KR20180067889A - Network managing system and vehicle remote control method using the same - Google Patents

Abstract

According to a disclosed embodiment of the present invention, provided are a network management system capable of transmitting a remote control signal to a vehicle through an ad-hoc network by relaying communication between clusters using a unmanned mobile vehicle when a node relaying communication between clusters of an ad-hoc network is lost or the number of nodes is insufficient, and to a remote control method of a vehicle using the same. The network management system comprises: a first cluster including a first node for storing location information and network connection state information of each node configuring an ad-hoc network; a second cluster configuring the node of the ad-hoc network, and including a vehicle having a low power communication module for receiving a remote control signal for the vehicle through the ad-hoc network; a second node for relaying communication between the first and second clusters; a server for receiving a remote control signal transmitted from a user terminal, and transmitting the remote control signal to the vehicle through the ad-hoc network including the first cluster, the second node, and the second cluster; and an unmanned mobile device for configuring the node of the ad-hoc network by moving to a location at which communication between the first and second clusters can be relayed, when the second node is lost or the number of the second nodes is less than or equal to a predetermined reference number.

Description

[0001] The present invention relates to a network management system and a vehicle remote control method using the same,

The disclosed embodiment relates to a network management system and a remote control method of a vehicle using the same.

Telematics is a term that combines Telecommunication and Informatics and is defined as a next-generation information service for automobiles through the combination of the IT industry and the automobile industry.

Telematics service can provide various services such as traffic and driving information, emergency response information, remote vehicle diagnosis service, and internet by utilizing wireless communication technology and GPS (Global Positioning System) technology.

Remote control technology of vehicles using this telematics technology is developing. However, the telematics terminal of the vehicle must maintain a connection with the mobile communication network in order to receive the remote control signal for the vehicle which can be transmitted at an unspecified time point, which may cause a problem related to the battery of the vehicle.

The disclosed embodiments relate communication between clusters using an unmanned mobile device when a node relaying communication between clusters of an ad hoc network is lost or the number is insufficient and a network capable of transmitting a remote control signal through an ad- Management system and a remote control method of a vehicle using the same.

According to an aspect of the present invention, there is provided a network management system for managing location information and network connection state information of each node constituting an ad hoc network, A first cluster comprising one node; A second cluster comprising a vehicle having a low power communication module for configuring a node of the ad hoc network and receiving a remote control signal for the vehicle via the ad hoc network; A second node for relaying communication between the first cluster and the second cluster; And a server for receiving the remote control signal transmitted from the user terminal and transmitting the remote control signal to the vehicle through the ad hoc network including the first cluster, the second node and the second cluster, Moving to a position capable of relaying communication between the first cluster and the second cluster to move to an unattended node constituting a node of the ad hoc network if the second node is lost or the number of the second nodes is equal to or less than a predetermined reference number, Device.

If the second node is lost or the number of the second nodes is less than or equal to a predetermined reference number, the first node may be located at a position where the unmanned mobile device can relay communication between the first cluster and the second cluster The location information of the second node can be transmitted to the unmanned mobile device or the server.

When the position information of the second node transmitted from the first node or the server is received, the unmanned mobile device repeats the communication between the first cluster and the second cluster based on the position information of the second node You can move to a position where you can.

In addition, the unmanned mobile device may include a low power communication module for transmitting a remote control signal for the vehicle through the ad hoc network to the second cluster.

In addition, the vehicle can turn off the telematics terminal of the vehicle when the remaining amount of the battery reaches a predetermined reference value.

When the remaining amount of the battery reaches a predetermined reference value, the vehicle transmits a message informing the turn-off of the telematics terminal of the vehicle to the server, and upon receipt of the confirmation message of the message reception from the server, Can be turned off.

When the telematics terminal of the vehicle is turned off and the low power communication module receives the remote control signal for the vehicle through the ad hoc network, the vehicle may turn on the telematics terminal, Control can be performed.

Further, the server may transmit the remote control signal to the low power communication module through the ad hoc network upon receiving a message informing the turn-off of the telematics terminal from the vehicle.

When the server receives the message informing the turn-off of the telematics terminal from the vehicle, the server may transmit the confirmation message to the telematics terminal of the vehicle.

Also, the server may transmit the remote control signal to the telematics terminal of the vehicle through the commercialized mobile communication network, if the message notifying the turn-off of the telematics terminal is not received from the vehicle.

According to one aspect of the present invention, there is provided a remote control method for a vehicle including a first cluster including the first node and a vehicle as a node at a first node constituting an ad hoc network Determining whether the second node relaying communication between the second cluster is missing or the number of the second nodes is less than or equal to a predetermined reference number; If the second node is lost or if the number of the second nodes is less than a predetermined reference number, the unmanned mobile device moves to a position capable of relaying communication between the first cluster and the second cluster, ≪ / RTI > Wherein, in the vehicle, when a remote control signal transmitted from a server is received through an ad hoc network including the first cluster, the second node or the unmanned mobile device and the second cluster, the telematics terminal of the vehicle is turned And turning it on.

In addition, when the second node is lost or the number of the second nodes is less than a predetermined reference number, the unmanned mobile device may move to a position where the unmanned mobile device can relay communication between the first cluster and the second cluster. And transmitting location information of the second node from the one node to the unmanned mobile device or the server.

If the second node is lost or the number of second nodes is less than or equal to the predetermined reference number, the unmanned mobile device moves to a position where it can relay communication between the first cluster and the second cluster, Wherein when the unmanned mobile device receives the position information of the second node transmitted from the first node or the server, the first cluster and the second node, based on the position information of the second node, And moving to a location where communications between the clusters can be relayed.

Further, when the remaining amount of the battery in the vehicle reaches a predetermined reference value, the telematics terminal of the vehicle is turned off; Receiving a remote control signal transmitted from a user terminal at a server; And transmitting the remote control signal to the low power communication module of the vehicle via an ad hoc network including the low power communication module of the vehicle as a node at the server.

When the remaining amount of the battery in the vehicle reaches a predetermined reference value, turning off the telematics terminal transmits a message informing the turn-off of the telematics terminal of the vehicle to the server when the remaining amount of the battery reaches a predetermined reference value ; And turning off the telematics terminal upon receiving an acknowledgment message for receipt of the message from the server.

In addition, in the server, transmitting the remote control signal to the low-power communication module of the vehicle through the ad-hoc network including the low-power communication module of the vehicle as a node may include, at the server, turning off the telematics terminal Upon receipt of the message, informing the telematics terminal of the vehicle of the receipt of the message; And transmitting the remote control signal from the server to the low power communication module of the vehicle via the ad hoc network.

The method may further include performing control according to the remote control signal in the vehicle when the telematics terminal of the vehicle is turned on.

According to the means for solving the above-mentioned problems, it is possible to remotely control the vehicle even in a place where a vehicle such as an airport, a vehicle yard, or a port is left for a long time and discharge of the battery can occur.

In addition, it is possible to improve the remote controllable time of the vehicle and to reduce the cost of further introducing the battery.

1 is a diagram showing a configuration of a telematics system.
2 is a view showing an exterior of a vehicle according to an embodiment.
3 is a view showing an interior of a vehicle according to an embodiment.
FIG. 4 and FIG. 5 are conceptual diagrams illustrating a method for remote control of a vehicle in a telematics system according to an embodiment.
6 is a flowchart illustrating a remote control method of a vehicle of a telematics system according to an embodiment.
7 to 9 are conceptual diagrams illustrating a method of remote control of a vehicle in a network management system according to an embodiment.
10 is a flowchart illustrating a remote control method of a vehicle in a network management system according to another embodiment.

The present specification discloses the principles of the present invention and discloses embodiments of the present invention so that those skilled in the art can carry out the present invention without departing from the scope of the present invention. The disclosed embodiments may be implemented in various forms.

Like reference numerals refer to like elements throughout the specification. The present specification does not describe all elements of the embodiments, and redundant description between general contents or embodiments in the technical field of the present invention will be omitted. As used herein, the term " part " may be embodied in software or hardware, and may be embodied as a unit, element, or section, Quot; element " includes a plurality of elements.

Also, when an element is referred to as "comprising ", it means that it can include other elements as well, without departing from the other elements unless specifically stated otherwise.

The singular forms " a " include plural referents unless the context clearly dictates otherwise.

In each step, the identification code is used for convenience of explanation, and the identification code does not describe the order of the steps, and each step may be performed differently from the stated order unless clearly specified in the context. have.

Hereinafter, the working principle and embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a diagram showing a configuration of a telematics system.

As shown in FIG. 1, the telematics system according to the disclosed embodiment includes a telematics terminal 520 provided in the vehicle 100 and a server 600 provided in the telematics center 2.

The telematics terminal 520 according to the disclosed embodiment may be installed in the vehicle 100 and may be provided to communicate with the server 600 via the network. The telematics terminal 520 according to the disclosed embodiment may be installed in the vehicle as described above, or may be implemented in various terminals capable of communicating with the server 600 without being installed in the vehicle. For example, the telematics terminal 520 may be implemented as a computer or a portable terminal capable of accessing the server 600 through a network. Here, the computer includes, for example, a notebook computer, a desktop computer, a laptop PC, a tablet PC, a slate PC, and the like, each of which is equipped with a WEB Browser. (PDS), a Personal Digital Assistant (PDA), an International Mobile Telecommunication (IMT), and a Personal Digital Assistant (PDS) -2000, Code Division Multiple Access (CDMA) -2000, W-CDMA (W-CDMA), WiBro (Wireless Broadband Internet) terminals, smart phones Of wireless communication devices.

The telematics terminal 520 according to the disclosed embodiment may include a communication unit for performing communication with the server 600 as described above, and the communication unit may include one or more components. For example, a wireless communication module, and may further include at least one of a short-range communication module and a wired communication module.

The wireless communication module may be a Wifi module, a wireless broadband module, a GSM (Global System for Mobile Communication), a CDMA (Code Division Multiple Access), a WCDMA (Wideband Code Division Multiple Access), a TDMA (Time Division Multiple Access) , Long Term Evolution (LTE), and the like.

The wireless communication module includes a communication port for connecting the network and a controller of the telematics terminal 520, a transmitter for transmitting a signal for providing a telematics service, and a receiver for receiving a signal related to providing a telematics service Receiver). ≪ / RTI > The wireless communication module may modulate the digital control signal output from the control unit through the wireless communication interface into an analog type wireless signal under the control of the controller, And a signal conversion module capable of demodulating the signal into a signal. The control unit is included in the telematics terminal 520 and includes an algorithm for controlling the operation of the components of the telematics terminal 520, a memory for storing data in a program form, and a processor for performing the above- Can be implemented. At this time, the memory and the processor may be implemented as separate chips, or may be implemented as a single chip. The control unit may be included in the telematics terminal 520 as described above, or may be provided outside the telematics terminal 520 to control the overall configuration of the vehicle.

The short-range communication module uses a wireless communication network, such as a Bluetooth module, an infrared communication module, an RFID (Radio Frequency Identification) communication module, a WLAN (Wireless Local Access Network) communication module, an NFC communication module, and a Zigbee communication module, And may include various short range communication modules for transmitting and receiving.

The wired communication module may be a wired communication module such as a CAN (Controller Area Network) communication module, a local area network (LAN) module, a wide area network (WAN) module, or a value added network A communication module, and various cable communication modules such as a USB (Universal Serial Bus), a HDMI (High Definition Multimedia Interface), and a DVI (Digital Visual Interface).

On the other hand, the telematics terminal 520 receives the GPS signals from at least three GPS satellites 3, and can calculate the current position of the vehicle 100 based on the GPS signals and the map data. In addition, the telematics terminal 520 can transmit the position information on the map of the vehicle 100 to the server 600 while the route from the current position to the destination of the vehicle is set. In addition, the telematics terminal 520 can transmit the vehicle running image captured by the black box or other image capturing apparatus, as well as the vehicle running image stored in the storage unit, to the server 600. As described above, the telematics terminal 520 can transmit various data related to the vehicle to the server 600. [ The storage unit may be a storage unit included in the telematics terminal 520, or may not be included in the telematics terminal 520, but may be a storage unit included in the vehicle. Or an external memory not included in the vehicle. The storage unit may be a nonvolatile memory device such as a cache, a read only memory (ROM), a programmable ROM (PROM), an erasable programmable ROM (EPROM), an electrically erasable programmable ROM (EEPROM) ), A hard disk drive (HDD), and a storage medium such as a CD-ROM. However, the present invention is not limited thereto. The storage unit may be a memory implemented in a chip separate from the processor described above in connection with the processor, and may be implemented as a single chip with the processor.

The server 600 may receive and store various data related to the vehicle, such as a vehicle running image, from the telematics terminal 520 in the vehicle 100, receive signals related to the execution of the specific telematics service, Services may be provided. The server 600 may receive a remote control signal for the vehicle transmitted from the user terminal 400 and may transmit the received remote control signal to the telematics terminal 520 of the target vehicle, Can be achieved.

If the vehicle is in a place where the vehicle can be left for a long time, such as an airport, a parking lot, a port, etc., the remote control of the vehicle has a time limit. In order to remotely control the vehicle, the telematics terminal 520 of the vehicle must maintain a connection to the mobile communication network 410 and the power is continuously supplied to the telematics terminal 520 even after the start- . Generally, in order to prevent the battery 700 of the vehicle from being discharged, the power supplied to the telematics terminal 520 is cut off when a predetermined period of time, for example, 96 hours after the vehicle start is turned off, is cut off. When the power supplied to the telematics terminal 520 is cut off, the remote control of the vehicle or the telematics function can not be used until the start of the vehicle.

In order to solve the above-mentioned problem, the disclosed embodiment receives a remote control signal for a vehicle through an ad hoc network including a low-power communication module n5 as a node after the power supplied to the telematics terminal 520 is shut off And a telematics system. Hereinafter, the embodiments disclosed with reference to Figs. 2 to 6 will be described in detail

FIG. 2 is a view showing an exterior of a vehicle according to an embodiment, and FIG. 3 is a view illustrating an interior of a vehicle according to an embodiment.

2, a vehicle 100 according to an embodiment of the present invention includes a main body 1 forming an outer appearance of a vehicle 100, wheels 51 and 52 for moving the vehicle 100, wheels 51 A door 71 for shielding the inside of the vehicle 100 from the outside, a windshield 30 for providing a driver inside the vehicle 100 with a view toward the front of the vehicle 100, And side mirrors 81 and 82 for providing the driver with a field of view behind the vehicle 100. [

The wheels 51 and 52 include a front wheel 51 provided on the front side of the vehicle 100 and a rear wheel 52 provided on the rear side of the vehicle 100. [

The driving device 80 provides a rotational force to the front wheel 51 or the rear wheel 52 so that the main body 1 moves forward or backward. The driving device 60 may include an engine or a battery 700 that generates combustion power by burning fossil fuel, or a motor that generates power by receiving power from the fuel cell. And includes an inverter for controlling the rotation of the motor when the motor is included.

The door 71 is rotatably provided on the left and right sides of the main body 1 so that the driver can ride inside the vehicle 100 at the time of opening and shields the inside of the vehicle 100 from the outside at the time of closing .

A front glass 30 called windshield glass is provided on the front upper side of the main body 100. The driver inside the vehicle 100 can see the front of the vehicle 100 through the windshield 30. [ The side mirrors 81 and 82 include a left side mirror 81 provided on the left side of the main body 1 and a right side mirror 82 provided on the right side. The driver inside the vehicle 100 can visually confirm the state of the side and rear of the vehicle 100 through the side mirrors 81 and 82. [

In addition, the vehicle 100 may include various sensors for sensing obstacles and the like around the vehicle 100 and helping the driver to recognize the situation around the vehicle 100. In addition, the vehicle 100 may include various sensors capable of sensing driving information of the vehicle, such as the speed of the vehicle. Further, the vehicle may include a sensor for acquiring an image of a surrounding environment of the vehicle including a lane or the like.

3, the vehicle 100 may include a dashboard provided with a gear box 120, a center fascia 130, a steering wheel 140, and a dashboard 150.

The gear box 120 may be provided with a gear lever 121 for shifting the vehicle. In addition, as shown in the figure, the gear box includes a dial control unit (not shown) provided to allow a user to control the functions of the multimedia device including the navigation device 10 and the audio device 133 or the main function of the vehicle 100 111 and an input unit 110 including various buttons. The center fascia 130 may be provided with an air conditioner 132, an audio device 133, a navigation system 10, and the like.

The air conditioner controls the temperature, humidity, air cleanliness, and air flow inside the vehicle 100 to comfortably maintain the interior of the vehicle 100. The air conditioner may include at least one discharge port installed in the center fascia 130 and discharging air. The center fascia 130 may be provided with a button or a dial for controlling the air conditioner or the like. A user such as a driver can control the air conditioner of the vehicle 100 using a button or a dial disposed on the center pacea 130. [ Of course, the air conditioner may be controlled through the buttons of the input unit 110 installed in the gear box 120 or the dial control unit 111.

According to the embodiment, the navigation system 10 may be installed in the center fascia 130. The navigation system 10 may be embedded in the center fascia 130 of the vehicle 100. According to one embodiment, the center fascia 130 may be provided with an input unit for controlling the navigation system 10. According to an embodiment, the input of navigation 10 may be located at a location other than the center fascia 130. For example, the input unit of the navigation system 10 may be formed around the display unit 300 of the navigation system 10. As another example, the input unit of the navigation system 10 may be installed in the gear box 120 or the like.

The steering wheel 140 is a device for adjusting the running direction of the vehicle 100. The steering wheel 140 is connected to the rim 141 gripped by the driver and the steering device of the vehicle 100 and includes a rim 141, And spokes 142 connecting hubs. According to the embodiment, the spokes 142 may be provided with operating devices 142a and 142b for controlling various devices in the vehicle 100, for example, an audio device and the like. In addition, various dashboards 150 may be installed on the dashboard to indicate the traveling speed, engine speed, fuel amount, etc. of the vehicle 100. The dashboard 150 may include a dashboard display 151 that displays vehicle status, information related to vehicle driving, information associated with the operation of the multimedia device, and the like.

The driver can operate the vehicle 100 by operating the various devices provided on the dashboard.

FIG. 4 and FIG. 5 are conceptual diagrams of a vehicle remote control method of a telematics system according to an embodiment, and FIG. 6 is a flowchart illustrating a method of remotely controlling a vehicle of a telematics system according to an embodiment.

4 and 5, there are shown a user terminal 400 that receives a remote control command input from a user and transmits a remote control signal corresponding to the received remote control command to the server 600, A server 600 for transmitting the remote control signal transmitted from the server 600 to the vehicle, and a vehicle for receiving the remote control signal transmitted from the server 600 and performing vehicle control according to the remote control signal.

The user terminal 400 may include any type of handheld based wireless communication device, such as a wireless communication device capable of data communication with the server 600, such as a smart phone. In addition, the user terminal 400 may be provided with an application that provides various functions related to remote control of the vehicle. The user terminal 400 and the server 600 can perform communication using the commercialized wireless network 410. For example, the commercialized wireless network 410 may be a WIFI, a wireless broadband, a GSM (Global System for Mobile Communication), a CDMA (Code Division Multiple Access), a WCDMA (Wideband Code Division Multiple Access) (Time Division Multiple Access), and LTE (Long Term Evolution).

The server 600 can determine a route to transmit the remote control signal to the vehicle depending on whether the user terminal 400 and the communication unit 620 capable of performing communication with the vehicle and the telematics terminal 520 of the vehicle are turned off And may include a control unit 610. The server 600 determines whether to transmit the remote control signal to the telematics terminal 520 or the low power communication module n5 of the vehicle as a node by using the commercial network 410 according to whether the telematics terminal 520 is turned off And may determine whether to transmit the remote control signal to the low power communication module n5 of the vehicle via the ad hoc network Ah.

The vehicle includes a plurality of control devices 540a and 540b that can be controlled according to a remote control signal received by the telematics terminal 520 and a plurality of control devices 540a and 540b that supply power to the telematics terminal 520 A battery 700 and a low power communication module n5 for receiving a remote control signal when the telematics terminal 520 is turned off. Control devices 540a and 540b may receive a remote control signal from telematics terminal 520 and output an electrical signal corresponding to the remote control signal to the vehicle's electronic device. For example, the first control device 540a may be an engine control module, and the engine control module may perform fuel injection control, fuel ratio feedback control, lean burn control, ignition timing control and idling control. Further, the second control device 540b may be a power transmission control module, and the power transmission control module may perform the shift control, the damper clutch control, the pressure control during the friction clutch on / off, and the engine torque control during the shift .

As described above, the telematics terminal 520 can receive power from the battery 700 and maintain the connection to the commercial network 410 for a predetermined time after the startup is turned off.

4, the server 600 may transmit a remote control signal to the telematics terminal 520 through the commercial network 410 when the telematics terminal 520 is powered on and turned on. Upon receiving the remote control signal transmitted from the server 600 through the commercial network 410, the telematics terminal 520 determines a control device associated with the remote control signal to be controlled and outputs a remote control signal to the determined control device So that control according to the remote control signal is performed.

On the other hand, the telematics terminal 520 monitors the remaining amount of the battery 700, and when the remaining amount of the battery 700 becomes less than a predetermined reference value, the power supplied from the battery 700 is cut off and can be turned off. That is, the telematics terminal 520 can be turned off when a predetermined time elapses after the start of the vehicle is turned off, or when the remaining amount of the battery 700 is less than a predetermined reference value.

The telematics terminal 520 transmits a message to stop the communication via the commercial network 410 due to the turning off of the telematics terminal 520 when the remaining amount of the battery 700 becomes less than a predetermined reference value.

When the server 600 receives the message transmitted from the telematics terminal 520, it transmits an acknowledgment message to the telematics terminal 520 that the message has been received. When the confirmation message transmitted from the server 600 is received, the telematics terminal 520 turns off the power supplied from the battery 700 and is turned off.

When the remote control signal is transmitted from the user terminal 400, the server 600 checks whether the message is received from the telematics terminal 520. If the message is received, the server 600 transmits a remote control signal to the commercial network 410 Through the ad hoc network (Ah) including the low power communication module (n5) of the vehicle as a node without transmitting through the ad hoc network (Ah).

The low power communication module n5 of the vehicle may include a low power short distance communication, for example, a Zigbee communication module n5. Since the low power communication module n5 can continuously communicate with the outside while minimizing the consumption of the battery 700, it can receive the remote control signal transmitted from the server 600 even after the telematics terminal 520 is turned off can do.

The low-power communication module n5 of the vehicle can constitute a node of the ad hoc network Ah together with various communication modules in the vicinity capable of short range communication. The server 600 first determines the position of the vehicle that transmitted the turn-off message of the telematics terminal 520 in order to transmit the remote control signal to the vehicle that transmitted the turn-off message of the telematics terminal 520. [ The server 600 determines an infrastructure network that manages the ad hoc network Ah containing the low power communication module n5 of the vehicle as a node based on the determined location of the vehicle and transmits the remote control signal to the determined infrastructure network .

As described above, the remote control signal transmitted from the server 600 is transmitted to the ad hoc network (Ah) through the infrastructure network. As shown in Fig. 5, the remote control signal may be transmitted to the low-power communication module n5 of the target vehicle via a plurality of nodes constituting the ad hoc network Ah.

In the low power communication module n5, when the remote control signal transmitted through the ad hoc network Ah is received, the low power communication module n5 outputs a remote control signal to the telematics terminal and turns on the telematics terminal. When the telematics terminal is turned on, a remote control signal is transmitted to the target control device 540 in accordance with the remote control signal outputted from the low power communication module n5, so that control according to the remote control signal is performed.

As described above, when the remote control signal is received using the low power communication module n5, the possibility of discharging the battery 700 can be lowered, and even in a place where the vehicle can be left unattended for a long time, Remote control can be done for more than 2 years.

With reference to Fig. 6, a remote control method of the vehicle will be described.

6, the telematics terminal 520 transmits a message informing the turn-off of the telematics terminal 520 to the server 600 when the remaining amount of the battery 700 is less than a predetermined reference value 800 ). The server 600 having received the message transmits an acknowledgment message to the telematics terminal 520 indicating that the message has been received 820 and the telematics terminal 520 having received the acknowledgment message is turned off 830.

The telematics terminal 520 monitors the remaining amount of the battery 700 and turns off the power supplied from the battery 700 when the remaining amount of the battery 700 becomes less than a predetermined reference value. The telematics terminal 520 transmits a message to stop the communication via the commercial network 410 due to the turning off of the telematics terminal 520 when the remaining amount of the battery 700 becomes less than a predetermined reference value.

When the server 600 receives the message transmitted from the telematics terminal 520, it transmits an acknowledgment message to the telematics terminal 520 that the message has been received. When the confirmation message transmitted from the server 600 is received, the telematics terminal 520 turns off the power supplied from the battery 700 and is turned off.

When the telematics terminal 520 is turned off and a remote control command is input to the user terminal 400 in operation 840, the user terminal 400 transmits a remote control signal corresponding to the remote control command to the server 600 (850), and the server (600) transmits the remote control signal to the low power communication module (n5) through the ad hoc network (Ah) (860).

When the remote control signal is transmitted from the user terminal 400, the server 600 checks whether the message is received from the telematics terminal 520. If the message is received, the server 600 transmits a remote control signal to the commercial network 410 Through the ad hoc network (Ah) including the low power communication module (n5) of the vehicle as a node without transmitting through the ad hoc network (Ah).

The low power communication module n5 of the vehicle may include a low power short distance communication, for example, a Zigbee communication module. Since the low power communication module n5 can continuously communicate with the outside while minimizing the consumption of the battery 700, it can receive the remote control signal transmitted from the server 600 even after the telematics terminal 520 is turned off can do.

The low-power communication module n5 of the vehicle can constitute a node of the ad hoc network Ah together with various communication modules in the vicinity capable of short range communication. The server 600 first determines the position of the vehicle that transmitted the turn-off message of the telematics terminal 520 in order to transmit the remote control signal to the vehicle that transmitted the turn-off message of the telematics terminal 520. [ The server 600 determines an infrastructure network that manages the ad hoc network Ah containing the low power communication module n5 of the vehicle as a node based on the determined location of the vehicle and transmits the remote control signal to the determined infrastructure network .

As described above, the remote control signal transmitted from the server 600 is transmitted to the ad hoc network (Ah) through the infrastructure network. As shown in Fig. 5, the remote control signal may be transmitted to the low-power communication module n5 of the target vehicle via a plurality of nodes constituting the ad hoc network Ah.

The low-power communication module n5 outputs a remote control signal to the telematics terminal 520 (870). When the telematics terminal 520 receives the remote control signal, the low-power communication module n5 turns on 880 and performs control according to the remote control signal (890).

The low power communication module n5 outputs a remote control signal to the telematics terminal 520 to transmit the telematics terminal 520 to the low power communication module n5, Turn on. When the telematics terminal 520 is turned on, the telematics terminal 520 transmits a remote control signal to the subject control device 540 in accordance with the remote control signal output from the low power communication module n5 so that control according to the remote control signal is performed.

On the other hand, the ad hoc network Ah may be configured to include a plurality of clusters including a plurality of nodes. The ad hoc network Ah may comprise nodes between these clusters that connect the clusters. However, if the number of the connection nodes is smaller than the amount of data to be transmitted, the communication efficiency becomes poor. In addition, if such a connection node is lost, communication between the clusters becomes impossible, and remote control of the vehicle 100 through the ad hoc network Ah may be impossible. Another embodiment disclosed herein provides a network management system capable of improving the communication efficiency between clusters and preparing for loss of a node connecting clusters, and a remote control method of a vehicle using the network management system. Hereinafter, a network management system according to an embodiment disclosed with reference to FIGS. 7 to 9 will be described. 7 to 9 are conceptual diagrams illustrating a method of remote control of a vehicle in a network management system according to an embodiment.

7, the ad hoc network Ah includes a first cluster C1 including a first node n1-1 and a second cluster C1 including a low power communication module n2-4 of the vehicle 100, And a second node nb for connecting the first cluster C1 and the second cluster C2 to transmit a remote control signal through the ad hoc network Ah, . ≪ / RTI >

7 to 9 show that the first cluster C1 includes four nodes including the first node n1-1 and the second cluster C2 includes four nodes including the low power communication module n2-4 ). However, the number of nodes included in each cluster is not limited. Although two clusters are shown in Figs. 7 to 9, the number of clusters is also not limited.

When configuring the ad hoc network Ah, the first node n1-1 periodically receives information on the connection state of the network and GPS information from each node, and stores and manages information on the network topology .

If the number of the second nodes nb is smaller than the amount of data of the remote control signal received from the server 600, the communication efficiency may decrease. Therefore, when the number of the second nodes nb is equal to or less than the predetermined reference number or the second node nb is lost, the first node n1-1 can not connect the first cluster C1 and the second cluster C2 You can search for a node to connect to.

The network management system according to the present embodiment may include an unmanned mobile device 710 including a low power communication module capable of configuring a node of the ad hoc network Ah to a second node nb, .

If the number of the second nodes nb is equal to or less than a predetermined reference number required for smooth transmission of the remote control signal, the first node n1-1 may transmit the control signal to the neighboring unmanned mobile device 710, The position information of the second node nb can be transmitted to the unmanned aerial vehicle.

That is, as shown in Fig. 8, the first node n1-1 transmits and receives the communication between the first cluster C1 and the second cluster C2 together with the second node nb, The position information of the second node nb can be directly transmitted to the unmanned mobile device 710 so as to move to a position where the second node nb can move.

Alternatively, the first node n1-1 may transmit the position of the second node nb to the server 600 without transmitting the positional information of the second node nb directly to the unmanned mobile device 710, The location information of the second node nb may be transmitted from the server 600 to the unmanned mobile device 710.

Alternatively, the first node n1-1 may transmit location information of the second node nb to the unmanned mobile device 710 using the ad hoc network Ah including the unmanned mobile device 710 as a node There will be.

When the position information of the second node nb is received from the first node n1-1 or the server 600, the unmanned mobile device 710 moves around the second node nb as shown in Fig. , And can serve as a new node capable of relaying communication between the first cluster C1 and the second cluster C2.

The unmanned mobile device 710 includes a low power communication module capable of acting as a node of the ad hoc network Ah and a wireless communication module capable of performing communication relay between the first cluster C1 and the second cluster C2 As shown in FIG. In addition to the low power communication module, the unmanned mobile device 710 may include a communication unit capable of performing communication with the server 600 through a commercial wireless network. As described above, the unmanned mobile device 710 can be implemented as an unmanned aerial vehicle such as a drone or an unmanned vehicle.

Meanwhile, when the second node nb is lost and communication between the first cluster C1 and the second cluster C2 is not performed, the first node n1-1 can not communicate with the neighboring unattended mobile device 710, , It is possible to transmit the movement position information to, for example, an unmanned vehicle or an unmanned flight device such as a drone.

In other words, the first node n1-1 is connected to the first cluster C1 and the second cluster n2 to perform the role of the second node nb in which the unmanned mobile device 710 has been lost, C2 to the location where it can relay the communication between the mobile terminal 710 and the unmanned mobile terminal 710. [ Here, the movement position information may include position information of the lost second node nb.

Alternatively, the first node n1-1 may not transmit the movement position information directly to the unmanned mobile device 710 but may transmit the movement position information to the server 600, as described above, And may transmit the movement position information to the device 710. [ Alternatively, the first node n1-1 may transmit mobile location information to the unmanned mobile device 710 using an ad hoc network Ah that includes the unmanned mobile device 710 as a node.

When the unmanned mobile device 710 receives the movement position information from the first node n1-1 or the server 600, the unmanned mobile device 710 moves around the lost second node, (N a, n c) capable of relaying communication between the second cluster C 2 and the second cluster C 2.

With reference to Fig. 10, a remote control method of a vehicle according to another embodiment will be described. 10 is a flowchart illustrating a remote control method of a vehicle in a network management system according to another embodiment.

10, when the second node nb is lost 900 or the number of the second nodes nb is less than the reference number 910, the unmanned mobile device 710 moves to the first cluster C1 And moves to a position where the communication between the second clusters C2 can be relayed (920).

When the communication between the first cluster C1 and the second cluster C2 is not performed due to the loss of the second node nb in the first node n1-1, The mobile position information can be transmitted to an unmanned vehicle or an unmanned flight device such as a drone.

In other words, the first node n1-1 is connected to the first cluster C1 and the second cluster n2 to perform the role of the second node nb in which the unmanned mobile device 710 has been lost, C2 to the location where it can relay the communication between the mobile terminal 710 and the unmanned mobile terminal 710. [ Here, the movement position information may include position information of the lost second node nb.

Alternatively, the first node n1-1 may not transmit the movement position information directly to the unmanned mobile device 710 but may transmit the movement position information to the server 600, as described above, And may transmit the movement position information to the device 710. [ Alternatively, the first node n1-1 may transmit mobile location information to the unmanned mobile device 710 using an ad hoc network Ah that includes the unmanned mobile device 710 as a node.

If the number of the second nodes nb is less than a predetermined reference number necessary for smooth transmission of the remote control signal although the second node nb is not lost, (710), for example, the position information of the second node (nb) to an unmanned flight vehicle such as an unmanned vehicle or a drone.

That is, as shown in Fig. 8, the first node n1-1 transmits and receives the communication between the first cluster C1 and the second cluster C2 together with the second node nb, The position information of the second node nb can be directly transmitted to the unmanned mobile device 710 so as to move to a position where the second node nb can move.

Alternatively, the first node n1-1 may transmit the position of the second node nb to the server 600 without transmitting the positional information of the second node nb directly to the unmanned mobile device 710, The location information of the second node nb may be transmitted from the server 600 to the unmanned mobile device 710.

Alternatively, the first node n1-1 may transmit location information of the second node nb to the unmanned mobile device 710 using the ad hoc network Ah including the unmanned mobile device 710 as a node There will be.

When the position information of the second node nb is received from the first node n1-1 or the server 600, the unmanned mobile device 710 moves around the second node nb as shown in Fig. , And can serve as new nodes (na, nc) capable of relaying communication between the first cluster C1 and the second cluster C2.

The vehicle 100 is connected to the transmitted remote (not shown) via the ad hoc network Ah composed of the first cluster C1, the second node nb or the unmanned mobile device 710 and the second cluster C2 described above. Upon receiving the control signal (930), the telematics terminal 520 of the vehicle 100 is turned on (940), and control according to the remote control signal is performed (950).

When the remote control signal transmitted through the ad hoc network Ah is received in the low power communication module n2-4 of the vehicle 100, the low power communication module n2-4 transmits a remote control signal to the telematics terminal 520, And turns the telematics terminal 520 on. When the telematics terminal 520 is turned on, the telematics terminal 520 transmits a remote control signal to the target control device 540 in accordance with the remote control signal output from the low power communication module n2-4 so that control according to the remote control signal is performed.

The embodiments disclosed with reference to the accompanying drawings have been described above. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. The disclosed embodiments are illustrative and should not be construed as limiting.

400: User terminal
520: Telematics terminal
600: Server
n5, n2-4: Low power communication module
700: Battery

Claims (17)

A first cluster including a first node storing location information and network connection state information of each node constituting an ad-hoc network;
A second cluster comprising a vehicle having a low power communication module for configuring a node of the ad hoc network and receiving a remote control signal for the vehicle via the ad hoc network;
A second node for relaying communication between the first cluster and the second cluster; And
And a server for receiving the remote control signal transmitted from the user terminal and transmitting the remote control signal to the vehicle through the ad hoc network including the first cluster, the second node and the second cluster,
If the second node is lost or the number of the second nodes is equal to or less than a predetermined reference number, it moves to a position capable of relaying communication between the first cluster and the second cluster, And a mobile device. The method according to claim 1,
The first node may move to a location where the unmanned mobile device can relay communications between the first cluster and the second cluster if the second node is lost or if the number of the second nodes is less than or equal to a predetermined reference number And transmits the location information of the second node to the unmanned mobile device or the server. The method according to claim 1,
Wherein the unmanned mobile device comprises:
And a second node for receiving the location information of the second node transmitted from the first node or the server and for moving to a location capable of relaying communication between the first cluster and the second cluster based on the location information of the second node, Management system. The method according to claim 1,
Wherein the unmanned mobile device comprises:
And a low power communication module for transmitting a remote control signal for the vehicle through the ad hoc network to the second cluster. The method according to claim 1,
The vehicle includes:
And turns off the telematics terminal of the vehicle when the remaining amount of the battery reaches a predetermined reference value. The method according to claim 1,
The vehicle includes:
When a remaining amount of the battery reaches a predetermined reference value, transmits a message informing the turn-off of the telematics terminal of the vehicle to the server, and upon receipt of the confirmation message of the message reception from the server, turns off the telematics terminal system. The method according to claim 1,
When the telematics terminal of the vehicle is turned off and the low power communication module receives a remote control signal for the vehicle through the ad hoc network, the vehicle turns on the telematics terminal and performs control according to the remote control signal A network management system to perform. The method according to claim 1,
The server comprises:
And transmitting the remote control signal to the low power communication module through the ad hoc network upon receiving a message informing the turn-off of the telematics terminal from the vehicle. The method according to claim 1,
Wherein the server transmits an acknowledgment message to the telematics terminal of the vehicle upon receipt of a message informing the turn-off of the telematics terminal from the vehicle. The method according to claim 1,
Wherein the server transmits the remote control signal to the telematics terminal of the vehicle through a commercialized mobile communication network if a message informing the turn-off of the telematics terminal is not received from the vehicle. A second node that relays communications between a first cluster that includes the first node and a second cluster that includes a vehicle as a node or a second node that relays communication between the first cluster and the second cluster, Determining whether the number is less than or equal to a predetermined reference number;
If the second node is lost or if the number of the second nodes is less than a predetermined reference number, the unmanned mobile device moves to a position capable of relaying communication between the first cluster and the second cluster, ≪ / RTI >
Wherein, in the vehicle, when a remote control signal transmitted from a server is received through an ad hoc network including the first cluster, the second node or the unmanned mobile device and the second cluster, the telematics terminal of the vehicle is turned And turning on the vehicle. 12. The method of claim 11,
Wherein if the second node is lost or if the number of the second nodes is less than or equal to a predetermined reference number then the first node and the second node are moved to a position where the unmanned mobile device can relay communication between the first cluster and the second cluster. Further comprising transmitting location information of the second node to the unattended mobile device or the server. 12. The method of claim 11,
If the second node is lost or if the number of the second nodes is less than a predetermined reference number, the unmanned mobile device moves to a position capable of relaying communication between the first cluster and the second cluster, ,
When the unmanned mobile device receives location information of the second node transmitted from the first node or the server, relaying communication between the first cluster and the second cluster based on the location information of the second node To a location where the vehicle is located. 12. The method of claim 11,
When the remaining amount of the battery in the vehicle reaches a predetermined reference value, turning off the telematics terminal of the vehicle;
Receiving a remote control signal transmitted from a user terminal at a server;
Further comprising transmitting the remote control signal to a low power communication module of the vehicle via an ad hoc network including the low power communication module of the vehicle as a node at the server. 15. The method of claim 14,
When the remaining amount of the battery in the vehicle reaches a predetermined reference value, turning off the telematics terminal,
Transmitting a message informing the turn-off of the telematics terminal of the vehicle to the server when the remaining amount of the battery reaches a predetermined reference value;
And turning off the telematics terminal when receiving an acknowledgment message for message reception from the server. 15. The method of claim 14,
Transmitting the remote control signal to the low power communication module of the vehicle through an ad hoc network including the low power communication module of the vehicle as a node at the server,
Receiving a message informing the turn-off of the telematics terminal from the vehicle, the server transmits an acknowledgment message for the message reception to the telematics terminal of the vehicle;
And transmitting the remote control signal from the server to the low power communication module of the vehicle via the ad hoc network. 12. The method of claim 11,
And when the telematics terminal of the vehicle is turned on, performing control according to the remote control signal in the vehicle.

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