KR20140050462A - System and apparatus for transmitting traffic information and emergency information using vehicle-roadside communications - Google Patents

Abstract

A system and apparatus for transmitting traffic information and traffic emergency situation information using a communications method between a vehicle and a road are disclosed. An aspect of the present embodiment provides a system for transmitting the traffic information and the traffic emergency situation information comprising: a plurality of sensor nodes for transmitting the emergency situation information to peripheral vehicles and other sensor nodes by receiving the emergency situation information from a telematics terminal mounted in a vehicle and by being installed at a road side with a predetermined distance; a plurality of local control units for displaying the emergency situation information on an electronic display board by receiving the emergency situation information from the sensor nodes installed in respective divisions by being installed in the predetermined divisions of the road; and a management server for receiving the emergency situation information from the local control units and for executing a predetermined action corresponding to the received emergency situation information. [Reference numerals] (220) Node 1; (221) Node 2; (222) Node 3; (230) N-section local control unit; (231) Emergency message; (240) Management server; (AA) Wireless communications method; (BB) Wired communications method

Description

TECHNICAL FIELD [0001] The present invention relates to a traffic information and traffic emergency information propagation system and apparatus using a vehicle-

The present embodiment relates to a method and apparatus for transmitting traffic information and traffic emergency information using a vehicle-to-road communication method. More particularly, the present invention relates to a vehicle-to-road communication method for preventing a secondary accident by propagating such information to a subsequent vehicle in the event of an emergency such as a traffic accident, And a method and an apparatus for spreading emergency information.

The contents described in this section merely provide background information on the present embodiment and do not constitute the prior art.

There is a risk that if a subsequent vehicle does not recognize such a traffic emergency information in the event of a traffic emergency such as an accident on the expressway or a vehicle stop due to a vehicle defect, it may lead to a secondary accident.

The use of an emergency light or a tripod for informing such traffic emergency information is not only difficult for the follower vehicle to recognize when it is in a bad weather condition such as heavy rain or fog, an area with low traffic volume, It is not suitable as a means for propagating emergency occurrence information to a vehicle running on the rear side of the vehicle. As a result, vehicles that enter the road without knowing information about the occurrence of a traffic accident or a point where an accident occurs are subjected to the inconvenience that they do not know English and wait until the accident process is completed.

1 is a diagram illustrating a conventional traffic emergency system based on inter-vehicle communication.

As shown in FIG. 1, in a conventional traffic emergency information propagation system (Korean Patent Laid-Open Publication No. 10-2007-0097093), a sensor node installed in a road center line and a node in a vehicle form a network. In the event of a traffic accident or an emergency, the sensor node transmits relevant information to the vehicle in operation, and the vehicle receiving the related information propagates to the surrounding vehicle using Vehicle-to-Vehicle Communication. Since the conventional traffic emergency system uses the inter-vehicle chain communication method, when there is a small number of traveling vehicles or when a communication device failure occurs in a specific vehicle among the vehicles running consecutively, the reliability may be deteriorated, .

The present embodiment provides a method and an apparatus for transmitting traffic information and emergency situation information that can prevent secondary accidents and traffic congestion by transmitting traffic information and traffic accident information to a rear vehicle using a vehicle-to-road communication system There is a main purpose.

According to an aspect of the present invention, in a traffic information and traffic emergency information propagation system, emergency situation information is received from a telematics terminal installed in a vehicle, and the received emergency information is transmitted to other sensor nodes and nearby vehicles A plurality of sensor nodes provided at certain intervals on the road at predetermined intervals on the road to receive the emergency information from the sensor nodes installed in each zone of the road and display the emergency information on a display board And a management server for receiving the emergency information from the plurality of local control units and performing a predetermined countermeasure in response to the emergency information received from the plurality of local control units Traffic information and traffic emergency information transmission system.

The plurality of sensor nodes can perform communication with the telematics terminal based on a local area communication method.

The plurality of sensor nodes may be installed on the road at predetermined intervals determined based on the close range communication range.

In addition, the plurality of sensor nodes may broadcast the emergency information received from the telematics terminal and the emergency information received from other sensor nodes in the vicinity on the road.

Further, the management server may propagate the emergency information to the relevant control center and the local control unit provided for each section of the road.

In addition, the local control unit may propagate the emergency information received from the management server to the sensor nodes installed in its own section.

In addition, the sensor nodes can propagate the emergency information received from the local control unit to the neighboring vehicle.

According to another aspect of the present invention, there is provided a traffic information and traffic emergency information propagation system, comprising: a plurality of sensor nodes which are installed at predetermined intervals on a road side and receive vehicle operation information from a telematics terminal mounted on the vehicle; A plurality of local control units provided for each of the plurality of subdivisions, for receiving the vehicle driving information from the sensor nodes installed in each of the subdivisions, and a management unit for receiving the vehicle driving information from the plurality of local control units and generating or updating traffic information And provides a traffic information and traffic emergency information propagation system including a server.

The plurality of sensor nodes can receive the traffic information from the management server through the local control unit and propagate the traffic information to the neighboring vehicles.

In addition, the plurality of sensor nodes can perform communication with the telematics terminal based on the local area communication method.

According to another aspect of the present invention, in a telematics terminal of a traffic information and traffic emergency information propagation system, the vehicle state information is collected through CAN (Controller Area Network) communication from OBD (ON-board Diagonsis) A wireless communication unit for communicating with a sensor node of the traffic information and traffic emergency information propagation system, a GPS receiver for receiving position information of the vehicle transmitted from the satellite, And a controller for monitoring the occurrence of an emergency situation based on the vehicle status information collected by the CAN communication unit and for detecting the emergency situation information detected together with the location information of the vehicle, And transmitting the traffic information and the traffic emergency information including the control unit to the sensor node It provides a system of the telematics terminal.

The control unit provides the sensed emergency information to the driver of the vehicle through the information providing unit, and controls the electronic control unit (ECU) in the vehicle through the CAN communication unit to select at least one of the emergency light or horn of the vehicle It is possible to warn the driver of the other vehicle by operating any one of them.

The control unit may receive the traffic information and the emergency information generated on the road from the sensor note through the wireless communication unit and provide the information to the driver of the vehicle through the information providing unit.

In addition, the wireless communication unit can perform communication with the sensor node based on the local area communication method.

According to another aspect of the present invention, there is provided a traffic information and traffic emergency information propagation system, comprising: a monitoring unit for monitoring an occurrence of an emergency situation based on vehicle status information collected from a OBD terminal of the vehicle through CAN communication, A plurality of sensor nodes provided at predetermined intervals on the road in order to receive the emergency information from the telematics terminal and to propagate the received emergency information to other sensor nodes and surrounding vehicles in the vicinity, A plurality of local control units which are installed for each of the predetermined sections and receive the emergency information from the sensor node installed in each of the compartments and display the received emergency information on the electric sign board, And performs a predetermined countermeasure in response to the received emergency situation information It provides traffic information and traffic information, emergency radio systems, including the management server.

According to another aspect of the present invention, in a traffic information and traffic emergency information propagation system, vehicle driving information is generated based on vehicle condition information collected from a OBD terminal of the vehicle via CAN communication, A plurality of sensor nodes which are installed at predetermined intervals on the road and receive the vehicle operation information from the telematics terminal, a plurality of sensor nodes which are provided for each predetermined section of the road, And a management server for receiving the vehicle driving information from the plurality of local control units and generating or updating traffic information.

As described above, according to the present embodiment, traffic accident information is transmitted not only to a vehicle running on a road but also to a vehicle that uses the road, thereby preventing a second accident caused by a subsequent vehicle, Traffic congestion can be reduced.

In addition, the management server notifies the related traffic agency of the traffic emergency information so that rapid response measures can be taken. By propagating the traffic information or the traffic emergency information generated by the management server to the telematics terminal mounted on the vehicle under running, Can be efficiently dispersed.

1 is a diagram illustrating a conventional traffic emergency system based on inter-vehicle communication.
2 is a schematic block diagram of a traffic information and traffic emergency propagation system according to an embodiment of the present invention.
FIG. 3 is a diagram illustrating an operation of the vehicle during road turn-on / exit in a traffic information and traffic emergency information propagation system according to an embodiment of the present invention.
4 is a diagram illustrating an operation in an emergency situation in a traffic information and traffic emergency situation propagation system according to an embodiment of the present invention.
FIG. 5 is a diagram schematically showing a configuration of a telematics terminal according to an embodiment of the present invention.
6 is a diagram schematically showing a configuration of a sensor node according to an embodiment of the present invention.
FIG. 7 is a view schematically showing a configuration of a local control unit according to an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Throughout the specification, when an element is referred to as being "comprising" or "comprising", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise . In addition, '... Quot ;, " module ", and " module " refer to a unit that processes at least one function or operation, and may be implemented by hardware or software or a combination of hardware and software.

2 is a schematic block diagram of a traffic information and traffic emergency propagation system according to an embodiment of the present invention.

The traffic information and traffic emergency situation propagation system according to an embodiment of the present invention includes a telematics terminal 210 mounted on a vehicle, sensor nodes 220 to 222 installed at predetermined intervals on a road, And a management server 240 for collecting information from a local control unit (LCU) 230 and a local control unit 230 for each compartment that constitute a sensor network and sensor nodes in each compartment.

The telematics terminal 210 is mounted on a vehicle and collects vehicle status information from the OBD (ON-board Diagonsis) terminal in the vehicle, and is used for an emergency such as a serious defect of the vehicle, an obstacle on the road, a traffic accident, And judges whether or not a situation occurs.

Here, the vehicle state information is information on the state of the vehicle, such as an engine control device, a transmission control unit (TCU), a suspension control device, a brake control device, and the like, which are detected or diagnosed by an electronic control unit And may include vehicle status information and running status information as diagnostic information. For example, the vehicle state information refers to the state or abnormality of a component installed or installed in the vehicle, and the running state information includes driving information such as the current driving speed, the engine speed, the maximum speed, the average speed, It says.

A plurality of sensor nodes 220 to 222 are arranged at predetermined intervals on the road side. The interval between the sensor nodes can be determined based on the wireless communication range of each sensor node. Each sensor node may have a unique sensor node number, and the sensor node number may function as a unique identifier of each sensor node 220-222 in the network connected to the local control unit. The sensor nodes 220 to 222 transmit the wireless data information periodically, and when the telematics terminal enters the communication area, the sensor nodes 220 to 222 perform information exchange by wireless communication.

Communication between the sensor nodes 220 to 222 and the telematics terminal 210 may be performed using a communication method such as WiFi or Wibro. However, due to the characteristics of this embodiment that the wireless communication should be performed between the locally located sensor nodes 220 to 222 and the telematics terminal 210 mounted on the vehicle moving at a high speed, It is preferable to use Dedicated Short Range Communication (DSRC) scheme.

The local control unit 230 acts as a relay between a plurality of sensor nodes 220 to 222 installed in each of the sections and the management server 240 for each predetermined section of the road, The traffic information or the emergency information can be provided to the driver who is traveling.

The local control unit 230 and the plurality of sensor nodes 220 to 222 provided in the respective sections are connected based on wire communication to form a sensor network. Here, the wired communication network on which the sensor network is based may be an Ethernet communication network or a dedicated communication network.

The management server 240 takes an emergency response action based on the information collected from the local control units 230 installed for each zone, generates traffic information, and distributes the traffic information to each zone-specific control unit. The traffic information may include traffic communication information, traffic control information, emergency information, road state information, and the like. Here, the traffic communication information is information indicating the traffic traffic situation and the traffic prediction situation of the road, and includes information such as speed, traffic volume, travel time, waiting length, congestion degree, interval predicted average speed, And the traffic control information is information indicating the control state of the traffic such as the construction and the event of the planned road, and may include the information such as the location of the control, the type of the control, the object to be controlled, and the control time. In addition, the emergency information is information informing the unexpected state of the road on the road, and may include information on occurrence of an emergency situation, information on an emergency situation, and the like. The road condition information may include a weather condition And may include information such as road surface condition, rainfall / snow water level, and the like.

Hereinafter, the operation of the traffic information and traffic emergency information propagation system according to an embodiment of the present invention will be described with reference to FIG. 3 and FIG.

FIG. 3 is a diagram illustrating an operation of the vehicle when the vehicle enters and exits the road in the traffic information and traffic emergency information propagation system according to an embodiment of the present invention.

3, when the vehicle enters the road where the traffic information and emergency situation information propagation system according to the present embodiment is installed and operated, the telematics terminal 210 mounted on the vehicle is connected to the sensor nodes 220 to 222 The information request message is transmitted periodically.

In response to the information request message, the telematics terminal 210 mounted on the vehicle transmits the vehicle driving information such as the vehicle ID, the moving speed of the vehicle, and the destination information to the sensor nodes 220-222. Here, the vehicle ID information may be a unique ID assigned to each telematics terminal 210. The sensor nodes 220 to 222 transmit the received vehicle driving information to the local control unit 230 of the corresponding partition. The local control unit 220 to 222 transmits the received vehicle driving information to the management server 240.

The management server 240 registers / stores the received vehicle state information and generates / updates traffic information (e.g., traffic communication information, traffic control information, emergency situation information, road state information, etc.) And transmits the updated traffic information to the local control units 230 located in each block.

The local control unit 230 transmits the traffic information received from the management server 240 to the sensor nodes 220 to 222 located in the corresponding segment. The local control unit 230 can provide the received traffic information to the driver of the vehicle passing through the corresponding point through an electric sign board (not shown).

The sensor nodes 220 to 222 propagate the traffic information received from the local control unit 230 to the telematics terminals 210 in the wireless communication area.

The telematics terminal 210 receives traffic information from the sensor nodes 220 to 222 and provides the corresponding traffic information to the driver.

When the vehicle is advanced from the road in which the traffic information and traffic emergency propagation system according to the present embodiment is deployed, the telematics terminal 210 installed in the vehicle periodically transmits an information request message periodically transmitted from the sensor nodes 220 to 222 . That is, the sensor nodes 220 to 222 installed near the exit of the road (for example, the exit of the highway) periodically broadcast an information request message on the road in order to obtain the vehicle departure information.

In response to the information request message, the telematics terminal 210 transmits the vehicle ID information to the sensor nodes 220-222. The sensor nodes 220 to 222 transmit the received vehicle ID information to the local control unit 230 responsible for the corresponding interval. The local control unit 230 transmits the received vehicle ID information to the management server (not shown), and the management server (not shown) releases the registration of the received vehicle ID information.

4 is a diagram illustrating an operation in an emergency situation in a traffic information and traffic emergency situation propagation system according to an embodiment of the present invention.

If the telematics terminal 210 detects emergency information that may pose a risk to safe operation such as a serious fault of the vehicle, an obstacle on the road, a traffic accident, or the like based on the vehicle condition information collected from the OBD terminal in the vehicle, 210 informs the driver primarily through the image, voice, etc. of the information, automatically activates the emergency light and horn of the vehicle, and notifies the driver of the other vehicle located at a nearby location of the occurrence of an emergency. Also, the telematics terminal 210 transmits an emergency message including the ID, destination information, location information, and defect information of the corresponding vehicle to the sensor node 222.

The sensor node 222 receiving the emergency message from the telematics terminal 210 transmits the received emergency message to the adjacent rear sensor node 221 and the local control unit 230. The rear sensor node 221 subsequently propagates the emergency message received at its rear sensor node 220. In addition, the sensor nodes 221-222 receiving the emergency message broadcast the received emergency message on the road in order to prevent the secondary accident and to secure the route of the emergency vehicle.

That is, the emergency message generated from the telematics terminal 210 is sequentially propagated to the sensor nodes 221 to 220 via the sensor node 222 that receives the emergency message, and the emergency messages are transmitted to the sensor nodes 220 to 222 And is sequentially transmitted to the vehicles that are running on the rear side of the point where the emergency occurs.

Upon receiving the emergency message, the local control unit 230 displays information such as the distance to the incident point on the electric signboard 231 based on the current position, and transmits the received emergency message to the management server 240.

The management server 240 takes emergency response measures (for example, transmission of information to a police station, an insurance company, etc.) on the basis of the received emergency message, and transmits emergency information to the rear local control units (not shown) of the accident point.

The backward local control units display the information such as the distance to the point of incidence based on the current position on the electric signboard, and transmit the emergency information to the sensor nodes located in their own compartments. The sensor nodes that have received the emergency information broadcast it on the road, and the telematics terminals that received the broadcast emergency information provide the emergency information to the driver.

Hereinafter, a schematic configuration of a telematics terminal, a sensor node, and a local control unit included in a traffic information and traffic emergency situation propagation system according to an embodiment of the present invention will be described with reference to FIG. 5 to FIG.

FIG. 5 is a diagram schematically showing a configuration of a telematics terminal according to an embodiment of the present invention.

5, the telematics terminal 500 according to the present embodiment includes a wireless communication unit 510, a GPS receiving unit 520, an information providing unit 530, a CAN communication unit 540, and a terminal_ control unit 550. .

The wireless communication unit 510 may be implemented as an RF module and an RF antenna capable of supporting DSRC communication, for example, as wireless communication means for exchanging information with a sensor node.

The GPS receiving unit 520 receives the current position information of the vehicle transmitted from the satellite and transmits it to the control unit, and includes a GPS receiving module and a GPS antenna.

The information providing unit 530 may be implemented as information providing means for providing the driver with the traffic information and the emergency information, and supporting the image or voice.

The CAN communication unit 540 collects the vehicle status information from the in-vehicle OBD terminal. Here, the vehicle state information is used as self-diagnosis information detected or diagnosed by an in-vehicle electronic control unit (ECU) such as an engine control device, a shift control device (TCU), a suspension control device, And may include status information. Specifically, the vehicle condition information is information on the condition or abnormality of the parts installed or installed in the vehicle, and the running condition information includes information on the current running speed, the engine speed, the maximum speed, the average speed, the mileage, Driving information.

The terminal control unit 550 controls the respective units 510 to 540 of the telematics terminal 500. The terminal control unit 550 transmits the vehicle driving information to the sensor node through the wireless communication unit 510 in response to the information request message of the sensor node. The vehicle operation information includes a vehicle ID (or a unique ID of the telematics terminal 500) acquired based on the information collected through the GPS receiver 520, the CAN communication unit 540, or information input from the driver, Destination information, and the like.

In addition, the terminal_control unit 550 monitors whether an emergency occurs, including serious faults or accidents, of the vehicle parts based on the vehicle state information collected through the CAN communication unit 540. [ If it is determined that an emergency has occurred, the terminal_ control unit 550 informs the driver of the emergency information through the information provision unit 530 in advance, and informs the driver of the other vehicle of the occurrence of an emergency, 540 to operate the emergency light, horn, etc. of the vehicle. Also, the terminal_ control unit 550 transmits the emergency information to the sensor node through the wireless communication unit 510.

In addition, the terminal_ controller 550 receives the traffic information of the road traveling from the sensor node and the emergency information of the other vehicle, and provides the information to the driver through the information provider 530.

6 is a diagram schematically showing a configuration of a sensor node according to an embodiment of the present invention.

6, the sensor node 600 according to the present embodiment includes a wireless communication unit 610, a wired communication unit 620, and a sensor node_ control unit 630. As shown in FIG.

The wireless communication unit 610 may be implemented as an RF module and RF antenna capable of supporting DSRC communication, for example, as wireless communication means for exchanging information with a telematics terminal installed in a vehicle.

The wired communication unit 620 is connected to the sensor network and is a wired communication means for communicating with the local control unit and the peripheral sensor node, and can support, for example, TCP / IP protocol based communication.

The sensor node_ controller 630 collectively controls the units 610 through 620 of the sensor node 600. The sensor node_controller 630 collects the vehicle operation information from the telematics terminal of the vehicle through the wireless communication unit 610 and transmits it to the local control unit through the wired communication unit 620. [

When receiving the emergency information from the telematics terminal, the sensor node_ controller 630 broadcasts the emergency information on the road through the wireless communication unit 610 and transmits the emergency state information to the peripheral sensor node through the wired communication unit 620 Spread the emergency information. The sensor node_controller 630 can receive the emergency information from the peripheral sensor node through the wired communication unit 620 and can broadcast the received emergency information on the road through the wireless communication unit 610 .

FIG. 7 is a view schematically showing a configuration of a local control unit according to an embodiment of the present invention.

7, the local control unit 700 according to the present embodiment includes a wired communication unit 710, a display board driving unit 720, and an LCU_ control unit 730.

The wired communication unit 710 is connected to the sensor network and is a wired communication unit for communicating with the sensor nodes and the management server in the corresponding area, and can support, for example, TCP / IP protocol based communication.

The electric panel drive unit 720 drives the electric signboard to display traffic information or emergency information.

The LCU_ control unit 730 controls the control of the units 710 to 720 of the sensor node. The LCU_controller 730 collects vehicle operation information and emergency situation information from the sensor nodes in the coverage area through the wired communication unit 710 and transmits the information to the local control unit through the wired communication unit 710. [ In addition, the LCU_ controller 730 displays the information such as the distance to the point of accident on the electric sign board through the electric panel driving unit 720 based on the received traffic emergency information.

The foregoing description is merely illustrative of the technical idea of the present embodiment, and various modifications and changes may be made to those skilled in the art without departing from the essential characteristics of the embodiments. Therefore, the present embodiments are to be construed as illustrative rather than restrictive, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of the present embodiment should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

210: Telematics terminal 220-222: Sensor node
230: Local control unit 231:
240: management server 500: telematics terminal
510: wireless communication unit 520: GPS receiver
530: Information providing unit 540: CAN communication unit
550: Terminal_controller 600: Sensor node
610: wireless communication unit 620: wired communication unit
630: Sensor node_ control unit 700: Local control unit
710: wire communication unit 720:
730: LCU_controller

Claims (16)

In a traffic information and traffic emergency information propagation system,
A plurality of sensor nodes installed at predetermined intervals on a road to receive emergency situation information from a telematics terminal mounted in a vehicle and to propagate the emergency situation information to other sensor nodes and surrounding vehicles;
A plurality of local control units (LCUs) installed for each predetermined section of the road, receiving the emergency information from the sensor node installed in each of the sections, and displaying the received emergency information on the electric signboard; And
A management server that receives the emergency situation information from the plurality of local control units and performs a predetermined corresponding action in response to the received emergency situation information;
Traffic information and traffic emergency information propagation system comprising a. The method of claim 1,
Wherein the plurality of sensor nodes comprise:
And communicates with the telematics terminal based on the short distance communication method. 3. The method of claim 2,
Wherein the plurality of sensor nodes comprise:
Traffic information and emergency situation information propagation system, characterized in that installed on the side of the road at a predetermined interval determined based on the short-range communication range. The method of claim 1,
Wherein the plurality of sensor nodes comprise:
The emergency information received from the telematics terminal and the emergency information received from other sensor nodes in the vicinity are broadcasted on a road. The method of claim 1,
The management server includes:
And the emergency situation information is propagated to the relevant control center and the local control unit provided for each section of the road. 6. The method of claim 5,
Wherein the local control unit comprises:
And the emergency information received from the management server is propagated to the sensor nodes installed in the compartment of the vehicle. The method according to claim 6,
The sensor nodes
Traffic information and traffic emergency information propagation system, characterized in that for propagating the emergency information received from the local control unit to the surrounding vehicles. In a traffic information and traffic emergency information propagation system,
A plurality of sensor nodes installed on the road at predetermined intervals to receive vehicle driving information from a telematics terminal mounted on the vehicle;
A plurality of local control units installed at predetermined sections of the road to receive the vehicle driving information from the sensor nodes installed in each section; And
A management server that receives the vehicle driving information from the plurality of local control units to generate or update traffic information.
Traffic information and traffic emergency information propagation system comprising a. 9. The method of claim 8,
Wherein the plurality of sensor nodes comprise:
Traffic information and traffic emergency information propagation system, characterized in that for receiving the traffic information from the management server through the local control unit to propagate to surrounding vehicles. 9. The method of claim 8,
Wherein the plurality of sensor nodes comprise:
And communicates with the telematics terminal based on the short distance communication method. A telematics terminal for traffic information and traffic emergency information propagation system,
A CAN communication unit for collecting the vehicle state information through a controller area network (CAN) communication from an on-board diagonsis (OBD) terminal of a vehicle;
A wireless communication unit for communicating with the sensor node of the traffic information and traffic emergency information propagation system;
A GPS receiver for receiving position information of the vehicle transmitted from a satellite;
An information providing unit for providing traffic information and emergency information to the driver of the vehicle; And
A controller for monitoring occurrence of an emergency situation on the basis of the vehicle state information collected by the CAN communication unit and transmitting the emergency state information sensed together with the vehicle position information to the sensor node through the wireless communication unit,
Telematics terminal of the traffic information and emergency situation information propagation system comprising a. 12. The method of claim 11,
Wherein,
And provides the detected emergency information to the driver of the vehicle through the information providing unit and controls an electronic control unit (ECU) in the vehicle through the CAN communication unit to detect at least one of the emergency light or horn of the vehicle Wherein the warning is issued to the driver of the other vehicle by operating any one of the plurality of traffic information and traffic emergency information. 12. The method of claim 11,
Wherein,
Telematics terminal of the traffic information and emergency situation information propagation system, characterized in that for receiving traffic information and emergency situation information generated on the road from the sensor note through the wireless communication unit to the driver of the vehicle through the information providing unit . 12. The method of claim 11,
The wireless communication unit includes:
And communicating with the sensor node based on the local communication method. The telematics terminal of the traffic information and traffic emergency information propagation system. In a traffic information and traffic emergency information propagation system,
A telematics terminal mounted on a vehicle and monitoring whether an emergency situation occurs based on vehicle state information collected through CAN communication from an OBD terminal of the vehicle;
A plurality of sensor nodes installed on the road at predetermined intervals in order to receive the emergency information from the telematics terminal and to propagate the emergency information to the other sensor nodes and the surrounding vehicles in the vicinity;
A plurality of local control units provided for each predetermined section of the road, receiving the emergency information from the sensor node installed in each of the sections, and displaying the received emergency information on the electric signboard; And
A management server that receives the emergency situation information from the plurality of local control units and performs a predetermined corresponding action in response to the received emergency situation information;
Traffic information and traffic emergency information propagation system comprising a. In a traffic information and traffic emergency information propagation system,
A telematics terminal mounted on a vehicle and generating vehicle driving information based on vehicle status information collected through CAN communication from an OBD terminal of the vehicle;
A plurality of sensor nodes installed on the road at predetermined intervals to receive the vehicle driving information from the telematics terminal;
A plurality of local control units installed at predetermined sections of the road to receive the vehicle driving information from the sensor nodes installed in each section; And
A management server that receives the vehicle driving information from the plurality of local control units to generate or update traffic information.
Traffic information and traffic emergency information propagation system comprising a.

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