JP2016095184A - Telematics system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide such a system that a vehicle traveling on a road detects damage on a road surface and informs a road administrator of the damage on the road surface.SOLUTION: A telematics system 1 of the present invention comprises at least a road administration device 12 and a vehicle terminal 10. The vehicle terminal 10 measures at least a vertical vibration measurement value; and when a vibration measurement value exceeds a predetermined threshold, the terminal transmits a road damage detection message including positional information at the detection time to a contact address of the road administration device 12 by use of mobile communication. The road administration device 12 groups the road damage detection message on the basis of the positional information and creates road damage information to display an icon representing a site corresponding to the positional information of the group on a road map.SELECTED DRAWING: Figure 1

Description

  The present invention relates to telematics for providing a service using a mobile communication network.

  In recent years, road surface damage has become a problem. Road surfaces are damaged (eg, collapsed) due to aging roads, larger vehicles, and a significant increase in traffic volume. Road surface damage can cause traffic accidents and hinder traffic.

  The damaged road surface is repaired by the road manager of the damaged road, but the report of the road surface damage to the road manager is basically left to the road passers. It is only necessary for passers to be able to report road damage to road managers promptly. However, since road contact information is often not reported to road managers without knowing the road manager's contact information, they must drive on the road. The vehicle should be able to detect road damage and report road damage to the road manager.

  For example, Patent Documents 1 and 2 have already been disclosed as inventions in which a vehicle detects road surface damage. The invention disclosed in Patent Document 1 is an invention for detecting abnormality of a bridge expansion joint by providing a vehicle with a microphone that collects vehicle running sound. The invention disclosed in Patent Document 2 And a laser displacement meter that measures the distance between the road surface and the lower part of the vehicle.

  Telematics is already known as a technology for transmitting a predetermined report from a vehicle using a mobile communication network. As an application example of telematics, a subscriber of a mobile communication network can be used when an emergency such as a traffic accident occurs. A vehicle emergency call service (for example, Patent Document 1) that sends an emergency call including an identification code (IMSI: International Mobile Subscriber Identity) to a predetermined emergency contact is well known.

  In order to use the vehicle emergency call service, it is necessary to install a terminal device for telematics in the vehicle. In the “prior art” of Patent Document 1, the terminal device for telematics used in the vehicle emergency call service is: In addition to the mobile communication function, it has a function to send an emergency call in an emergency, a function to detect vehicle position information included in the emergency call, and a function to detect an emergency using a collision detection sensor and a rollover detection sensor Have been described.

JP 2011-242294 A Japanese Patent Laid-Open No. 10-2727 JP 2000-232533 A

  As described above, the vehicle is equipped with a microphone that collects driving sound and a laser displacement meter that measures the distance between the vehicle and the road surface, and the vehicle detects damage to the road surface, and from the vehicle using the mobile communication network. Although a technique for transmitting a predetermined notification has already been disclosed, there is no disclosure of an invention in which a vehicle traveling on a road can detect road damage and notify the road manager of the road damage. SUMMARY OF THE INVENTION An object of the present invention is to provide a system in which a vehicle traveling on a road detects road damage and notifies the road manager of the road damage.

  A first invention for solving the above-described problem is a telematics system including at least a road management device operated by a road manager and a vehicle terminal in which a contact information of the road management device is registered. The vehicle terminal according to a first aspect of the present invention is a mobile communication means for performing data communication using a mobile communication network, vibration measurement means for measuring at least a vertical vibration measurement value, and position information of the vehicle terminal. The position detection means to detect and the vibration measurement value measured by the vibration measurement means are monitored, and when the vibration measurement value exceeds a predetermined threshold, the position information at this time is acquired from the position information detection means and then the movement Report control means for executing a process of transmitting a road surface damage detection report including the position information to the contact information of the road management device using body communication means is provided.

  When the vehicle travels on a damaged part of the road surface, vertical vibration due to the road surface damage is applied to at least the vehicle. Therefore, when the vehicle terminal is mounted on the vehicle, the vehicle traveling on the road detects the damage on the road surface. The manager can be notified of road damage. In addition, the conventional technology requires a dedicated vehicle equipped with a microphone that collects running sound and a laser displacement meter that measures the distance between the vehicle and the road surface, whereas in this embodiment, it is mounted on a smartphone or the like. Since the three-axis acceleration sensor can be used as the vibration measuring means, the vehicle terminal can be miniaturized and no significant modification of the vehicle is required. For example, if an application that functions as the notification control means of the vehicle terminal is installed in a smartphone, the smartphone can be used as the vehicle terminal.

  Further, according to a second invention, in the telematics system described in the first invention, when the road management device receives the road surface damage detection report from the vehicle terminal, the road surface damage detection report is sent to the road surface damage detection report DB. Upon receiving a request for provision of road surface damage information from the road surface damage detection report storage means for executing the storing process and the road administrator's terminal device, the road surface damage detection report is sent to the road surface damage detection report within a predetermined period in the past. After extracting the road surface damage detection reports having the same position information extracted from the DB into one group, the information indicating the location corresponding to the position information of the group on the road map is generated as the road surface damage information. And road surface damage information providing means for executing processing to be transmitted to the terminal device of the road manager.

  According to a second aspect of the present invention, the road surface damage information providing means of the road management device generates, as the road surface damage information, information for displaying an icon indicating a location corresponding to the position information of the group on a road map. By providing it to the road manager, the road manager can easily grasp the place where the road surface is damaged visually.

  Furthermore, a third invention is the telematics system described in the second invention, wherein the road management device acquires road construction information including a road construction period and a road construction section from a terminal device of a road manager, and Road construction information acquisition means for performing processing for storing construction information in the road construction information DB is provided, and the road surface damage information providing means of the road management device combines the road surface damage detection reports having the same position information into one group. Previously, the road damage detection notification whose location information is included in the road construction section of the road construction information and whose reception date and time is included in the road construction period of the road construction information is extracted from the road damage detection notification DB. A process of excluding from the road surface damage detection notification is executed.

  The vibration measurement value increases when the vehicle travels on a road construction site other than the road surface damage site, but it corresponds to road construction when generating road surface damage information as in the third aspect of the invention. By omitting the road surface damage detection report, it is possible to omit the road surface damage detection report corresponding to road construction being reflected in the road surface damage information.

  Further, the fourth invention is the telematics system according to the second or third invention, wherein the notification control means of the vehicle terminal uses the vibration measurement value when the threshold value is exceeded as the road damage detection notification. The road surface damage information providing means of the road management device calculates an average value of vibration measurement values of the road surface damage detection notification included in the group, and the color of the icon according to the average value of vibration measurement values Or it is characterized by changing either size.

  As the degree of road surface damage increases, the vibration measurement value generated when the vehicle travels on the road damage point increases. Therefore, as in the fourth aspect, the vibration measurement value is displayed on the icon displayed in the road surface damage information. If the average value is reflected, the road manager can grasp the degree of damage occurring at the location corresponding to the icon from the icon displayed in the road surface damage information.

  Furthermore, a fifth aspect of the present invention is the telematics system according to any one of the second to fourth aspects, wherein the road surface damage information providing means of the road management device includes the road surface damage included in the group. The number of detection reports is counted, and either the color or the size of the icon is changed according to the number of road surface damage detection reports.

  The greater the number of vehicles that have generated large vibrations when traveling on a damaged part of the road surface, the greater the number of road surface damage detection notifications transmitted to the road management device. Therefore, the icon displayed in the road surface damage information If the number of the road surface damage detection notifications is reflected on the road surface, the road manager has generated a large vibration from the icon displayed in the road surface damage information due to the road surface damage occurring in the location corresponding to the icon. Know the number of vehicles.

  As described above, according to the present invention described above, when a vehicle traveling on a road travels on a road surface damaged part, the road surface damage is automatically detected and the road administrator is notified of the road surface damage. Can provide.

The figure explaining the telematics system which concerns on this embodiment. The block diagram of the telematics system which concerns on this embodiment. The figure explaining operation | movement of a vehicle terminal. The figure explaining operation | movement of the road surface damage information provision means of a road management apparatus. The figure explaining road surface damage information.

  From here, preferred embodiments of the present invention will be described. The following description is not intended to limit the scope of the present invention, but is provided to aid understanding.

  FIG. 1 is a diagram illustrating a telematics system 1 according to the present embodiment, and FIG. 2 is a block diagram of the telematics system 1 according to the present embodiment. As shown in FIG. 1, the telematics system 1 according to this embodiment includes at least a road management device 12 operated by a road manager and a vehicle terminal 10 in which a contact information of the road management device 12 is registered. 1, in addition to these devices, a road map DB device 14 storing road map information and a road manager's terminal device 13 are illustrated.

  First, the vehicle terminal 10 which comprises the telematics system 1 which concerns on this embodiment is demonstrated. The vehicle terminal 10 mounted on the vehicle 11 is a device realized by using a computer. As shown in FIG. 2, the vehicle terminal 10 according to this embodiment includes a mobile communication unit 100, a vibration measurement unit 101, Position detecting means 102 and notification control means 103 are provided.

  The mobile communication means 100 of the vehicle terminal 10 is means for the vehicle terminal 10 to communicate using the mobile communication network 15. Since the mobile communication means 100 of the vehicle terminal 10 is the same as the mobile communication function provided in a commercially available mobile phone or smartphone, it will not be described in detail.

  The vibration measuring means 101 of the vehicle terminal 10 is a means for measuring at least a vertical vibration measurement value as an index indicating road surface unevenness. The vibration measuring means 101 according to this embodiment has a predetermined sampling interval. Outputs the maximum vibration measurement value within the sampling interval. A triaxial acceleration sensor can be used as the vibration measuring unit 101. When a triaxial acceleration sensor is used as the vibration measuring unit 101, the vibration measurement value output from the vibration measuring unit 101 is acceleration.

  The position detection means 102 of the vehicle terminal 10 is a means for measuring the position information (latitude and longitude) of the vehicle terminal 10, and the vehicle terminal 10 according to the present embodiment includes the position detection means 102 for detecting road surface damage. This is because the location can be specified on the vehicle terminal 10 side. As a method for detecting the position information of the vehicle terminal 10, there is a method using GPS (Global Positioning System). However, since the vehicle terminal 10 of the present embodiment includes the mobile communication unit 100, the position of the vehicle terminal 10 is determined. The detecting means 102 is preferably means for detecting position information using a mobile communication relay base.

  The notification control means 103 of the vehicle terminal 10 is a means for transmitting a road surface damage detection report including position information when the road surface damage is detected to the contact point of the road management device 12 when the road surface damage is detected. 10 is a means realized by a CPU (Central Processing Unit) implemented in the computer 10 and a computer program for causing the CPU to function as the notification control means 103.

  FIG. 3 is a diagram for explaining the operation of the vehicle terminal 10. When the vehicle terminal 10 is turned on and the mobile communication means 100 is connected to the mobile communication network 15 (S1), the vibration measurement means 101 of the vehicle terminal 10 starts measuring vibrations and vibrates at predetermined sampling intervals. The measured value is output (S2).

  The notification control means 103 of the vehicle terminal 10 monitors the output of the vibration measuring means 101, and when the vibration measuring means 101 outputs a vibration measurement value, executes a process of acquiring the vibration measurement value from the vibration measuring means 101 (S3). Then, the notification control means 103 of the vehicle terminal 10 executes a process of acquiring the position information at this time from the position detection means 102 (S4). If the time interval from the acquisition of the vibration measurement value to the acquisition of the position information is long, the distance traveled by the vehicle 11 between the acquisition of the vibration measurement value and the acquisition of the position information is increased. The time interval from the acquisition of the measurement value to the acquisition of the position information should be as short as possible.

  Next, the notification control unit 103 of the vehicle terminal 10 executes a process of determining whether the vibration measurement value acquired from the vibration measurement unit 101 is equal to or greater than a threshold value (S5). Since this threshold value becomes a reference value when the notification control means 103 of the vehicle terminal 10 determines whether or not the road surface is damaged, the minimum vibration measurement value that determines that the road surface is damaged is the threshold value.

  The notification control means 103 of the vehicle terminal 10 returns the process to S3 of FIG. 3 when the vibration measurement value acquired from the vibration measurement means 101 is less, and when the vibration measurement value acquired from the vibration measurement means 101 is greater than or equal to the threshold value, The notification control means 103 of the vehicle terminal 10 executes processing for determining whether or not the vehicle 11 is traveling (S6). Although it can be configured to input the traveling speed of the vehicle 11 to the vehicle terminal 10 so that it can be determined whether or not the vehicle 11 is traveling, the vibration measurement of the vehicle terminal 10 is performed using a three-axis acceleration sensor. When the means 101 is realized, the traveling speed of the vehicle 11 can be calculated from the acceleration in the horizontal direction.

  If it is determined that the vehicle 11 is not traveling, the notification control means 103 of the vehicle terminal 10 returns the process to S3 in FIG. 3 without transmitting a road surface damage detection notification, and determines that the vehicle 11 is traveling. In this case, the mobile communication unit 100 is activated, and a road surface damage detection report including the position information acquired from the position detection unit 102 and the vibration measurement value acquired from the vibration measurement unit 101 is transmitted to the contact of the road management device 12. The process (S7) is executed, and the process returns to S3 in FIG. Note that the procedure illustrated in FIG. 3 ends when the vehicle terminal 10 is turned off.

  In FIG. 1, there are two places 2a and 2b where the road surface is damaged, and two places 2c and 2d as road construction places. When the vehicle 11 travels on a damaged road surface or a road construction site, the vibration measurement value output by the vibration measuring means 101 increases, so that the vehicle terminal 10 mounted on the vehicle 11 passes the road surface to the contact point of the road management device 12. Send a damage detection report. Further, when the vehicle 11 travels other than the damaged part and the construction part, the vibration measurement value output from the vibration measuring means 101 does not increase, so that the vehicle terminal 10 mounted on the vehicle 11 sends a road surface to the contact point of the road management device 12. Do not send damage detection report.

  In FIG. 1, the road management device 12 is illustrated as a single unit. However, since the road manager of the road becomes a prefecture where the road is located, it is desirable to install the road management device 12 for each prefecture. . When the road management device 12 is installed for each prefecture, the contact information of the road management device 12 is stored in the vehicle terminal 10 for each prefecture, and the vehicle terminal 10 corresponds to the position information of the road surface damage detection report. It is preferable that a road surface damage detection report can be transmitted to the contact information of the road management device 12.

  Next, the road management device 12 constituting the telematics system 1 according to the present embodiment will be described. The road management device 12 is a device realized by using a general-purpose server. As a means in which a computer program and hardware resources cooperate, a road surface damage detection report storage means 120, a road surface damage information provision means 121, and road construction information acquisition Means 122 is provided, and as the DB, a road surface damage detection notification DB 123 for storing road surface damage detection notifications received from the vehicle 11 and a road construction information DB 124 for storing road construction information are provided.

  The road surface damage detection report storage means 120 of the road management device 12 is a means for storing the road surface damage detection report received from the vehicle terminal 10 in the road surface damage detection report DB 123. When the road surface damage detection report is transmitted from the vehicle terminal 10, The process which memorize | stores the road surface damage detection report received from the vehicle terminal 10 in road surface damage detection report DB123 is performed.

  The road construction information acquisition means 122 of the road management device 12 can set the road construction information including the road construction period and road construction section of the road construction performed by the road manager within the jurisdiction of the road manager in the road management device 12. It is means provided in. When the road construction information acquisition means 122 of the road management device 12 receives a request for setting the road construction information from the terminal device 13 of the road manager, the road construction information acquisition means 122 transmits a form for inputting the road construction information to the terminal device 13 of the road manager. Then, the road construction information is acquired from the terminal device 13 of the road manager, and the road construction information is stored in the road construction information DB 124.

  The road surface damage information providing means 121 of the road management device 12 is a means provided so as to be able to provide the road manager with the road surface damage status within the jurisdiction of the road manager.

  FIG. 4 is a diagram for explaining the operation of the road surface damage information providing means 121 provided in the road management device. When the road surface damage information providing means 121 of the road management device 12 receives a road surface damage information provision request from the terminal device 13 of the road manager, the road surface damage detection notification is made within the past predetermined period (for example, within one month). Is extracted from the road surface damage detection notification DB 123 (S10). Next, the road surface damage information providing means 121 of the road management device 12 includes a road surface damage detection report that matches the content of the road work information, that is, the position information is included in the road work section of the road work information, and the report date and time is A process of removing the road surface damage detection report included in the road construction period of the road work information from the road surface damage detection report extracted from the road surface damage detection report DB 123 is executed (S11). Next, the road surface damage information providing unit 121 of the road management device 12 executes a process of grouping road surface damage detection reports having the same position information into one group (S12). Next, the road surface damage information providing means 121 of the road management device 12 generates, as road surface damage information, information for displaying an icon indicating a location corresponding to the group position information on the road map, and the terminal device 13 of the road manager. (S13), and this procedure ends.

  The notification date and time of the road surface damage detection notification required in the procedure of FIG. 4 may be the date and time when the vehicle terminal 10 transmits the road surface damage detection notification, and the date and time when the road management device 12 receives the road surface damage detection notification. It may be. When the date and time at which the vehicle terminal 10 transmits a road surface damage detection report is used as the notification date and time of the road surface damage detection report, the vehicle terminal 10 uses this date and time as the notification date and time when transmitting the road surface damage detection report. Is added to the road damage detection report. Further, when the road management device 12 receives the road surface damage detection report as the notification date, the road surface damage detection report storage means 120 of the road management device 12 adds the reception date and time to the road surface damage detection report as the report date. From this, the road damage detection report is stored in the road damage detection report DB 123.

  Further, in the procedure of FIG. 4, when the road surface damage information providing unit 121 of the road management device 12 executes a process of grouping road surface damage detection reports having the same position information into one group, the position information included in the road surface damage information is obtained. Round to a predetermined number of digits.

  In the procedure of FIG. 4, the road surface damage information providing means 121 of the road management device 12 calculates the average value of the vibration measurement values of the road surface damage detection notification included in the group, and the road according to the average value of the vibration measurement values. It is desirable to change either the color or the size of the icon displayed on the map. Further, the road surface damage information providing means 121 of the road management device 12 counts the number of road surface damage detection reports included in the group, and displays the color or size of the icon displayed on the road map according to the number of road surface damage detection reports. It is more desirable to change either. When changing the color or size of the icon displayed on the road map according to the average value of the vibration measurement value and the number of road surface damage detection reports, the content of the icon change is the average value of the vibration measurement value. It is important not to overlap the number of road damage detection reports. For example, when the icon color is changed according to the average value of the vibration measurement values, it is necessary to change the icon size according to the number of road surface damage detection reports.

  FIG. 5 is a diagram for explaining road surface damage information. In FIG. 5, the road map of road surface damage information 3 is a road map in the jurisdiction of the road manager. The road map information in the jurisdiction area of the road manager may be stored in the road management device 12 in advance, but the road management device 12 sends the road map information in the jurisdiction area of the road manager from the road map DB device 14. It is common to configure to obtain.

  In FIG. 5, the icon 30 displayed on the road map has a bar shape, the height of the icon 30 indicates the number of road surface damage detection reports included in the group, and the color of the icon 30 (here, concentration). , Represents the average value of vibration measurement values of road surface damage detection reports included in the group.

  In FIG. 5, the icon 30a displayed at the location corresponding to the location 2a in FIG. 1 where the road surface is damaged is high in the height of the icon 30a and the color of the icon 30a is dark. Since the degree of damage of the road surface occurring in 2a is large, and it can be seen that there are a large number of vehicles 11 that have generated large vibrations due to road surface damage occurring in the location 2a in FIG. Therefore, it can be determined that the road surface damage occurring at the location 2a in FIG. Further, the icon 30b displayed at the location corresponding to the location 2b in FIG. 1 where the road surface has been damaged is low in the height of the icon 30b and the color of the icon 30b is light. Since the degree of damage of the generated road surface damage is small, and the number of vehicles 11 that have generated large vibrations due to the road surface damage occurring at the location 2b in FIG. It can be determined that the road surface damage occurring at the location 2b in FIG. 1 does not require immediate repair. In FIG. 1, a road surface damage detection report is sent from the vehicle 11 when traveling at a damaged location and a construction location. However, when the vehicle 11 travels at a road construction location by executing the procedure of FIG. The road damage detection report transmitted from the vehicle 11 is not reflected in the road damage information.

  As described above, according to the telematics system 1 according to the present embodiment, when the vehicle 11 travels on a damaged portion of the road surface, vertical vibration due to the road surface damage is applied to at least the vehicle 11, so that the vehicle on which the vehicle terminal 10 is mounted. 11 can detect road surface damage and report road surface damage to the contact person of the road manager device. Further, the road management device 12 generates road surface damage information that displays on the road map an icon indicating a location corresponding to the position information of the group related to the road surface damage detection report, so that the road administrator can recognize that the road surface is damaged. It becomes easy to visually grasp the place where it occurs. Furthermore, when the road management device 12 generates road surface damage information, the road surface damage detection report transmitted from the road construction site is reflected in the road surface damage information by removing the road surface damage detection report suitable for road construction. Can be omitted. Further, the road management device 12 reflects the average value of the vibration measurement value on the icon displayed on the road surface damage information, so that the road manager can change the icon corresponding to the icon from the icon displayed on the road surface damage information. The degree of damage occurring can be grasped. Further, the road management device 12 reflects the number of road surface damage detection reports on the icon displayed on the road surface damage information, so that the road manager is generated from the icon displayed on the road surface damage information at a location corresponding to the icon. It is possible to grasp the number of vehicles 11 in which large vibration has occurred due to damage on the road surface.

DESCRIPTION OF SYMBOLS 1 Telematics system 10 Vehicle terminal 100 Mobile communication means 101 Vibration measuring means 102 Position detection means 11 Vehicle 12 Road management apparatus 120 Road surface damage detection report storage means 121 Road surface damage information provision means 122 Road construction information acquisition means 123 Road surface damage detection report DB
124 Road construction information DB
13 Terminal equipment of road manager

Claims (5)

A road management device operated by a road manager, and a vehicle terminal in which a contact information of the road management device is registered.
The vehicle terminal includes mobile communication means for performing data communication using a mobile communication network, vibration measurement means for measuring at least a vertical vibration measurement value, and position detection means for detecting position information of the vehicle terminal. The vibration measurement value measured by the vibration measurement means is monitored, and when the vibration measurement value exceeds a predetermined threshold, the position information at this time is acquired from the position information detection means, and then the mobile communication means is used. And a report control means for executing a process of transmitting a road surface damage detection report including the position information to the contact information of the road management device,
A telematics system characterized by that. The road management device, when receiving the road damage detection report from the vehicle terminal, road damage detection report storage means for executing processing for storing the road damage detection report in a road damage detection report DB, and a road manager's terminal When a request for provision of road surface damage information is received from the device, the road surface damage detection report whose notification date and time is within a predetermined period in the past is extracted from the road surface damage detection report DB, and the road surface damage detection report with the same position information is grouped into one group After the data is collected, road surface damage information is provided for executing processing for generating, as the road surface damage information, information for displaying an icon indicating a location corresponding to the position information of the group on the road map and transmitting the information to the terminal device of the road manager With means,
The telematics system according to claim 1. The road management device includes road construction information acquisition means for acquiring road construction information including a road construction period and a road construction section from a terminal device of a road manager and storing the road construction information in a road construction information DB. The road surface damage information providing means of the road management device includes the position information included in the road work section of the road work information before collecting the road surface damage detection reports having the same position information into one group. , Executing a process of removing the road damage detection report whose reception date / time is included in the road construction period of the road construction information from the road damage detection report extracted from the road damage detection report DB;
The telematics system according to claim 2. The notification control means of the vehicle terminal includes a vibration measurement value when a threshold value is exceeded in the road damage detection notification, and the road damage information providing means of the road management device includes the road damage included in the group. Calculate the average value of the vibration measurement value of the detection report, and change either the color or the size of the icon according to the average value of the vibration measurement value.
The telematics system according to claim 2 or claim 3, characterized by that. The road surface damage information providing means of the road management device counts the number of road surface damage detection reports included in the group, and changes either the color or the size of the icon according to the number of road surface damage detection reports. Do,
The telematics system according to any one of claims 2 to 4, wherein the telematics system is provided.