JP2013016004A - Moving image information providing server, moving image information providing system, and navigation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To use collected moving image information more efficiently.SOLUTION: A moving image information providing server comprises: means for acquiring moving image information photographed during traveling of a vehicle and attribute information of the moving image information, and storing them in a storage device; receiving means for receiving a generation instruction of route moving image information made up of moving image information along a predetermined route from an external device; route moving image information generating means for identifying moving image information making up the route moving image information by using the attribute information to generate the route moving image information by using the identified moving image information; and transmitting means for transmitting the generated route moving image information to the external device.

Description

  The present invention relates to a moving image information providing server, a moving image information providing system, and a navigation device.

  Patent Document 1 discloses a technique for transmitting vehicle information including moving image information captured by a drive recorder to a server.

JP 2007-11148 A

  However, the video information collected by the server is used only for the analysis of the cause of an accident, despite the fact that it is highly valuable information that records image information viewed from the driver's point of view. It is not done.

  Therefore, an object of the present invention is to provide a server that can use collected video information more efficiently.

  In order to solve the above-described problem, the moving image information providing server according to the present invention acquires moving image information and attribute information of the moving image information captured when the vehicle is traveling, and stores the moving image information in a storage device along a predetermined route. A receiving unit that receives an instruction to generate route moving image information configured from the moving image information from an external device, the moving image information constituting the route moving image information is identified using the attribute information, and the identified moving image information is used A route moving image information generating unit that generates the route moving image information and a transmitting unit that transmits the generated route moving image information to the external device are included.

  According to the moving image information providing server according to the present invention, the collected moving image information can be used more efficiently.

It is a figure which shows schematic structure of the moving image information provision system which concerns on one Embodiment of this invention. It is a figure which shows schematic structure of the navigation apparatus which concerns on one Embodiment of this invention. It is a figure which shows schematic structure of the drive recorder which concerns on one Embodiment of this invention. It is a figure which shows schematic structure of the moving image information provision server which concerns on one Embodiment of this invention. It is the figure which showed the area | region information which concerns on one Embodiment of this invention. It is the figure which matched the probe data which concern on one Embodiment of this invention, and moving image information, and moving image ID. It is a figure which shows the functional block of the drive recorder which concerns on one Embodiment of this invention. It is a figure which shows the functional block of the navigation apparatus which concerns on one Embodiment of this invention. It is a figure which shows the functional block of the moving image information provision server which concerns on one Embodiment of this invention. It is a flowchart which shows the probe data generation process which concerns on one Embodiment of this invention. It is a flowchart which shows the moving image information storage process which concerns on one Embodiment of this invention. It is a flowchart which shows the path | route moving image information generation process which concerns on one Embodiment of this invention. It is a flowchart which shows the detail of the path | route moving image information generation process which concerns on one Embodiment of this invention. It is a flowchart which shows the detail of the path | route moving image information generation process which concerns on one Embodiment of this invention. It is a figure which shows the probe data log | history which concerns on the discontinuous driving | running | working area which concerns on one Embodiment of this invention. It is a figure which shows the probe data log | history which concerns on the discontinuous driving | running | working area (when a right turn point is included) which concerns on one Embodiment of this invention. It is a figure which shows the probe data log | history which concerns on one Embodiment of this invention. It is a figure which shows the apparatus regarding the simulation process which concerns on one Embodiment of this invention.

  Hereinafter, a moving picture information providing system according to an embodiment of the present invention will be described.

  FIG. 1 is a diagram showing a schematic configuration of a moving image information providing system. The moving image information providing system includes a navigation device 100 and a drive recorder 50 mounted on a vehicle, a moving image information providing server 200 installed in an information center, and a user terminal 300 that is a personal computer. The moving image information providing server 200 is a website server that can provide a travel planning site through the user terminal 300.

  The navigation device 100 and the moving image information providing server 200 are connected to each other by wireless communication via a digital communication network c such as the Internet network. The user terminal 300 and the moving image information providing server 200 are connected to each other by wired communication or wireless communication via the digital communication network c.

  Further, as shown in the figure, the predetermined information generated by the drive recorder 50 or the navigation device 100 is stored in, for example, a removable recording medium and transmitted to the moving image information providing server 200 via the user terminal 300. Can do.

  FIG. 2 is a diagram showing a schematic configuration of the navigation device 100 according to the present embodiment. The navigation device 100 includes an arithmetic processing device 1, a display 10, a storage device 11, a voice input / output device 13, an input device 16, a ROM device 20, a vehicle speed sensor 21, a gyro sensor 22, and a GPS receiver. 23, an FM multiplex broadcast receiver 24, a beacon receiver 25, and a data transmitter / receiver 26. These devices and sensors are connected to each other via a bus 6 so that data can be exchanged.

  The navigation device 100 is a device that can realize a so-called navigation function such as display of map information, traffic information, search for a recommended route, route guidance, and the like.

  The arithmetic processing device 1 is a central unit that performs various processes of the navigation device 100. The arithmetic processing device 1 specifies the current location of the user using information output from various sensors such as the vehicle speed sensor 21 and the gyro sensor 22, the GPS receiver 23, and the like. In addition, the arithmetic processing device 1 searches for a recommended route connecting the departure place and the destination using the map information 12 stored in the storage device 11. In addition, the arithmetic processing device 1 performs graphics conversion on the map information 12, traffic information, guidance route information, and the like, and outputs them to the display 10. In addition, the arithmetic processing device 1 generates voice information for performing route guidance and outputs this to the speaker 15.

  In addition, the arithmetic processing device 1 generates probe data indicating the vehicle state. Specifically, the arithmetic processing device 1 generates probe data using other devices and sensors mounted on the navigation device 100 and predetermined information acquired from the vehicle, and moves the moving image via the data transmission / reception device 26. It transmits to the information providing server 200.

  FIG. 6A is a diagram illustrating an example of the probe data 400. The probe data 400 includes a vehicle ID 401 for identifying the vehicle, date / time information 402 indicating the date and time when the probe data was generated, a link ID 403 of the link on which the vehicle was running or stopped when the probe data was generated, and the drive recorder 50. A moving image ID 404 for identifying the acquired moving image information, vehicle speed information 405, traveling lane information 406, weather information 407, and vehicle type information 408 are recorded. Such probe data 400 is also attribute information indicating the attribute of the moving image information at the same time as indicating the vehicle state. Such probe data 400 is generated regularly (for example, every second) by the arithmetic processing device 1.

  FIG. 6B is a diagram in which the moving image information acquired from the drive recorder 50 and the moving image ID 404 are associated with each other. The arithmetic processing device 1 acquires moving image information from the drive recorder 50 every time one piece of probe data 400 is generated, that is, every second. As will be described later, one piece of moving image information includes, for example, a predetermined number (for example, five frames) of still image information. The arithmetic processing apparatus 1 associates one moving image ID 404 with one piece of moving image information including five frames of still image information per second.

  In addition, the arithmetic processing apparatus 1 acquires moving image information (hereinafter referred to as “route moving image information”) along a route requested by the user (hereinafter referred to as “requested route”) from the moving image information providing server 200, and Run the simulation process.

  The arithmetic processing unit 1 includes a CPU 2 (Central Processing Unit) that executes various processes such as numerical calculations and control of each device and sensor, a RAM 3 that temporarily stores programs, data, calculation results, and the like. ROM 4 (Read Only Memory) for storing data and data, and an I / F (interface) 5 for connecting various types of hardware to the arithmetic processing unit. The CPU 2, RAM 3, and ROM 4 are connected to each other by a bus 6.

  Returning to FIG. 2, the description of the navigation device 100 will be continued. The display 10 is a unit that displays graphics information generated by the arithmetic processing device 1 in a display area. The display 10 is composed of, for example, a liquid crystal display, an organic EL display, or the like.

  The storage device 11 is composed of at least a readable / writable recording medium such as an HDD (Hard Disk Drive) or a nonvolatile memory card. The storage device 11 stores, for example, map information 12, traffic information, route information, section information, dictionary information, and the like used for the navigation function. The map information 12 includes link information, which is information related to roads on the map, and the information includes region information for each region (for example, mesh region) obtained by dividing a predetermined region on the map into a plurality of sections. Stored in Further, the map information has point coordinates indicated by XY coordinates in order to uniquely identify each point on the map.

  FIG. 5 is a diagram showing the area information 500. The area information 500 is information including link information 503 included in each area on the map. The link means, for example, a road connecting nodes such as an intersection. In the link information 503, information on the road is registered.

  The area information 500 includes, for each mesh ID 501 for identifying an area on the map, a road link ID 502 included in each mesh and link information 503 associated with each link ID 502. In the link information 503, start point and end node point coordinates 504 indicating both ends of a road, road type information 505 indicating a road type such as a general road, a toll road, a national road, and a prefectural road, and a road name are registered. Road name information 506, link length information 507 indicating the length of the road, travel time information 508 indicating the time required to pass through the road, and other roads connected to each of the start node and end node of the road Start link / end link information 509 in which the link ID is registered, and lane number information 510 indicating the number of lanes of the link.

  The storage device 11 stores route moving image information acquired from the moving image information providing server 200.

  The storage device 11 stores white line pattern information (not shown) for identifying a white line on the road. As will be described later, the white line pattern information is used for pattern matching processing for identifying a white line on a road.

  Returning to FIG. 2 again, the description of the navigation device 100 will be continued. The voice input / output device 13 includes a microphone 14 as a voice input device and a speaker 15 as a voice output device. The microphone 14 collects an external sound of the navigation device 100 such as a voice uttered by the user. The speaker 15 outputs a message to the user generated by the arithmetic processing device 1 as an audio signal.

  The input device 16 is a device for the navigation device 100 to receive a predetermined instruction from the user. Specifically, it is composed of a direction key 17, a dial switch 18, a touch panel 19, and the like.

  The ROM device 20 includes at least a readable recording medium such as a ROM (Read Only Memory) such as a CD-ROM or a DVD-ROM, or an IC (Integrated Circuit) card. For example, still image information, audio information, and the like are recorded on this recording medium.

  The vehicle speed sensor 21, the gyro sensor 22, and the GPS receiver 23 are used to detect the current location of the vehicle on which the navigation device 100 is mounted.

  The vehicle speed sensor 21 outputs information used for calculating the vehicle speed. Specifically, the vehicle speed sensor 21 converts the detected rotation speed of the wheel into a pulse signal, and outputs predetermined information such as the number of pulse signals within a predetermined time.

  The gyro sensor 22 is configured by an optical fiber gyro, a vibration gyro, or the like, and detects an angular velocity due to the rotation of the moving body.

  The GPS receiver 23 receives a signal from a GPS satellite, and measures the distance between the vehicle and the GPS satellite and the rate of change of the distance with respect to three or more satellites. Measure the heading.

  The FM multiplex broadcast receiver 24 receives an FM multiplex broadcast signal sent from an FM broadcast station. FM multiplex broadcasting includes VICS (Vehicle Information Communication System) information outline current traffic information, regulatory information, SA / PA (service area / parking area) information, parking lot information, weather information, etc. Information includes text information provided by radio stations.

  The beacon receiving device 25 receives rough current traffic information such as VICS information, regulation information, SA / PA (service area / parking area) information, parking lot information, weather information, emergency alerts, and the like. For example, it is a receiving device such as an optical beacon that communicates by light and a radio beacon that communicates by radio waves.

  The data transmission / reception device 26 transmits / receives predetermined data to / from an external device other than the navigation device 100. For example, the data transmitting / receiving device 26 transmits the probe data 400 and the moving image information acquired from the arithmetic processing device 1 to the moving image information providing server 200. Further, the data transmitting / receiving device 26 receives the route moving image information from the moving image information providing server 200.

  FIG. 3 is a diagram showing a schematic configuration of the drive recorder 50. The drive recorder 50 is a device that is mounted on a vehicle and generates moving image information that is a video imaged from the viewpoint of the driver. The drive recorder 50 includes an arithmetic processing device 51, an imaging device 52, a storage device 53, and an I / F (interface) 54. Each of these devices is connected to each other by a bus 55 so that data can be exchanged.

  The arithmetic processing unit 51 is a central unit that performs various processes of the drive recorder 50. Specifically, the arithmetic processing device 51 controls the imaging device 52 to generate moving image information including a predetermined number (for example, five frames) of still image information within a predetermined time (for example, one second). In addition, the arithmetic processing device 51 outputs the generated moving image information to the storage device 53.

  The arithmetic processing unit 51 includes a CPU 56 (Central Processing Unit) that executes various processes such as numerical calculation and control of each device and sensor, a ROM 57 (Read Only Memory) that stores programs and data, a program, And a RAM 58 for temporarily storing data, calculation results, and the like. The CPU 56, ROM 57, and RAM 58 are connected to each other by a bus 59.

  The imaging device 52 includes, for example, an imaging element such as a charge-coupled device (CCD) and a lens, and shoots a subject reflected on the lens based on the control of the arithmetic processing device 51. The imaging device is installed near the driver's seat in the vehicle, for example, with the lens facing in the forward direction of the vehicle.

  The storage device 53 is configured by at least a readable / writable recording medium such as an HDD (Hard Disk Drive) or a nonvolatile memory card. The storage device 53 stores moving image information for a predetermined time taken by the imaging device 52.

  The I / F (interface) 54 electrically connects the drive recorder 50 and another device (for example, the navigation device 100), and enables data communication with each other. The drive recorder 50 is connected to the navigation apparatus 100 via the I / F 54 and transmits the generated moving image information.

  FIG. 4 is a diagram illustrating a schematic configuration of the moving image information providing server 200. The moving image information providing server 200 executes various processes in response to a request from the user, and provides the generated information to the user. As illustrated, the moving image information providing server 200 includes an arithmetic processing device 201, a data transmission / reception device 202, and a storage device 203. Each of these devices is connected to each other via a bus 204 so that data can be exchanged.

  The arithmetic processing device 201 is a central unit that performs various processes of the moving image information providing server 200. For example, the arithmetic processing unit 201 generates information related to a search for a recommended route, a recommended spot, and the like in response to a request from a user via a travel planning site (“Chizuru and Susumu” provided by Clarion Co., Ltd.). In addition, the arithmetic processing device 201 transmits the generated information to the user terminal 300 via the data transmission / reception device 202.

  In addition, the arithmetic processing device 201 performs processing on the moving image information acquired from the navigation device 100 or the user terminal 300. Specifically, the arithmetic processing unit 201 performs a masking process on the license plate of another vehicle shown in the video information.

  In addition, the arithmetic processing device 201 generates route moving image information in response to a request from the user. Specifically, the arithmetic processing unit 201 generates route moving image information using moving image information specified by the probe data 400.

  The data transmission / reception device 202 is a device for transmitting / receiving predetermined data to / from an external device other than the moving image information providing server 200. Specifically, the data transmission / reception device 202 acquires probe data 400 and moving image information from the navigation device 100 and the user terminal 300. Further, the data transmission / reception device 202 receives a route moving image information acquisition request signal from the navigation device 100 or the user terminal 300. Further, the data transmission / reception device 202 transmits the generated route moving image information to the navigation device 100 or the user terminal 300.

  The arithmetic processing unit 201 includes a CPU 205 (Central Processing Unit) that executes various processes such as numerical calculation and control of each device and sensor, a ROM 206 (Read Only Memory) that stores programs and data, a program, And a RAM 207 for temporarily storing data, calculation results, and the like. The CPU 205, ROM 206, and RAM 207 are connected to each other via a bus 208.

  The storage device 203 is a device for storing predetermined information. The storage device 203 is configured by at least a readable / writable recording medium such as an HDD (Hard Disk Drive) or a nonvolatile memory card. The storage device 203 stores, in addition to map information and traffic information used for route search, probe data 400 and moving image information acquired from the navigation device 100 and the user terminal 300.

  Further, the storage device 203 stores plate pattern information (not shown) for identifying the license plate of the vehicle. Here, the plate pattern information is information in which the shape of the license plate expressed from various dimensions and angles is recorded. As will be described later, the plate pattern information is used in a pattern matching process for identifying a license plate of a vehicle shown in the video information.

  The user terminal 300 is assumed to be a personal computer having normal functions such as displaying information on a website and executing arithmetic processing. That is, such a user terminal 300 has at least an I / O for connecting a display, an input device for a user to input predetermined information, and a predetermined recording medium (for example, a removable recording medium). F, and browser software capable of browsing a website need only be installed.

  Note that the user terminal 300 acquires the moving image information and the probe data 400 acquired by the navigation device 100 from a removable recording medium or the like, and transmits them to the moving image information providing server 200. Therefore, for example, even in the navigation device 100 that does not include the data transmitting / receiving device 26, the moving image information and the probe data 400 can be transmitted to the moving image information providing server 200 via the user terminal 300.

  In addition, when the user terminal 300 acquires the route moving image information from the moving image information providing server 200, the user terminal 300 reproduces the moving image information and displays a video showing the requested route on the display.

  Next, functional blocks of the navigation device 100, the drive recorder 50, and the moving image information providing server 200 according to the present embodiment will be described. The functional blocks of the navigation device 100, the drive recorder 50, and the moving image information providing server 200 execute predetermined programs read by the CPUs 2, 56, and 205 installed in the respective arithmetic processing devices 1, 51, and 201. It is constructed by. Therefore, each ROM 4, 57, 206 stores a program for executing processing of each functional unit.

  Further, the functional blocks of the navigation device 100, the drive recorder 50, and the moving image information providing server 200 are provided to facilitate understanding of the functions of the navigation device 100, the drive recorder 50, and the moving image information providing server 200 realized in the present embodiment. These are classified according to the main processing contents. Further, the present invention is not limited by the classification method of each function or its name. Each configuration of the navigation device 100, the drive recorder 50, and the moving image information providing server 200 can be classified into more components depending on the processing content. Moreover, it can also classify | categorize so that one component may perform more processes.

  Further, the functional units of the navigation device 100, the drive recorder 50, and the moving image information providing server 200 may be constructed by hardware (such as ASIC). Further, the processing of each functional unit may be executed by one hardware or may be executed by a plurality of hardware.

  FIG. 7 is a diagram showing functional blocks of the drive recorder 50. The drive recorder 50 includes an information control unit 601 and a moving image information generation unit 602.

  The information control unit 601 is a central functional unit that performs various processes of the drive recorder 50. The information control unit receives predetermined information and instructions from other functional units, a device built in the drive recorder 50, an external device, and the like. The information control unit outputs the acquired information and the received instruction to a predetermined functional unit or device according to the type or content of the information or instruction.

  Further, the information control unit 601 synchronizes with the navigation device 100, and at the timing when one probe data 400 is generated by the navigation device 100, one moving image information, that is, five frames of still images per second. The moving image information generation unit 602 is controlled so as to generate moving image information including information.

  When the information control unit 601 receives a moving image information acquisition request from the navigation device 100, the information control unit 601 transmits the moving image information to the navigation device 100 via the I / F 54.

  The moving image information generation unit 602 is a functional unit that generates moving image information. Specifically, the moving image information generation unit 602 controls the imaging device 52 to generate moving image information including still image information of a predetermined number of frames (for example, 5 frames) within a predetermined time (for example, 1 second). Generate. Note that the moving image information generation unit 602 delivers the generated moving image information to the information control unit 601.

  Next, functional blocks of the navigation device 100 will be described. FIG. 8 is a diagram showing functional blocks of the navigation device 100. The navigation device 100 includes an information control unit 701, a route search unit 702, a probe data generation unit 703, and a simulation unit 704.

  The information control unit 701 is a central functional unit that performs various processes of the navigation device 100. The information control unit 701 receives predetermined information and instructions from other functional units, other devices built in the navigation device 100, sensors, and external devices. Further, the information control unit 701 outputs the acquired information and the received instruction to a predetermined sensor, device, or function unit according to the type or content of the information or instruction.

  Further, the information control unit 701 is synchronized with the information control unit 601 of the drive recorder 50 and includes a predetermined number (for example, 5 frames) of still image information at the timing when one probe data 400 is generated. A predetermined signal is output to the information control unit 601 of the drive recorder 50 so as to transmit one piece of moving picture information.

  In addition, the information control unit 701 receives a request for acquiring route moving image information from the user, and generates a route moving image information request signal including link information constituting the requested route. Specifically, when the information control unit 701 receives an acquisition request for route moving image information from the user, the information control unit 701 outputs an instruction to generate information about the requested route to the route search unit 702. In addition, when the information control unit 701 acquires information about the requested route from the route search unit 702, the information control unit 701 outputs the information to the moving image information providing server 200 via the data transmission / reception device 26.

  In addition, the information control unit 701 performs graphic conversion on predetermined information and outputs it to the display 10. In addition, when the information control unit 701 receives a request for obtaining the moving image information from the user, the information control unit 701 performs graphics conversion of information for inputting the departure place and the destination of the requested route, and the departure time zone, and outputs the converted information to the display 10. .

  The route search unit 702 is a functional unit that searches for a route that connects a current location or a specified departure location to a destination. For example, the route search unit 702 searches for the recommended route with the minimum cost that connects the current location or the departure location received from the user and the destination using the Dijkstra method. Further, the route search unit 702 outputs information related to the searched recommended route to the information control unit 701.

  In addition, when receiving an instruction to generate information on the requested route, the route search unit 702 executes a requested route search process using information indicating the departure place, the destination, and the departure time zone specified by the user. Further, the route search unit 702 outputs information related to the searched request route to the information control unit 701.

  Further, the route search unit 702 specifies the current location of the vehicle at a predetermined timing (for example, every second). Specifically, the route search unit 702 acquires information output from the GPS receiver 23, the vehicle speed sensor 21, and the gyro sensor 22, and specifies the current location of the vehicle by converting the information into coordinate information on a map. . In addition, the route search unit 702 specifies the link ID 502 of the link on which the vehicle is running or stopped using the coordinate information of the specified current location.

  The probe data generation unit 703 is a functional unit that generates probe data 400 indicating the vehicle state. For example, the probe data generation unit 703 generates probe data 400 using information acquired from various sensors of the navigation device 100, other devices, and external devices.

  The simulation unit 704 is a functional unit that provides a virtual driving simulation function along the requested route using the route moving image information stored in the storage device. The simulation unit 704 provides a predetermined simulation function by linking the accelerator / brake operation / handle operation of the user with the reproduction speed of the route moving image information.

  Next, functional blocks of the moving image information providing server 200 will be described. FIG. 9 is a diagram illustrating functional blocks of the moving image information providing server 200. The moving image information providing server 200 includes an information control unit 801, a website providing unit 802, and a moving image information processing unit 803.

  The information control unit 801 is a central functional unit that performs various processes of the moving image information providing server 200. The information control unit 801 receives predetermined information and instructions from other functional units, other devices built in the moving image information providing server 200, and external devices. Further, the information control unit 801 outputs the acquired information and the received instruction to a predetermined device or function unit according to the type or content of the information or instruction.

  The website providing unit 802 is a functional unit that provides a travel planning site to the user. Further, the website providing unit 802 generates information according to a request received from the user through the site. Specifically, upon receiving a route search request from the user through the travel planning site, the website providing unit 802 searches for a route connecting from the designated departure point to the destination. In addition, the website providing unit 802 transmits the searched recommended route to the user terminal 300 via the data transmission / reception device 202.

  In addition, the website providing unit 802 receives a request for acquisition of route moving image information from the user, and generates a route moving image information request signal including link information constituting the requested route. Specifically, when the website providing unit 802 receives an acquisition request for route moving image information from the user, the website providing unit 802 outputs information for inputting the departure and destination of the requested route and a departure time zone to the user terminal 300. .

  In addition, the website providing unit 802 executes a request route search process using information indicating a departure place, a destination, and a departure time zone specified by the user. Also, the website providing unit 802 outputs a route moving image information request signal including information regarding the searched request route to the moving image information processing unit 803.

  The moving image information processing unit 803 is a functional unit that processes moving image information. For example, the moving image information processing unit 803 performs a masking process on the license plate of the vehicle shown in the moving image information image acquired from the navigation device 100 or the user terminal 300.

  The moving image information processing unit 803 is a functional unit that generates route moving image information. Specifically, the moving image information processing unit 803 extracts the link ID 502 of the link constituting the requested route from the route moving image information request signal acquired from the navigation device 100 or the user terminal 300. Further, the moving image information processing unit 803 specifies moving image information necessary for generating route moving image information, using the extracted link ID 502 and the probe data 400 stored in the storage device 203. The moving image information processing unit 803 generates route moving image information along the requested route by connecting the specified moving image information.

  Also, the moving image information processing unit 803 transmits the generated route moving image information to the navigation device 100 or the user terminal 300 via the data transmission / reception device 202.

  [Description of Operation] Next, the moving image information generation process executed by the drive recorder 50 will be described. Note that the moving image information generation process is started when the drive recorder 50 is activated.

  The moving image information generation unit 602 controls the imaging device 52 to generate moving image information including a predetermined number (for example, 5 frames) of still image information within a predetermined time (for example, 1 second). In addition, the moving image information generation unit 602 outputs the generated moving image information to the storage device 53. Note that the moving picture information generation unit 602 repeatedly executes such moving picture information generation processing while the drive recorder 50 is activated.

  Next, probe data generation processing executed by the navigation device 100 will be described. FIG. 10 is a flowchart showing such processing. The probe data generation process is started when the navigation device 100 is activated, and is periodically (for example, every second) by the probe data generation unit 703 while the navigation device 100 is activated.

  When the navigation device 100 is activated, the probe data generation unit 703 acquires information indicating the vehicle state (step S001). Specifically, the probe data generation unit 703 acquires a predetermined identifier that uniquely identifies the vehicle on which the navigation device 100 is mounted. Such vehicle ID 401 should just be unique ID produced | generated from the combination of a vehicle number and the serial number of the navigation apparatus 100, for example.

  The probe data generation unit 703 acquires date information 402 from a timer (not shown) built in the navigation device 100.

  In addition, the probe data generation unit 703 acquires the link ID 403 of the link on which the vehicle is running or stopped. Specifically, the probe data generation unit 703 acquires the link ID 403 specified from the point coordinates indicating the current location from the route search unit 702.

  In addition, the probe data generation unit 703 obtains vehicle speed information 405 calculated based on predetermined information output from the vehicle speed sensor 21.

  In addition, the probe data generation unit 703 identifies the travel lane 406 of the vehicle. Specifically, the probe data generation unit 703 uses the white line pattern information stored in the storage device 11 and the moving image information acquired from the drive recorder 50 to identify the traveling lane 406 by pattern matching processing.

  In the pattern matching process, when a white line matching the white line pattern information is detected on the left side of the vehicle, the probe data generation unit 703 specifies that the vehicle is traveling in the right lane. On the other hand, when a white line matching the white line pattern information is detected on the right side of the vehicle, the probe data generation unit 703 specifies that the vehicle is traveling in the left lane. In addition, when a white line that matches the white line pattern is detected on both sides of the vehicle, the probe data generation unit 703 refers to the lane information of the map information 12, and when the vehicle is traveling on a link with three lanes, Identify driving on the middle road. Such white line position may be detected by using a conventional technique such as pattern matching.

  In addition, the probe data generation unit 703 acquires the weather information 407 from the VICS information received by the FM multiplex broadcast receiving device 24 and the VICS information received by the beacon receiving device 25.

  Further, the probe data generation unit 703 specifies the vehicle type information 408. Specifically, the probe data generation unit 703 acquires the vehicle type information 408 of the vehicle on which the navigation device 100 such as a sedan or SUV is mounted from the storage device 11 or the like.

  When the predetermined information indicating the vehicle state is acquired (step S001), the probe data generation unit 703 acquires moving image information from the drive recorder 50 (step S002). Specifically, the probe data generation unit 703 acquires moving image information after a predetermined time (for example, 1 second) has elapsed from the reference time, with the startup time of the navigation device as the reference time. Note that the moving image information includes a predetermined number (for example, five frames) of still image information captured during a predetermined time (for example, one second) from the reference time.

  When the moving image information is acquired (step S002), the probe data generation unit 703 generates a moving image ID 404 that uniquely identifies the moving image information, and outputs the moving image information to the storage device 11 in association with the moving image ID (step S003).

  When the moving image information in which the moving image ID 404 is associated with the moving image information is output to the storage device 11 (step S003), the probe data generation unit 703 includes predetermined information 401 to 403 and 405 to 408 indicating the vehicle state, the moving image ID 404, Is generated (step S004). Further, the probe data generation unit 703 outputs the generated probe data 400 to the storage device 11 and ends the probe data generation process.

  Such probe data generation processing (steps S001 to S004) is executed every second with the startup time of the navigation device 100 as a reference time.

  The generated probe data 400 and moving image information are transmitted to the moving image information providing server 200 via the data transmitting / receiving device 26. Further, for example, the generated probe data 400 and moving image information may be stored in a recording medium that can be attached and detached by the user and transmitted to the moving image information providing server 200 via the user terminal 300.

  Next, the moving image information accumulation process executed by the moving image information providing server 200 will be described. FIG. 11 is a flowchart of such processing. The moving image information accumulation process is started when the moving image information providing server 200 is activated.

  The moving image information processing unit 803 performs a masking process on the license plate of the vehicle reflected in the moving image information acquired from the navigation device 100 or the user terminal 300 (step S011). In the masking process, the moving image information processing unit 803 uses the license plate pattern information stored in the storage device 203, for example, to specify the position of the license plate of the vehicle shown in the video by the pattern matching process. Then, the moving image information processing unit 803 performs a masking process on the identified license plate. In order to detect the position of the license plate, a conventional technique such as pattern matching may be used.

  After performing the masking process (step S011), the moving image information processing unit 803 outputs the moving image information to the storage device 203 (step S012), and returns the process to step S011. Thus, the moving image information providing server 200 performs predetermined processing on the moving image information acquired from the navigation device 100 or the user terminal 300, and repeatedly executes processing for storing the processed moving image information in the storage device 203.

  Next, route moving image information generation processing will be described. FIG. 12 is a flowchart showing such processing. The route moving image information generation process is started when the moving image information providing server 200 is activated.

  The moving image information processing unit 803 determines whether a route moving image information request signal has been received (step S021). Specifically, the moving image information processing unit 803 determines whether a route moving image information request signal has been received from the navigation device 100 or from a travel plan site provided to the user terminal 300.

  When the route moving image information request signal is received (Yes in step S021), the moving image information processing unit 803 acquires the link ID 502 of the link constituting the requested route from the signal (step S022). On the other hand, when the route moving image information request signal has not been received (No in step S021), the moving image information processing unit 803 repeatedly executes the process in step S021.

  When the link ID 502 of the link constituting the request route is acquired (step S022), the moving image information processing unit 803 generates route moving image information (step S023). Details of this processing will be described with reference to FIG.

  FIG. 13 is a flowchart showing details of the process in step S023. First, the moving image information processing unit 803 extracts the probe data 400 in which the link ID 502 of the link constituting the request route is recorded (step S031). Specifically, the moving image information processing unit 803 extracts from the storage device 203 the probe data 400 in which the same link ID 403 as each link of the requested route is recorded.

  Then, the moving image information processing unit 803 records a series of probe data 400 in which the same vehicle ID 401 is recorded from the extracted probe data 400 and generated at a predetermined time interval (for example, every one second). One probe data history, that is, a probe data history generated from the same vehicle that has traveled the link at a specific timing is specified.

  For example, FIG. 17 is a diagram showing a probe data history corresponding to a certain link. The moving picture information processing unit 803 specifies the probe data 400 in which the same vehicle ID 401 is recorded from the extracted probe data 400 and is generated at a predetermined time interval (for example, every one second). Classify as individual probe data history. As shown in the figure, for example, the group A, B, and C are probe data 400 in which the same vehicle ID 401 is recorded and generated at a predetermined time interval (1 second interval). In step 803, each of the groups A, B, and C is specified as a probe data history.

  When the probe data history is specified (step S031), the moving picture information processing unit 803 determines whether or not there is a probe data history in which a speed difference (for example, 30 km / h) is greater than or equal to a predetermined value in the same history. If it exists, the history is not used for the route moving image information generation process (step S032). This is because such probe data history indicates that a problem such as traffic jam has occurred during traveling of the corresponding link, and is not appropriate for use of route moving image information.

  In specifying the vehicle speed difference, the moving image information processing unit 803 compares the fastest value and the slowest value for each probe data history. When the difference between the two values is a speed difference greater than or equal to a predetermined value (for example, 30 km / h or more), the moving image information processing unit does not use the history for the route moving image information generation process. Also, the moving image information processing unit 803 deletes the probe data history and the corresponding moving image information from the storage device 203.

  Next, the moving image information processing unit 803 specifies the probe data history related to the continuous travel section (step S033). Here, the continuous travel section refers to a section of links in which the same vehicle travels continuously, that is, without passing through other links.

  The moving picture information processing unit 803 compares the probe data histories of adjacent links when specifying the continuous travel section. Specifically, the moving image information processing unit 803 specifies the latest date / time information 402 of the probe data included in the probe data history of one link (for example, the link closer to the departure place). In addition, the moving image information processing unit 803 specifies the oldest date / time information 402 of the probe data included in the probe data history of the other link adjacent to the link (the link far from the departure point). Then, when the two specified time differences are less than a predetermined value (for example, less than 2 seconds), the moving image information processing unit 803 specifies that these probe data histories relate to the continuous running section.

  On the other hand, when the time difference between the two is not less than a predetermined time (for example, 2 seconds or more), the moving picture information processing unit 803 does not relate these probe data histories to the continuous travel section (hereinafter referred to as “discontinuous travel section”). ).

  For example, FIG. 15 is a diagram illustrating a probe data history related to a continuous travel section. As shown in the figure, there are probe data histories A to E corresponding to links (1) to (5) constituting a predetermined route.

  Here, a section to which the same identification code is attached corresponds to a continuous travel section. For example, the probe data history A is associated with the link (1) and the link (2). This indicates that the probe data history A is a probe data history generated when a specific vehicle continuously travels on the link (1) and the link (2). Further, for example, the probe data histories B and C indicate that the probe data is generated when a specific vehicle continuously travels the links (2) to (4).

  Next, the moving image information processing unit 803 generates a predetermined number or more (for example, 5 sets or more) of combinations of probe data histories so that the discontinuous traveling sections are reduced (step S034). In the example of FIG. 15, “A-A-B-B-E”, “A-A-C-C-E”, “A-B-B-B-E”, “A-C-C-C-C”. The combination of probe data histories of “-E” is the combination with the fewest discontinuous travel sections (since there are two connection points each connecting the discontinuous travel sections).

  When the requested route includes a right turn link or a left turn link, the moving image information processing unit 803 specifies the probe data history in which the links before and after the node performing the right / left turn are continuous running sections. For example, in the example of FIG. 16, the moving image information processing unit 803 specifies the probe data history B in which the link (6) and the link (7) before and after the node α are continuous running sections. Then, the moving image information processing unit 803 uses B for the probe data history of the link before and after the node α, and generates a combination of the probe data history so that the discontinuous traveling sections are reduced in the links at both ends. To do.

  Next, the moving image information processing unit 803 performs weighting by adding points according to the conditions of the generated combination of probe data histories.

  First, the moving image information processing unit 803 performs weighting by adding a predetermined point for each combination according to the number of connection points connecting discontinuous travel sections (step S041). For example, in the example of FIG. 15, there are two connection points of five or more generated combinations. Therefore, in this case, the moving image information processing unit 803 adds a point obtained by multiplying a predetermined point (for example, 10 points) by 2 as the number of connection points to each combination.

  Next, in the probe data history before and after the connection point, the moving image information processing unit 803 performs weighting by adding a predetermined point to a combination in which the vehicle speed difference is greater than or equal to a predetermined value (for example, 10 km / h) (step S042). Specifically, the moving image information processing unit 803 records the latest date / time information 402 out of the probe data 400 included in the probe data history corresponding to one link (for example, the link closer to the departure place). The vehicle speed 405 of the obtained probe data 400 is specified. In addition, the moving image information processing unit 803 records the oldest date / time information 402 in the probe data 400 included in the probe data history of the other link adjacent to the link (for example, the link far from the departure point). The vehicle speed 405 of the obtained probe data 400 is specified.

  Then, when these vehicle speed differences are larger than a predetermined value (for example, 10 km / h or more), the moving image information processing unit 803 gives a predetermined point (for example, 10 points) to the combination having such connection points. to add. For example, when there are two connection points where a speed difference of 10 km / h or more occurs, the moving image information processing unit 803 adds 20 points to the combination.

  Next, the moving image information processing unit 803 performs weighting by adding a predetermined point to a combination that is not traveling in the same lane before and after the connection point (step S043). Specifically, in the moving image information processing unit 803, the latest date / time information 402 is recorded in the probe data 400 included in the probe data history of one link (for example, the link closer to the departure place). The travel lane 406 of the probe data is specified. In addition, the moving image information processing unit 803 records the oldest date / time information 402 in the probe data 400 included in the probe data history of the other link adjacent to the link (for example, the link far from the departure point). The travel lane 406 of the probe data 400 is specified.

  Then, when these lanes do not match, the moving image information processing unit 803 adds a predetermined point (for example, 10 points) to the combination having the connection point. For example, when there are two connection points where the traveling lanes do not match, the moving image information processing unit 803 adds 20 points to the combination.

  Next, the moving image information processing unit 803 stores the travel date and time of each link (hereinafter referred to as “scheduled travel date and time”) included in the route moving image information acquisition request signal and the probe data history corresponding to the links constituting each combination. Weighting is performed by adding a predetermined point in accordance with the deviation from the date / time information 402 of the included probe data 400 (step S044). Specifically, the moving image information processing unit 803 divides the scheduled travel date / time of each link from the date / time information 402 of the probe data 400 included in the probe data history based on each element of the month range, the day range, and the time range. Determine the degree of.

  Here, the month range is January to March, April to June, July to September, and October to December. In addition, the day range is 1 to 9 days, 10 to 19 days, and 20 to 31 days. In addition, the time range is from 0 o'clock to 2 o'clock, 3 o'clock to 5 o'clock, 6 o'clock to 8 o'clock, 9 o'clock to 11 o'clock, 12 o'clock to 14 o'clock, 15 o'clock to The time range is 17:00, 18: 00-20: 00, and 21: 00-23: 00.

  When determining the degree of divergence, the moving image information processing unit 803 specifies the scheduled travel date and time of each link included in the requested route from the route moving image information acquisition request signal. Specifically, the moving image information processing unit 803 specifies the scheduled travel date and time for each link. In addition, the moving image information processing unit 803 specifies the date / time information 402 of the probe data 400 included in the probe data history corresponding to the links constituting the request route. Then, the moving picture information processing unit 803 compares the scheduled traveling date and time with the date and time information 402 of the probe data 400 included in the probe data history for each link.

  In comparison, the moving image information processing unit 803 determines whether the date / time information 402 of the probe data 400 included in the probe data history is included in each of the month range, the day range, and the time range of the scheduled travel date and time. To do. When the date information 402 of the probe data 400 is not included in each range of the scheduled date and time, the moving image information processing unit 803 adds a predetermined point (3 points) to the combination having the probe data 400.

  For example, when there is probe data 400 in which all of the month range, the day range, and the time range are not included in each range of the scheduled travel date and time, the moving image information processing unit 803 has a probe data history including the probe data 400. Add 9 points to the combination. Further, for example, when there is probe data 400 in which only the month range and the day range are not included in the range of the scheduled travel date and time, the moving image information processing unit 803 adds 6 to the combination having the probe data history including the probe data 400. Add points.

  For example, the moving image information processing unit 803 adds 18 points to a combination having two probe data histories including the probe data 400 not included in each range of the scheduled travel date and time.

  Next, the moving image information processing unit 803 performs weighting by adding a predetermined point when the weather information 407 is different in the probe data history before and after the connection point (step S045). Specifically, the moving image information processing unit 803 has the weather information of the probe data 400 in which the latest date / time information 402 is recorded in the probe data history of one link (for example, the link closer to the departure place). 407 is specified. In addition, the moving image information processing unit 803 includes the probe data 400 in which the oldest date / time information 402 is recorded in the probe data history of the other link adjacent to the link (for example, the link far from the departure point). The weather information 407 is specified.

  Then, when the weather information 407 of the two is different, the moving image information processing unit 803 adds a predetermined point (for example, 5 points) to the combination having the connection point. For example, when “sunny” is recorded in the latest probe data 400 of one link and “rain” is recorded in the oldest probe data 400 of the other link adjacent thereto, the moving picture information processing unit 803 Add 5 points to this combination. For example, when there are two such mismatching connection points, the moving image information processing unit 803 adds 10 points to such a combination.

  Next, the moving image information processing unit 803 performs weighting by adding a predetermined point when the vehicle type information 408 is different in the probe data history before and after the connection point (step S046). Specifically, the moving image information processing unit 803 includes the vehicle type information of the probe data 400 in which the latest date / time information 402 is recorded in the probe data history of one link (for example, the link closer to the departure place). 408 is specified. In addition, the moving image information processing unit 803 includes the probe data 400 in which the oldest date / time information 402 is recorded in the probe data history of the other link adjacent to the link (for example, the link far from the departure point). The vehicle type information 408 is specified.

  Then, when the vehicle type information 408 is different, the moving image information processing unit 803 adds a predetermined point (for example, 3 points) to the combination having the connection point. For example, when “sedan” is recorded in the latest probe data 400 of one link and “SUV” is recorded in the oldest probe data 400 of the other link adjacent to the link, the moving image information processing unit 803 Adds 3 points to such a combination. For example, when there are two such mismatched links, the moving image information processing unit 803 adds 6 points to the combination.

  Next, the moving image information processing unit 803 specifies the combination having the smallest added point (step S047). Specifically, the moving image information processing unit 803 calculates the sum of the added points, and specifies the combination having the smallest total points.

  Next, the moving image information processing unit 803 generates route moving image information using the specified probe data history (step S048). Specifically, the moving image information processing unit 803 acquires the moving image ID 404 from the probe data history of the combination having the smallest total points, and extracts moving image information in which the same moving image ID 404 is recorded from the storage device 203. Then, the moving image information processing unit 803 generates route moving image information along the requested route using the extracted moving image information (step S049).

  Note that the moving image information processing unit 803 records predetermined information in the generated route moving image information. Specifically, the moving image information processing unit 803 specifies the probe data history using the moving image ID 404 of each moving image information constituting the route moving image information, and specifies the corresponding link ID 403 and vehicle speed information 405 from the history. To do. Then, the moving image information processing unit 803 records the specified link ID 403 and vehicle speed information 405 in association with each moving image information. In addition, when there is a right / left turn link in the link constituting the route moving image information, the moving image information processing unit 803 records information indicating that in association with the link.

  Next, the moving image information processing unit 803 outputs the generated route moving image information to the data transmitting / receiving device 202 (step S024). The data transmission / reception device 25 transmits the route moving image information to the navigation device 100 or the user terminal 300.

  The route moving image information generation process according to the present embodiment has been described above. According to such a process, the moving image information accumulated in the moving image information providing server 200 can be connected more comfortably.

  Next, simulation processing executed by the navigation device 100 will be described. Simulation is virtual driving by a user. Specifically, it means that a user experiences a virtual driving by interlocking a steering operation, an accelerator, a braking operation of a vehicle, and route moving image information displayed on the display 10 of the navigation device 100.

  FIG. 18 is a diagram illustrating a connection state between the navigation device 100 and the vehicle control device 900 that controls various operations of the vehicle. As shown in the figure, the vehicle control device 900 includes a signal converter A that converts the depression amount of the accelerator 910 and the brake 911 into a predetermined signal, and a signal converter B that converts the steering angle of the handle 920 into a predetermined signal. , Is connected.

  For example, when a signal related to the depression amount of the accelerator 910 is acquired from the signal converter A, the vehicle control device 900 gives a predetermined instruction to the power source 930 of the vehicle so as to generate the acceleration specified by the acquired signal. Output.

  In addition, for example, when a signal related to the steering angle of the handle 920 is acquired from the signal converter B, the vehicle control device 900 causes the control device 940 to control the tire orientation so that the vehicle orientation specified by the acquired signal is obtained. A predetermined instruction is output.

  Note that a vehicle on which such a vehicle control device 900 is mounted is assumed to be a vehicle that can be realized, for example, without the accelerator 910 and the handle 920 being mechanically connected to the engine and tires. For example, such vehicles include electric vehicles (EV).

  The vehicle is also provided with a mode setting switch for setting a travel mode that is set when the vehicle travels and a simulation mode that performs a simulation travel using the navigation device 100.

  Here, the traveling mode is a mode set when the vehicle is traveling. Specifically, in the driving mode, the steering operation, the accelerator, and the braking operation are converted into predetermined signals, and an instruction specified by the signals is output to the power source 930 and the control device 940, thereby driving the vehicle. Control.

  On the other hand, in the simulation mode, a signal generated by a steering wheel operation, an accelerator, or a brake operation is not output to the vehicle power source 930 or the control device 940, but only to the navigation device 100.

  In such a simulation mode, when the user depresses the accelerator 910, the vehicle control device 900 generates an acceleration instruction signal corresponding to the depressing amount of the accelerator 910, and transmits this to the navigation device 100. When the user turns the handle 920, the vehicle control device 900 generates a steering angle instruction signal corresponding to the steering angle of the handle, and transmits this to the navigation device 100.

  Note that the vehicle control device 900 acquires a predetermined signal output from the mode setting switch, sets a travel mode or a simulation mode, and controls a signal output destination.

  The mode setting may be realized by a setting on the navigation device 100 side. Specifically, the arithmetic processing unit 1 of the navigation device 100 connected to the vehicle control device 900 via the I / F 5 acquires a control signal indicating a handle operation, an accelerator operation, or the like, and sends this to the navigation device 100 side. May be output only.

  Next, simulation processing will be described. The simulation process is executed by the simulation unit of the navigation device 100. The simulation unit executes a predetermined simulation process based on the route moving image information acquired from the moving image information providing server 200 and the signals indicating the accelerator, brake operation, and steering wheel operation acquired from the vehicle control device 900.

  The information control unit 701 of the navigation device 100 stores the route moving image information acquired from the moving image information providing server 200 in a recording medium such as the storage device 11. Moreover, the simulation part 704 will start a simulation process, if the signal which shows that the simulation mode was selected is acquired from the vehicle control apparatus 900. FIG.

  The simulation unit 704 changes the reproduction speed of the route moving image information displayed on the display 10 of the navigation device 100 according to the signal acquired from the vehicle control device 900. For example, when reproducing the route moving image information in which the vehicle speed information at a speed of 50 km / h is recorded, when the vehicle speed specified by the acceleration instruction signal acquired from the vehicle control device 900 is 60 km / h, the simulation unit 704 gradually changes the reproduction speed of the route moving image information, and finally reproduces it at 1.2 times speed. As a result, the route moving image information displayed on the display 10 is displayed as if traveling at a vehicle speed of 60 km / h.

  Similarly, when the route moving image information in which the vehicle speed information at the speed of 50 km / h is recorded is reproduced, the vehicle speed specified by the acceleration instruction signal acquired from the vehicle control device 900 from the vehicle control device 900 is 70 km / h. In the case of h, the simulation unit 704 gradually changes the reproduction speed of the route moving image information, and finally reproduces it at 1.4 times speed. As a result, the route moving image information displayed on the display 10 is displayed as if traveling at a vehicle speed of 70 km / h.

  Further, when the simulation unit 704 approaches a right turn and a left turn, the simulation unit 704 determines whether or not a vehicle speed instruction signal acquired from the vehicle control device 900 indicates a vehicle speed that is lower than a predetermined value (for example, 10 km / h or lower). Specifically, the simulation unit 704 determines whether or not the link being reproduced is a right / left turn link from information indicating the right / left turn link recorded in the route moving image information.

  When the vehicle position being reproduced is a right / left turn link, the simulation unit 704 includes a predetermined number (for example, five) of moving image information in which new date and time information 402 is recorded among the moving image information having the link ID 403 of the link. It is determined whether or not the acceleration instruction signal acquired during the reproduction of the signal is a signal indicating a vehicle speed of a predetermined value or less (for example, 10 km / h or less).

  If the acceleration instruction signal indicates a vehicle speed equal to or lower than a predetermined value, the simulation unit 704 determines whether or not the steering angle instruction signal has been acquired from the vehicle control device 900. When the steering angle instruction signal is acquired, the simulation unit 704 changes the reproduction speed of the route moving image information so as to be the vehicle speed specified by the acquired signal, and continues the reproduction of the route moving image information. At this time, the route moving image information for turning right or left at a predetermined speed or less is reproduced on the display.

  On the other hand, when the acquired acceleration instruction signal is not at a predetermined speed or less, the simulation unit 704 stops the reproduction of the route moving image information. Further, even when the acquired acceleration instruction signal has a speed equal to or lower than a predetermined speed, if the steering angle instruction signal is not acquired, the simulation unit 704 stops the reproduction of the route moving image information.

  The invention according to this embodiment has been described above. According to the present invention, collected video information can be used more efficiently. Further, according to the present invention, it is possible to generate and provide route moving image information with less discomfort. Further, in the present invention, moving image information with less sense of incongruity can be used for driving simulation.

  In addition, in the present invention, it is possible to provide moving image information that is captured at a date and time that is relatively not deviated from the specified date and time. You can check the situation (such as traffic conditions and construction) through videos.

  The present invention is not limited to the embodiment described above. For example, in the first modification of the above-described embodiment, the image quality, luminance, and saturation of moving image information are taken into account when generating route moving image information.

  In the invention according to the first modification, information indicating image quality, luminance, and saturation is recorded in the probe data 400. That is, the drive recorder 50 transmits the moving image information and information regarding the image quality, luminance, and saturation of the moving image information to the navigation device 100. Note that such image quality information, luminance information, and saturation information only need to be given a predetermined rank (for example, ranks 1, 2, 3,...) According to the quality.

  Then, the moving image information providing server 200 performs weighting in consideration of information on the image quality, luminance, and saturation of the moving image information when generating the route moving image information. Specifically, in the moving image information providing server 200, the latest date / time information 402 is recorded in the probe data 400 included in the probe data history of one link (for example, the link closer to the departure place). Specify the image quality information (or brightness and saturation) of the probe data. In addition, the moving image information providing server 200 records the oldest date / time information 402 among the probe data 400 included in the probe data history of the other link adjacent to the link (for example, the link far from the departure place). The image quality information (or luminance and saturation) of the probe data 400 is specified.

  Then, when the ranks of the image quality information do not match, the moving image information providing server 200 adds a predetermined point (for example, 10 points) to the combination having the connection point. For example, when there are two connection points where the ranks of the image quality information do not match, the moving image information providing server 200 adds 20 points to the combination.

  According to the invention according to the first modified example, it is possible to provide route moving image information with a more uncomfortable feeling even with route moving image information having discontinuous travel sections.

  In the invention according to the second modified example, the moving image information corresponding to the discontinuous travel section is subjected to processing for eliminating the uncomfortable feeling. Specifically, the moving image information providing server 200 performs a morphing process.

  For example, between the moving image information corresponding to one link of the discontinuous travel section and the moving image information corresponding to the other link, the viewpoint shift, shooting time, shooting date, weather caused by the installation position of the drive recorder 50 Differences in video due to differences, differences in image quality, luminance, saturation, and the like due to differences in the type of the installed drive recorder 50 occur. In the invention according to the second modification, these different elements are complemented by the moving image information providing server 200 (morphing process), and the moving image information image corresponding to one link is changed to the moving image information image corresponding to the other link. Process the video information so that it changes naturally.

  According to the invention according to the second modified example, it is possible to provide route moving image information with very little discomfort even with route moving image information having discontinuous travel sections.

100 ... navigation device 100, 1 ... arithmetic processing device,
DESCRIPTION OF SYMBOLS 10 ... Display, 11 ... Memory | storage device, 13 ... Voice input / output device 16 ... Input device, 20 ... ROM device, 21 ... Vehicle speed sensor,
22 ... Gyro sensor, 23 ... GPS receiver,
24 ... FM multiplex broadcast receiver, 25 ... beacon receiver,
26: Data transmission / reception device 200: Video information providing server,
201: Arithmetic processing device of moving image information providing server,
202: Data transmission / reception device 203 of moving image information providing server 203 ... Storage device 300 of moving image information providing server: User terminal

Claims (14)

Means for acquiring moving image information and attribute information of the moving image information captured when the vehicle is traveling, and storing the information in a storage device;
Accepting means for accepting an instruction to generate route movie information composed of movie information along a predetermined route from an external device;
Route moving picture information generating means for specifying moving picture information constituting the route moving picture information using the attribute information, and generating the route moving picture information using the specified moving picture information;
Transmitting means for transmitting the generated route moving image information to the external device, and a moving image information providing server. The video information providing server according to claim 1,
The route moving image information generating means
Among the links constituting the predetermined route, the moving image information of each link is specified as moving image information used for the route moving image information so that attribute information corresponding to moving image information between adjacent links satisfies a predetermined condition. A video information providing server characterized by this. The video information providing server according to claim 1,
The route moving image information generating means
Movie information using moving image information between adjacent links out of the links constituting the predetermined route taken by the same vehicle and having a shooting date and time within a predetermined range for the route moving image information A video information providing server characterized by specifying as follows. The video information providing server according to claim 1,
The route moving image information generating means
A plurality of candidates for route video information are generated using the video information of the links constituting the predetermined route,
Of the links constituting the predetermined route, the number of links between links whose attribute information corresponding to the video information between adjacent links does not satisfy the predetermined condition is calculated for each candidate of the route video information,
A moving image information providing server that identifies a predetermined number of candidates for the route moving image information in ascending order of the calculated number. The video information providing server according to claim 4,
The route moving image information generating means
A weight value corresponding to the number of links that do not satisfy the predetermined condition is set for each of the identified route moving image information candidates, and the candidate having the smallest total weight value over the predetermined route is selected as the route. A moving image information providing server characterized by moving image information. The video information providing server according to claim 4,
The attribute information includes vehicle speed information at the time of shooting,
The route moving image information generating means
For each of the identified route moving image information candidates, a weight value corresponding to a difference in vehicle speed at the time of shooting moving image information between adjacent links is set, and the candidate having the smallest sum of weight values over the entire predetermined route is selected. A moving image information providing server characterized in that it is route moving image information. The video information providing server according to claim 4,
The attribute information includes travel lane information at the time of shooting,
The route moving image information generating means
For each of the identified route moving image information candidates, a weight value corresponding to a lane mismatch at the time of shooting the moving image information between adjacent links is set, and the candidate having the smallest total weight value over the predetermined route is selected A moving image information providing server characterized in that it is route moving image information. The video information providing server according to claim 4,
The accepting means accepts a scheduled travel date and time of the predetermined route;
The route moving image information generating means
For each identified route moving image information candidate, a weight value is set according to the difference between the shooting date and time of the moving image information of each link and the scheduled traveling date and time, and the sum of the weight values over the entire predetermined route is the smallest A moving image information providing server, wherein a candidate is the route moving image information. The video information providing server according to claim 4,
The attribute information includes weather information at the time of shooting,
The route moving image information generating means
For each of the identified route moving image information candidates, a weight value corresponding to the weather mismatch at the time of shooting the moving image information between adjacent links is set, and the candidate with the smallest total weight value over the predetermined route is selected A moving image information providing server characterized in that it is route moving image information. The video information providing server according to claim 4,
The attribute information includes vehicle type information at the time of shooting,
The route moving image information generating means
For each of the identified route moving image information candidates, a weight value corresponding to a vehicle type mismatch at the time of shooting moving image information between adjacent links is set, and the candidate having the smallest total weight value over the predetermined route is A moving image information providing server characterized in that it is route moving image information. A predetermined device that transmits the moving image information captured by the imaging device during traveling of the vehicle and the attribute information of the moving image information to the moving image information providing server;
Means for acquiring the moving picture information and the attribute information and storing them in a storage device;
Accepting means for accepting an instruction to generate route movie information composed of movie information along a predetermined route from an external device;
Route moving picture information generating means for specifying moving picture information constituting the route moving picture information using the attribute information, and generating route moving picture information using the specified moving picture information;
Transmitting means for transmitting the generated route moving image information to the external device, and a moving image information providing system. A transmission means for transmitting an acquisition request signal for path video information that is video information along a predetermined path;
Means for storing the route moving picture information received from the moving picture information providing server in a storage means;
Signal acquisition means for acquiring a predetermined signal relating to a power source and a steering angle of the vehicle from a control device for controlling the vehicle;
A navigation device comprising: a display unit configured to change image information of route moving image information displayed on the display unit according to a signal acquired by the signal acquisition unit. A navigation device according to claim 12, comprising:
The route moving image information has vehicle speed information at the time of travel of links constituting a predetermined route,
The display means includes
A navigation apparatus, wherein a reproduction speed of the route moving image information is determined based on a vehicle speed specified by the predetermined signal and vehicle speed information included in the route moving image information. A navigation device according to claim 13,
The route moving image information includes right and left turn information of links constituting a predetermined route,
The display means includes
Determining whether or not the vehicle speed specified by the predetermined signal is equal to or lower than a predetermined value when displaying the moving image information of the route taken at the time of traveling of the link having the right / left turn information on the display unit;
When the vehicle speed is less than or equal to a predetermined value, it is determined whether or not a signal indicating a predetermined steering angle has been acquired.If acquired, the reproduction of the route moving image information is continued.
A navigation device characterized in that the reproduction of the route moving image information is stopped when the vehicle speed is not less than a predetermined value or when a signal indicating a predetermined steering angle is not acquired.

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