KR101066552B1 - Automatic supply system and automatic supply method of spare power for optical coaxial mixed network - Google Patents

Abstract

The present invention relates to an automatic supply system and an automatic supply method of a preliminary power supply for an optical coaxial mixed network. It is configured to control the power supply state through the automatic power changer, and to automatically supply power to the main line through the preliminary power automatic changer while installing one preliminary power supply in the contact portion of the plurality of main lines, If the power supply of the main line fails while monitoring the status and operation status of the automatic power changer installed in the main line of the optical coaxial mixed network through the network management server, the backup power supply By supplying the backup power to the main line in which the above fault occurs, one by one main line It makes it possible to reduce installation costs and maintenance costs compared to installing a redundant power supply line, respectively.

Description

Automatic Supply System and Method of Reserve Power For The Hybrid Fiber Coax Network}

The present invention relates to an automatic supply system and an automatic supply method of a preliminary power source for a hybrid fiber coax network (HFCN), and more particularly, an automatic power installed in a main line of an optical coaxial hybrid network (HFC Network). If the power supply of the corresponding main line fails while monitoring the status value and operation status of the APS through the network management server, the backup power supply connected to the main line The automatic power supply system of the optical power supply system for the optical coaxial mixed network, which saves the installation cost and the maintenance cost compared to installing one backup power supply line in each main line by supplying the backup power supply to the main line in which the above fault occurs. It relates to an automatic feeding method.

In general, an optical coaxial mixed network or HFCN is a type of access network configuration, and refers to a network in which a main trunk portion of a coaxial CATV transmission network is improved with an optical cable. This is a configuration method using a fiber optic cable from a CATV broadcasting station to an optical network unit (ONU) and a coaxial cable from the ONU to the subscriber terminal.

FIG. 1 schematically shows the overall configuration for power supply of a conventional optical coaxial mixing network, one of a plurality of main lines 100 and 105 for transmitting a broadcast signal to an area allocated in the optical coaxial mixing network. While installing the power supply (101) 106 to control the supply state of the power through the automatic power switch 102 (107), one each of the first and second main line (100, 105) It is configured to automatically supply power to the first or second main line (100, 105) through the preliminary power automatic switch (104, 109) while installing the reserve power supply (103) (108).

In the conventional optical coaxial mixed network, as shown in FIG. 2, each of the ONUs (optical network units) 112 connected to the CATV broadcasting station 110 by an optical cable or optical paths 111a and 111b. 122, a plurality of subscriber stations are connected via coaxial cables 111b, 111c, 111d, 121b, 121c and 121d via amplifiers 113, 114, 123 and 124. Each ONU 112, 122 is connected to a power supply 115, 125 such as, for example, a UPS. In the power supply device 115, 125, the power is supplied via the power supply lines 117, 127 via the power inserters 116, 126, and the coaxial cables 111b, 111c, 111d, 121b ( 121c) and 121d. The power inserters 116 and 126 insert power on the coaxial cable through which the RF signal flows, and at the same time, prevent the RF signal on the coaxial cable from flowing toward the power line. In this optical coaxial mixed network, subscriber traffic management and network expansion are all centered on the ONU, and thus, in the present specification, a power supply device connected to one ONU and an accessory device such as an amplifier and a connection line are included. The unit is referred to as a 'cell'. In the following description, there is no limitation except that an ONU is essentially included in one cell. In the optical coaxial mixed network, the ONU is a device for converting an optical signal into a radio frequency (RF) signal, and each ONU is connected to a power supply (PS) for supplying power. In order to improve the stability of power supply among PS, the power supply with built-in battery is called Uninterrupted Power Supply (UPS). It usually receives AC 200V and outputs AC 90V. In general, in the optical coaxial mixed network widely used in the CATV field, power supplied to all devices in the network is transmitted through a coaxial cable line connected from the ONU to the subscriber station. The power supply problem is very important for the reliability of the network because there may be a loss of information transmission through the optical coaxial mixed network if the power supply is interrupted due to a failure in the power supply. Therefore, it is generally stable to use a UPS that can be powered by a built-in battery when there is no phase change. However, while the UPS's built-in battery typically lasts about two hours, the recovery time of the phase transformer for power supply often takes longer than the UPS's battery maintenance time. It could not be prevented from occurring. Therefore, if the power supply to the network of a specific area fails in the optical coaxial mixed network, the power supply can be resumed immediately, and moreover, the power supply can be stably supplied for a sufficient time to recover the power supply in the failed area. There is an urgent need for new technologies that can improve the stability of transmission network power supplies. In addition, since one preliminary power supply 103 (108) and a reserve power automatic switcher (104, 109) must be installed in one main line (100) (105), the installation cost is excessively spent, as well as maintaining, In addition to the inconvenience to manage, there was a disadvantage such as unnecessary power consumption for the supply and monitoring of the reserve power.

The present invention is to improve the problems associated with the stable supply of backup power in the event of a power supply failure in the conventional optical coaxial mixed network described above, the state value and operating state of the automatic power switch installed in the main line of the optical coaxial mixed network If the power supply of one (first) main line or one (second) main line fails during monitoring through the network management server, the reserve power by the reserve power supply connected in common to these main lines is Automatic supply system and automatic supply method of spare power for optical coaxial mixed network, which can reduce installation and maintenance cost compared to installing one backup power supply line in each main line by supplying to main line that has failed. The purpose is to provide.

In order to achieve the above object, an automatic supply system and an automatic supply method of an optical power supply network for optical coaxial mixing networks according to the present invention include one power source for a plurality of main lines for transmitting a broadcast signal to an area allocated from an optical coaxial mixing network of cable broadcasting. While supplying the power supply to control the power supply state through the automatic power switcher, and by supplying a single power supply to the contact portion of the plurality of main lines automatically supply power to the corresponding main line through the reserve power automatic switcher In the optical coaxial mixed network of cable broadcasting, it is basically installed in each main line through the network management server installed inside the headend which mixes and broadcasts the broadcasting signals of each channel to the relay transmission network. To check that the normal power is supplied through a single power supply; Through the failure occurs in the power supply of the first main line and consists of a process of recognizing a state in which the supply of power that is not operating normally.

Subsequently, a control signal is transmitted to the automatic power changer of the corresponding main line to cut off the supply of power, and the network management server confirming a state in which power supply is cut off by the automatic power changer of the corresponding main line. The control signal is transmitted to the automatic power changer of the spare power supply in the process to ensure that the reserve power through the reserve power supply is supplied to the corresponding main line to operate normally, the network management server while the reserve power is supplied. A process of checking whether a failure of the power supply of the main line has been resolved; and if the failure has been resolved, transmitting a control signal from the network management server to the reserve power automatic switcher to cut off the supply of the reserve power; At the moment of confirming that the power supply is cut off, the network management server By including the process of transmitting the control signal to the coin power changer to ensure that the power is normally supplied, not only improves the stability of the power supply during cable broadcasting, but also reduces the installation and maintenance costs of the reserve power supply for supplying the reserve power. It was made to be possible.

According to the present invention having the above-described configuration, by installing a preliminary power supply and an automatic power switch for basically one preliminary power supply to two main lines, installation costs can be reduced, as well as these preliminary power supplies and automatic power This reduces the waste of unnecessary power for the monitoring and operation of the switchboard, and significantly reduces the cost of maintaining and maintaining these devices.

1 is a schematic diagram showing the overall configuration for power supply of a conventional optical coaxial mixing network.
2 is a schematic diagram illustrating a multi-cell configuration of a conventional optical coaxial mixing network.
Figure 3 is a schematic diagram showing a configuration for power supply of the optical coaxial mixing network of the present invention.
Figure 4 is a block diagram showing the internal configuration of the automatic power changer used in the power supply backup system between adjacent cells of the optical coaxial mixed network according to an embodiment of the present invention.
Figure 5 is a block diagram showing the internal configuration of the automatic power supply changer used in the power supply backup system between adjacent cells of the optical coaxial mixed network according to an embodiment of the present invention.
Figure 6 is a schematic diagram showing an example of power supply between adjacent cells of the optical coaxial mixing network according to an embodiment of the present invention.
Figure 7 is a schematic diagram showing an intuitive operation state of the automatic supply method of the pre-power for the optical coaxial mixed network according to an embodiment of the present invention.
Figure 8 is a block diagram showing the internal configuration for measuring the amount of power consumed in the optical coaxial mixed network according to another embodiment of the present invention.
9 is a block diagram showing an internal configuration for measuring the amount of reserve power consumed in an optical coaxial mixed network according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings illustrating the present invention with a specific example as follows.

FIG. 3 is a schematic diagram showing an example of the present system, in which one power supply unit 2 or 6 is installed in a plurality of main lines 1 and 5 for transmitting a broadcast signal in an allocated area in an optical coaxial mixed network. The automatic power switch (4) (7) to control the supply state of the power supply, and the preliminary power automatic transfer while installing one reserve power supply (8) at the contact portion of the main line (1) (5) It is configured to automatically supply power to a plurality of the main line (1) (5) through the machine (9).

Figure 4 is a block diagram showing the internal configuration of an automatic power changer (APC, Automatice Power Changer) (3) (7) used in the automatic power supply system of the optical power coaxial mixed network according to the present invention, It is an automatic switching device that can have a structure and function similar to that disclosed in No. 10-0717512.

In particular, the APC (3) (7) forms a plurality of connector insertion holes (11) (14) on both sides for input and output of power and / or RF signal, the inside of each connector insertion hole (11) (14) Built-in sensors 12 and 15 for determining the presence or absence of power, switches (SW1) 13 for power switching, and monitoring module 16 for additional functions such as power detection, short check, and network monitoring In this way, the power supplied from the power supply 2 (6) through the connector insertion hole 11 is supplied to the main line 1 (5) connected to the connector insertion hole 14.

FIG. 5 is a block diagram showing an internal configuration of a spare power automatic changer used in an automatic supply system of a reserve power supply for an optical coaxial mixed network according to an embodiment of the present invention. And / or a plurality of connector insertion openings 21, 23 and 26 for inputting / outputting RF signals, respectively, in which each connector insertion opening 21, 23 and 26 determines whether power is present. Sensors 22, 24, 27 and switches (SW2), 25 (SW3) and 28 for power switching and monitoring module 29 for power detection, short check and network monitoring In this case, when an abnormality occurs in the power supplied from the power supply (2) (6) to the two main lines (1) (5) through the automatic power switch (3) (7), (1) (5) After confirming whether the switch (SW2) (25) (SW3) 28 of the automatic power changer (9) is connected to the reserve power is supplied through this A.

The automatic supply system of a preliminary power supply for an optical coaxial mixed network provided according to the present invention includes at least two cells, that is, a first cell configured to include an optical network unit (ONU) for connecting an optical path and a coaxial cable. And a hybrid fiber coax network (HFCN) having a second cell, when a power supply of the first cell fails, a power supply of an adjacent second cell that does not fail is connected to the first cell. In this way, stable backup power is supplied until recovery of the first cell.

Referring to FIG. 6, the first cell includes a first optical network termination unit (ONU1) 31, a first power supply device (UPS1) 32, and a first automatic power changer (APC1) 33. The first optical network terminator (ONU1) 31 is connected to, for example, a coaxial cable 37 and 38 from a CATV broadcasting station by an optical cable or an optical line 34 and a subscriber station connected to the amplifiers 35 and 36. Connected, converts the optical signal into an electrical signal.

In addition, the first power supply device (UPS1) 32 is a device for supplying power to the first cell, and is connected to the coaxial cable 38 by a power supply line (39). The first automatic power changer (APC1) 33 may have a configuration as shown in FIG. 4, for example, and is installed on the power supply line 39 to monitor the flow of power and then perform switching on / off operation. It is configured to.

Also, in the first cell, the first power supply (UPS1) 32 is powered via the first power inserter 40 at a predetermined position of the coaxial cable 38 connected to the first optical network termination device (ONU1) 31. To supply. The first automatic power changer (APC1) 33 is installed between the first power supply device 32 and the first power inserter 40 to detect when a failure of the first power supply device UPS1 32 occurs.

In the embodiment according to the present invention, the APC can be used separately for the purpose of monitoring and power switching function and the purpose of power supply insertion.

Hereinafter, when the APC is used for the purpose of monitoring and power switching functions, it is referred to as an 'automatic power switch', and when used as a power insertion, it is referred to as a 'power inserter'. Of course, those skilled in the art will readily understand that the components of the structure shown in FIG. 4 are just one example, and any circuit configuration may be provided if the structure satisfies the functions.

The second cell also includes a second optical network termination unit (ONU2) 41, a second power supply (UPS2) 42, and a second automatic power switch (APC2) 43 similarly to the first cell. The second optical network terminator (ONU2) 41 is connected, for example, by a coaxial cable 47 and 48 to a subscriber terminal connected to an optical cable or an optical path 44 from a CATV broadcasting station and connected to the amplifiers 45 and 46. To convert an optical signal into an electrical signal.

In addition, the second power supply device (UPS2) 42 is a device for supplying power to the second cell, and is connected to the coaxial cable 47 by the power supply line 49. The second automatic power changer (APC2) 43 may have a configuration as shown in FIG. 4, for example, and is installed on the power supply line 17 to monitor the flow of power and then switch on / off operation. It is configured to be. In the second cell, the second power supply (UPS2) 42 supplies power via the second power inserter 50 at a predetermined position of the coaxial cable 47 connected to the second optical network termination unit (ONU2) 41. Supply.

In addition, the second automatic power switch (APC2) 43 is installed between the second power supply 42 and the second power inserter 50 to detect when a failure of the second power supply UPS2 42 occurs. In this case, the first cell and the second cell are characteristically connected to each other via a third automatic power switch APC3 51, unlike the conventional network configuration shown in FIG. 2.

In addition, the third power inserter 52 installed at a predetermined position on the coaxial cable 38 of the first cell and the fourth power inserter 53 provided at a predetermined position on the coaxial cable 47 of the second cell are automatically operated. It is configured in such a way that is connected to each other via a power switch 51.

This connection constitutes an important feature of the invention, which allows backup power to be supplied from adjacent cells in the event of a failure. The operation for supplying backup power can be performed by the monitoring and switching functions of the three APC1 33, APC2 43, and APC3 51 mentioned above, and their operation is performed by the network management of the remote headend center. It can be integrated under the control of the server.

This central headend center can be connected to three APC1 33, APC2 43, APC3 51 by wired communication lines of, for example, FSK (300 KHz band) or CM (6 MHz band). . These communication methods enable the central headend center to check the status of the three APC1 33, APC2 43, and APC3 51 (i.e., switch on or switch off), and switch on / off operation. To control. In particular, the central head-end center receives a signal indicating whether a failure is detected from the first and second automatic power changers 33 and 43 that monitor power failure of each cell, and a failure occurs for the failed cell. The operation of the third automatic power changer 51 may be controlled to supply the power of the neighboring cells which have not been provided as the backup power.

Here, the first, second, third and fourth power inserters 40, 50, 52, and 53 have a radio frequency (RF) signal except for a power signal flowing through the coaxial cables 38 and 47. The first, second, and third automatic power supply switching devices APC1 33, APC2 43, and APC3 51 are prevented from flowing to the structure.

Specifically, when the first and second automatic power changers APC1 33 and APC2 43 which monitor the presence or absence of power of each cell are normally in a switched-on state, and the connected power supply devices 32 and 42 have a failure, It automatically switches off and simultaneously transmits a failure detection signal to the headend center, and operates to restore the switching on state according to the failure recovery control signal of the headend center.

On the other hand, the third automatic power changer APC3 51 for supplying backup power is normally switched off and then switched on according to the fault backup control signal transmitted from the headend center, Operate to recover to a switched off state according to a failover confirmation control signal.

The example shown in the drawings attached to this specification shows a network having two cells for simplicity of explanation, but this is merely an example, and the number of cells in the network to which the present invention is applied is not necessarily limited to two. It will be readily understood by those skilled in the art that no configuration is possible with no more cells connected.

According to the present invention, the central headend center can monitor the power status of the cells of the entire network through the AMS dedicated NMS system. If the power supply of a particular cell fails due to any cause, the power failure can be blocked at the source by automatically switching the power of the cell to the power supply of the adjacent cell.

7 is a flowchart illustrating a method for automatically supplying a preliminary power supply for an optical coaxial mixed network according to the present system. In the optical coaxial mixed network of cable broadcasting, a headend that mixes and broadcasts broadcast signals of each channel to a relay transmission network. Through the network management server installed in the headend, it is checked whether the normal power is supplied through the power supply 2 or 6 installed in each main line 1 or 5 (step 61).

Through the network management server, it is recognized that the power supply 2 of one main line 1 or the power supply 6 of the other main line 5 has failed and the power supply is not normally performed. On the other hand (process 62), the control signal is transmitted to the automatic power changer (3) (7) of the corresponding main line (1) (5) to cut off the supply of power (process 63).

When the network management server confirms that the supply of the power is cut off by the automatic power switch (3) (7) of the corresponding main line (1) (5) (step 64), the backup power supply 8 The control signal is transmitted to the standby power automatic switch 9 so that the backup power through the spare power supply 8 is connected to the main line 1 of one (first) or the main line 5 of the other (second). Supply it to ensure normal operation (procedure 65).

When the standby power is supplied, the network management server confirms that the failure of the power supply 2 of one main line 1 or the power supply 6 of the other main line 5 is resolved (process). 66), the network management server outputs a control signal to the reserve power automatic changer 9 so that the supply of the reserve power is cut off (step 67).

At the moment when the network management server confirms that the supply of the reserve power has been cut off (step 68), the automatic power changer 3 of the main line 1 of one side (first) or the other side of the network management server (second) The control signal is transmitted to the automatic power changer 7 of the main line 5) so that power is normally supplied (step 69).

FIG. 8 illustrates an internal configuration of an automatic power changer (APC) 71 for measuring an amount of power consumed in an optical coaxial mixed network according to another embodiment of the present invention. ) Forms a plurality of connector insertion openings 72 and 78 on both sides for input and output of power and / or RF signals, and therein, it is possible to determine the presence or absence of the power supply at each connector insertion opening 72 and 78 therein. The switch 74 and the sensor (73) and the switch (SW4) 74 for power switching and the monitoring module 75 for additional functions of power detection, short check, and network monitoring. By installing and configuring a digital power meter 79 for metering the amount of power consumed between 77, the power supplied from the power supply 2, 6 through the connector insert 11 is connected to the connector insert 14 The amount of power consumed while supplying the main line (1) (5) It is to be transmitted by the power line communication method (general communication method to send a digital signal to the power line) to the center.

9 is a diagram illustrating an internal configuration of a spare power automatic changer 81 for measuring the amount of reserve power consumed in an optical coaxial mixed network according to another embodiment of the present invention. And / or a plurality of connector insertion holes 82, 86, 89 for inputting / outputting RF signals, respectively, and therein, at each connector insertion hole 82, 86, 89, to determine whether power is present. Sensors 83, 85, 88 and switches (SW5), 84 (SW6), 87 for power switching and monitoring module 90 for power detection, short check, and network monitoring While installing the digital power meter 91 for reading the amount of power consumed between the switches (SW5) 84 (SW6) 87 and the sensor 83, it is shown in Figure 8 from the power supply If an error occurs in the power supplied to the two main lines through the automatic power switch 71, after checking which main line When one of the switches SW5, 84, SW6, 87 of the standby power automatic machine 81 is connected, the amount of spare power consumed while the standby power is supplied is also read and a power line communication method is performed to the headend center. General communication method that sends a signal on a power line).

Although the present invention has been described through specific embodiments, various modifications are possible to those skilled in the art by referring to and combining various features described herein. Therefore, it should be pointed out that the scope of the present invention should not be limited to the described embodiments, but should be interpreted by the appended claims.

1 is a schematic diagram showing the overall configuration for power supply of a conventional optical coaxial mixing network.
2 is a schematic diagram illustrating a multi-cell configuration of a conventional optical coaxial mixing network.
Figure 3 is a schematic diagram showing a configuration for power supply of the optical coaxial mixing network of the present invention.
Figure 4 is a block diagram showing the internal configuration of the automatic power changer used in the power supply backup system between adjacent cells of the optical coaxial mixed network according to an embodiment of the present invention.
Figure 5 is a block diagram showing the internal configuration of the automatic power supply changer used in the power supply backup system between adjacent cells of the optical coaxial mixed network according to an embodiment of the present invention.
Figure 6 is a schematic diagram showing an example of power supply between adjacent cells of the optical coaxial mixing network according to an embodiment of the present invention.
Figure 7 is a schematic diagram showing an intuitive operation state of the automatic supply method of the reserve power for the optical coaxial mixed network according to an embodiment of the present invention.
Figure 8 is a block diagram showing the internal configuration for measuring the amount of power consumed in the optical coaxial mixed network according to another embodiment of the present invention.
9 is a block diagram showing an internal configuration for measuring the amount of reserve power consumed in an optical coaxial mixed network according to another embodiment of the present invention.

Claims (6)

Through the automatic power switch (3) (7), one power supply (2) (6) is installed in a plurality of main lines (1) and (5) for transmitting a broadcast signal in the allocated area in the optical coaxial mixed network. To control the power supply,
Automatically supply power to the main line (1) (5) through the preliminary power automatic transfer machine (9) while installing one reserve power supply (8) at the contact points of the plurality of main lines (1) (5). An automatic supply system for a reserve power supply for a coaxial mixed network, characterized in that configured to supply. The method according to claim 1,
The automatic power changer (3) (7) forms a plurality of connector insertion openings (72) (78) on both sides for input / output of power and / or RF signals, and each connector insertion opening (72) therein. While there are built-in sensors 73 and 77 for determining the presence or absence of power at 78, a switch 74 for switching power, and a monitoring module 75 for additional functions of power detection, short check, and network monitoring. And a digital power meter (79) for metering the amount of power consumed between the switch (74) and the sensor (77). The method according to claim 1,
The preliminary power automatic changer 9 forms a plurality of connector insertion holes 82, 86, 89 for input / output of power and / or RF signals, respectively, and each connector insertion hole 82 ( Sensors 83, 85 and 88 capable of determining the presence or absence of power at 86 and 89, switches 84 and 87 for power switching, and monitoring for the functions of power detection, short check and network monitoring A preliminary power source for a coaxial mixed network, comprising a module 90 having a digital power meter 91 installed to read an amount of power consumed between the switches 84 and 87 and the sensor 83. Automatic feeding system. Hybrid Fiber Coax Network (HFCN) comprising at least two cells, namely a first cell and a second cell, including one optical network unit (ONU) for connecting an optical path and a coaxial cable ),
The first cell is configured to supply power via the first power inserter 40 at a predetermined position of the coaxial cable 38 connected to the first optical network terminator 31 and the first optical network terminator 31. A first automatic power changer installed between the first power supply device 33 and the first power supply device 32 and the first power inserter 40 to detect a failure of the first power supply device 15 ( 33);
The second cell is configured to supply power via the second power inserter 50 at a predetermined position of the second optical fiber terminator 41 and the coaxial cable 47 connected to the second optical fiber terminator 41. A second automatic power switch installed between the second power supply 42 and the second power supply 42 and the second power inserter 50 to detect when a failure of the second power supply 42 occurs; 43);
The third power inserter 52 installed at a predetermined position on the coaxial cable 38 of the first cell and the fourth power inserter 53 provided at a predetermined position on the coaxial cable 47 of the second cell are provided in a third position. Connected to each other via an automatic power switch 51;
A headend center connected to the first, second and third automatic power changers 33, 43 and 51 by a communication line detects a failure occurrence from the first and second automatic power changers 33 and 43. Receiving a signal indicating whether or not to control the operation of the third automatic power switch 51, automatic supply system for a pre-powered optical coaxial mixed network. The method of claim 4,
The first, second, third, and fourth power inserters 40, 50, 52, and 53 have RF signals excluding power signals flowing through the coaxial cables 38 and 47. The first, second, and third automatic power supply switching system (33) (43) (51) is configured to prevent the flow of the automatic power supply system for the optical coaxial mixed network, characterized in that configured in the structure. Power installed in each main line (1) (5) through the network management server installed inside the headend that plays a role of mixing and broadcasting broadcast signals of each channel in the optical coaxial mixed network of cable broadcasting A process of confirming that normal power is supplied through the supply (2) and (6),
Through the network management server, it is recognized that the power supply 2 of one main line 1 or the power supply 6 of the other main line 5 has failed and the power supply is not normally performed. If so, the process of transmitting the control signal to the automatic power switch (3) (7) of the main line (1) (5) to cut off the supply of power,
When the network management server confirms that the power supply is cut off by the automatic power switch (3) (7) of the main line (1) (5), the automatic power switch of the backup power supply (8) (9) transmitting a control signal so that the preliminary power through the preliminary power supply 8 is supplied to the corresponding main line (1) (5) to operate normally;
When the standby power is supplied and the network management server confirms that the failure of the power supply unit 2 (6) of the main line (1) (5) has been resolved, the automatic power changer of the reserve power in the network management server ( 9) outputting a control signal to cut off the supply of spare power;
At the moment when the network management server confirms that the supply of the reserve power has been cut off, the network management server transmits a control signal to the automatic power changer (3) (7) of the corresponding main line (1) (5) to supply power normally. The automatic supply method of the pre-power for the optical coaxial mixed network, characterized in that by operating to be supplied.

Images