution system and the network operating method of the present invention, since a passive element is used for branching the communication line, there is no need for a separate active communication equipment for branching, thereby facilitating maintenance of the line. Therefore, it is possible to apply it to a place such as a manhole which is likely to be submerged, which is hard to maintain by a person, or where power supply is impossible, without any maintenance burden.

Further, it can be solved by combining the ring network with the restriction condition of the communication loss caused by using a plurality of optical distributors.

In addition, it can accommodate both the advantages of a PON that uses passive devices for communication branching and the advantages of a ring network that are less restricted by communication loss.

In addition, it is possible to realize efficient communication in a distribution section without a communication crosstalk without using an OLT, which is an expensive active communication device.

1 is a view for explaining a conventional PON (Passive Optical Network) topology.
2 is a diagram comparing a conventional PON topology and a PON topology in a distribution system.
3 is a diagram illustrating a configuration of a ring network-based distribution system according to an embodiment of the present invention.
4 is a view for explaining the operation of the optical splitter shown in Fig.
5 is a view for explaining a network operating method of a distribution system according to an embodiment of the present invention.

Hereinafter, a ring network-based distribution system and a network operating method according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a diagram illustrating a configuration of a ring network-based distribution system according to an embodiment of the present invention, and FIG. 4 is a view for explaining an operation of the optical distributor shown in FIG.

The distribution system according to an embodiment of the present invention includes a mastering communication device 110 and a plurality of ring communication devices 121 and 122 so that the starting point and the ending point of the connected network are the same, (Ring Topology).

The ring communication devices 121 and 122 are connected (coupled) to the mastering communication device 110 via optical communication lines to form a signal path in the form of multiple rings. At each branch point where each of the ring communication devices 121 and 122 is combined with a signal path of a multiple ring type, optical splitters 131 to 138 (collectively referred to as 130 when no division is required) are provided.

Without a mastering communication device 110, a mastering communication device 110 (not shown) that exchanges data with the ring communication devices 121, 122 on the ring network since one network loop is formed and data communication can not be made ) Must be present.

The nodes connected to the ring network can be extended to different numbers according to the embodiment, and thus the number of the ring communication devices 121 and 122 and the optical distributor 130 can also be changed. Assuming that each of the ring communication devices 121 and 122 has two interfaces A and B and configures the system using a minimum ring communication device, Communication devices 121 and 122: The number of optical distributors 130 will maintain a ratio of 1: 2: 8. Of course, if the number of ring communication devices increases, it is natural that this ratio may be exceeded.

As shown in FIG. 3, the minimum network includes one mastering communication apparatus 110 and two ring communication apparatuses 121 and 122 for preventing communication collision between lower ring communication apparatuses 121 and 122 .

A method of configuring a ring network according to an embodiment will be described below.

Each of the mastering communication device 110 and the ring communication devices 121 and 122 has two interfaces A and B configured to pair the transmitting end TX and the receiving end RX. The first interface A of the first ring communication device 121 is connected to the second interface B of the second ring communication device 122 of the rear stage and the second interface B is connected to the first Ring communication apparatus 121 to form a circular network configuration.

The optical distributor 130 is a passive element for branching the optical line, and includes an optical splitter and an optical coupler.

The optical splitter 130 includes a first port and a plurality of second ports, and transmits signals in both directions opposite to the first direction. The optical splitter 130 splits an optical signal input to the second port into a first port So that it can be exported only through the network.

4 shows the operation of the optical splitter 130 described above.

In one embodiment, if the first port a of the optical splitter 130 is one port, the second port beta and the third port gamma correspond to the other port. Here, it is assumed that the number of the other ports for setting the signal path is two, but the present invention is not limited to this, and the number of the other ports may be expanded according to the embodiment.

When the optical distributor 20, which is common to the ring network, is used, signal communication between the ring communication devices 121 and 122 does not result in communication. Thus, in one embodiment, directional optical distributor 130 is used to force the direction of the signal flow so that communication between the ring communication devices 121, 122 can be made without interference of the communication signal.

In the case of a general optical distributor 20, a signal received from one side is propagated by 0.5 times to the other side, regardless of whether a signal is received from either side.

In comparison, the optical distributor 130 according to an embodiment adjusts a signal-to-noise ratio of a propagated signal to add directionality as shown in (a) and (b).

Accordingly, the signal input from the first port? In one direction is branched into the second port? And the third port? In the opposite direction, and is branched into the second port? Or the third port? The incoming optical signal is summed to the first port alpha but the signal input to the second port beta is transmitted only to the first port alpha and not to the third port alpha. Similarly, a signal input to the third port? Is not transmitted to the second port?, But is transmitted only to the first port?.

In the embodiment of FIG. 3, the first to fourth optical distributors 131, 132, 133 and 134 transmit a signal flow when communicating in one direction of the ring network, and the fifth to eighth optical distributors 135 and 136 , 137 and 138 carry signal flow when communicating in the opposite direction of the ring network.

When communication is performed in one direction of the ring, operations of the first to fourth optical splitters 131 to 134 are sequentially described as follows.

As described above, the optical splitter 130 according to the embodiment includes the first port? As one port, the second port? And the third port? As the other port, The signal flow between the second port and the third port (?,?) Is restricted and the direction is given so that only the signal flow between one side and the other side (? And?, Or?

The first optical splitter 131 receives the signal transmitted from the transmitting end TX of the first interface A of the mastering communication apparatus 110 at the second port β and then transmits the first port α To the second interface (B) receiving terminal (RX) of the first ring communication device (121).

When the signal transmitted to the receiving end RX of the second interface B of the first ring communication device 121 is transmitted again via the transmitting end TX of the first interface A, the second optical splitter 132 And transmits the signal transmitted from the first interface (A) transmission terminal (TX) of the first ring communication device 121 to the second port (beta) and then through the first port (alpha).

The third optical splitter 133 receives the signal transmitted at the first port? Of the second optical splitter 132 at the second port? And transmits the signal at the second port? Via the first port? 122 to the second interface (B) receiving end RX of the second interface (B).

When the signal transmitted to the receiving end RX of the second interface B of the second ring communication device 122 is transmitted again via the transmitting end TX of the first interface A, the fourth optical splitter 134 After receiving the signal transmitted at the first interface (A) transmission end (TX) of the second ring communication device 122 to the mastering communication device 110 via the first port (?), To the second interface (B) receiving terminal (RX).

In the above-described one-directional communication, although it is assumed that the second port? Is used as the other port for receiving the optical signal, the third port? May be used instead of the second port?.

Likewise, when communicating in the opposite direction of the ring, the optical signal is sequentially transmitted along the ring network through the fifth to eighth optical distributors 135 to 138 which are directed.

In this way, when an optical signal is input through one of the other ports, for example, the second port (?) Or the third port (?) Of the other ports included in the optical distributors 131 to 134 provided for one- The optical distributors 131 to 134 exclusively transmit the optical signal received through the corresponding port (? Or?) Through the first port (?), Which is one port, according to the given directionality.

Also, in the case of the opposite direction communication, when an optical signal is input through the other port, for example, the second port? Or the third port? Of one of the other ports of the optical distributors 135 to 138, The distributors 135 to 138 exports the optical signal received through the port (? Or?) Only through the first port (?) As one port according to the given directionality.

FIG. 5 is a view for explaining a network operating method of a distribution system according to an embodiment of the present invention, and is a network in which the FIG. 3 is laid out in a line.

As described above, the optical splitter 130 includes one port and a plurality of other ports, and is provided with a directivity so as to allow only a signal flow between one port and the other port without signal flow between the other ports.

Specifically, the optical splitter 130 according to an embodiment divides an optical signal input to the first port? In one direction into a second port? And a third port? In the opposite direction, (?) Of the first port (?) And the third port (?) Of the first port (?) Of the first port (a).

Therefore, when the optical signal enters the second port beta, the optical splitter 130 of the ring network transmits the received optical signal to the first port alpha in the other direction except for the third port gamma in the same direction. . Similarly, the optical signal entering the third port? Is transmitted only to the first port? In the other direction except for the second port? In the same direction.

Referring to FIG. 5, a signal flow in the case of communication in one direction of the ring will be sequentially described as follows.

A signal is first output from the first interface A of the mastering communication device 110 and a signal transmitted from the first interface A is transmitted through the first optical splitter 131, Lt; / RTI > that is the other port of the second port.

The signal received at the second port (?) Of the first optical splitter 131 is then transmitted to the receiving end RX of the second interface (B) of the first ring communication device 121 via the first port? And the signal transmitted to the second interface receiving end RX of the first ring communication device 121 is transmitted through the transmitting end TX of the first interface A. [

The signal transmitted from the first interface (A) transmission terminal (TX) of the first ring communication device 121 is then received by the second port (?) Of the second optical splitter 132 and then transmitted to the first port And is transmitted to the second port (?) Of the third optical splitter 133.

The signal received at the second port (?) Of the third optical splitter 133 is then transmitted to the second interface (B) receiving end RX of the second ring communication device 122 via the first port? And the signal transmitted to the receiving end RX of the second interface B of the second ring communication device 122 is transmitted again via the transmitting end TX of the first interface A. [

The signal transmitted at the first interface (A) transmission end (TX) of the second ring communication device 122 is then received at the second port (?) Of the fourth optical splitter 134, To the receiving end RX of the second interface (B) of the mastering communication device 110. [

In the configuration and signal flow of the first to fourth optical splitters 131 to 134, if the directionality is maintained, the positions of the second port? And the third port? In the same direction may be changed. That is, a signal input to the second port? Or the third port? Can be output only through the first port?, And the signal output from the first port? The third port γ may be used instead of the third port γ in the case where the direction of the optical splitter 130 is provided so as to be output through both of the three ports γ, The second port? May be used instead of the second port?. In this case, a signal flow from the second port? To the third port? Or a signal flow from the third port? To the second port? Is of course impossible.

As a result, all signals are transmitted along the ring network without communication crosstalk, and signal transmission from the transmitting end (TX) of the second interface B of the mastering communication device 110, The same principle is applied to the fifth to eighth optical distributors 135 to 138. [

As described above, since the installation area of the power cable is wide and the power cable is installed long on one side as described above, it is necessary to use a plurality of optical distributors in the PON configuration, and communication loss is inevitable. In addition, due to the characteristics of the distribution system, a network is often constructed including a place where the installation and maintenance of communication equipment such as a manhole is not easy.

Thus, in one embodiment, a ring network that is less restricted by communication loss is configured, using an optical distributor as a passive element in the communication branch, eliminating the need for active communication equipment and facilitating network maintenance. In addition, the optical distributor is given directionality to minimize communication loss at the point where the signal is branched.

Particularly, in the optical-power complex distribution system, which can monitor the state variables (conductor temperature, allowable current, installation environment variables, etc.) of the power cable by composing the optical cable in the power cable of the distribution section, Or weaker signal strength can be a bigger problem. Therefore, it is possible to expect a more meaningful effect in terms of system efficiency and minimization of error by applying the principle of combining PON and ring network, using optical passive optical divider, and directing direction of optical distributor.

The configuration of the ring network-based distribution system and the network operating method thereof according to the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

110: mastering communication device
121, 122: ring communication device
130: optical distributor

Claims (5)

In a ring network-based distribution system,
A mastering communication device;
Ring communication devices coupled with the mastering communication device through an optical communication line to form a multi-ring signal path; And
An optical distributor provided at each branch point at which the ring communication devices are coupled to the signal path of the multiple ring type,
Each of the optical splitters includes one port and a plurality of other ports and is directed to emit an optical signal to an arbitrary port of the other port to the port without signal flow between the other ports,
Wherein the optical distributors include first through fourth optical distributors for transmitting a signal flow when communicating in one direction of the ring network,
The first optical splitter receives a signal transmitted from the first interface transmission terminal of the mastering communication apparatus to the other port and then transmits the signal to the second interface receiving terminal of the first ring communication apparatus through the one port,
When the signal transmitted to the second interface receiving end of the first ring communication apparatus is transmitted again through the transmitting end of the first interface, the second optical splitter transmits the signal transmitted from the first interface transmitting end of the first ring communication apparatus To the other port, and then transmits through one port,
The third optical splitter receives a signal transmitted from one port of the second optical splitter to the other port and transmits the signal to the second interface receiver of the second ring communication device through the one port,
Wherein when the signal transmitted to the second interface receiving end of the second ring communication apparatus is transmitted again through the transmitting end of the first interface, the fourth optical splitter transmits the signal transmitted from the first interface transmitting end of the second ring communication apparatus To the second port of the mastering communication device through one port.
The method according to claim 1,
Wherein each of the mastering communication device and the ring communication devices comprises:
A first interface and a second interface configured to couple the transmitting end to the receiving end.
delete delete A master communication device, a ring communication device coupled to the mastering communication device via an optical communication line to form a signal path in the form of a multiple ring, and a plurality of ring communication devices coupled to the multi- A network operating method of a distribution system, comprising: an optical distributor provided at a branch point and provided with a direction so as to enable only a signal flow between one port and the other port without signal flow between the other ports,
Receiving a signal transmitted from a first interface transmission end of the mastering communication apparatus to the other port of the first optical splitter;
The signal received at the other port of the first optical splitter is transmitted to the second interface receiver of the first ring communication device through the one port;
The signal transmitted to the second interface receiving end of the first ring communication apparatus is transmitted through the transmitting end of the first interface;
A signal transmitted from a first interface transmission terminal of the first ring communication device is received through a port of the second optical splitter and then transmitted through a port and transmitted to the other port of the third optical splitter;
The signal received at the other port of the third optical splitter is transmitted to the second interface receiving terminal of the second ring communication device through the one port;
The signal transmitted to the second interface receiving end of the second ring communication apparatus is transmitted through the transmitting end of the first interface; And
Wherein the signal transmitted at the first interface transmission end of the second ring communication device is received at the other port of the fourth optical splitter and then transmitted to the second interface receiving end of the mastering communication device via the one port, A method for network operation of a system.

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