JP2004171294A - Data delivery system and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a data delivery system and method that can reliably deliver data without burdening a data delivery server even if a repeater of radio communication is switched over. <P>SOLUTION: The data delivery server 200 divides data A delivered to a plurality of division data A1 to A4, and delivers them in advance to a plurality of access points 400D to 400F and 400C arranged along a route where a vehicle 100 travels. The vehicle 100 then receives the division data A1 as passing the communication area of the access point 400D. The vehicle 100 similarly receives the division data A2 to A4 as passing the communication areas of the other access points 400E, 400F and 400C respectively. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a data distribution system and method for receiving various data distribution in a vehicle.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a data distribution system that distributes map data and the like from a distribution center to a traveling vehicle has been known (for example, Patent Document 1). In this map distribution system, a map distribution server searches for a traveling route of a vehicle, and divides and distributes map data necessary for map display or the like according to a traveling position to a vehicle traveling along the traveling route. I have. As a result, only the necessary map data can be distributed, and the communication time can be reduced by reducing the amount of distribution data, and the memory of the in-vehicle terminal can be reduced.
[0003]
[Patent Document 1]
JP 2002-48573 A (page 5-10, FIG. 1-15)
[0004]
[Problems to be solved by the invention]
By the way, in the map distribution system of Patent Document 1 described above, a telephone company terminal (mobile telephone) is used as a communication means on the in-vehicle terminal side, and the connected line is frequently disconnected due to a communication state or the like. It is not a system that assumes. For example, recently, the wireless LAN environment has been improved, and by providing access points everywhere on roads and public facilities, map data is transmitted from the map distribution server to the onboard terminal device using the wireless LAN as a communication means. Is also technically possible. However, at present, the communication area of each access point of the wireless LAN is smaller than the communication area of a mobile phone or the like, so that it may not be possible to send all map data to be distributed via one access point. As a service that assumes such an unstable connection state of the line, there is a service that buffers the server side and continues the distribution process when the line connection is restarted. However, if the server-side buffering function is used to distribute map data, it is necessary to distribute map data to multiple vehicles in parallel, so the server side has to secure the line for disconnection and reconnection. It is not practical because the buffer amount of map data that needs to be stored becomes enormous. For this reason, even when the relay device such as an access point switches frequently as in a wireless LAN or the like, it is possible to reduce the burden on the distribution side, and a distribution method capable of reliably distributing data is provided. Was desired.
[0005]
The present invention has been made in view of such a point, and an object of the present invention is to distribute data reliably without burdening a distribution server even when a wireless communication relay device is switched. It is an object of the present invention to provide a data distribution system and method capable of performing the above.
[0006]
[Means for Solving the Problems]
In order to solve the above-described problems, a data distribution system of the present invention includes a terminal device mounted on a vehicle and a plurality of terminal devices having communication areas that can be connected by wireless communication and have different locations. A relay device; and a data distribution server connected to the terminal device via one of the plurality of relay devices. The data distribution server includes: a data dividing unit that divides data to be distributed so as to complete transmission in a communication area where a vehicle is to pass to generate a plurality of divided data; and a plurality of divided data generated by the data dividing unit. A first distribution processing unit that distributes each of the divided data to a plurality of relay devices that the vehicle is to pass through the communication area.
[0007]
In addition, the data distribution method of the present invention enables a vehicle equipped with a terminal device connectable to each of the plurality of relay devices by wireless communication to be able to perform distribution while passing through the communication area of each of the plurality of relay devices. Dividing the data to be distributed to create a plurality of divided data, distributing each of the plurality of divided data to the plurality of relay devices and distributing the divided data, And transmitting the divided data from the relay device to the terminal device when is passing.
[0008]
Each divided data is created so that the distribution is completed while the vehicle is passing through the communication area of each relay device, and each divided data is distributed to the terminal device. Therefore, even when the relay device is switched, the distribution processing is performed. There is no interruption. For this reason, there is no need to perform processing for resuming the interrupted distribution operation on the data distribution server side, and the load on the data distribution server can be reduced. Further, since the distribution operation is not interrupted when the relay device is switched, it is possible to reliably perform data distribution.
[0009]
In addition, the above-described data dividing means may be used to determine the distance of the traveling route of the vehicle passing through the communication area, the communication speed of wireless communication between the terminal device and the relay device, the speed of the vehicle passing through the communication area, It is desirable to determine the data size of the plurality of divided data based on the required transit time when passing through the communication area. This makes it possible to set a specific data size that can be distributed while the vehicle passes through the communication area of each relay device.
[0010]
Further, the terminal device described above may include a second distribution processing unit that requests the data distribution server to distribute data, and sends, to the data distribution server, travel route data that specifies a scheduled travel route of the vehicle upon the request. desirable. This makes it possible for the data distribution server to specify a plurality of relay devices to which the divided data is to be distributed.
[0011]
In addition, it is desirable that the above-mentioned traveling route data include a scheduled passing time at which the vehicle passes through a plurality of points on the scheduled traveling route. With this, the data distribution server can know the timing at which each divided data can be transmitted from the relay device to the terminal device, the time when the vehicle passes through the communication area of each relay device, and set the data size of each divided data. It is possible to set which relay device should be transmitted to ensure that each divided data is distributed to the terminal device.
[0012]
Further, it is desirable that the above-described vehicle includes a navigation device that creates travel route data. This makes it easy to create accurate travel route data.
Further, the above-described navigation device may include a travel route processing unit that sets a travel route to a destination by route search processing to create travel route data and guides a vehicle to travel along the travel route. desirable. It becomes possible to use the traveling route data used to actually guide the vehicle in the navigation device, and to distribute the divided data from each relay device to the terminal device along the route on which the vehicle actually travels.
[0013]
Further, the first distribution processing means distributes each of the plurality of divided data to the relay device before entering the communication area, and each of the plurality of relay devices to which the divided data has been distributed is transmitted to its own device. It is desirable that the divided data be held until the vehicle enters the corresponding communication area, and that the divided data be transmitted to the terminal device after the vehicle enters the communication area. This can further reduce the processing load on the data distribution server.
[0014]
Further, the divided data delivered to the relay device described above is added with a first program for transmitting the divided data to a terminal device mounted on a vehicle passing through the communication area, and the divided data is transmitted to the relay device. It is desirable that the first program be executed when the data is transmitted. This makes it possible to autonomously transmit the divided data distributed to each relay device to the terminal device at an appropriate timing, thereby further reducing the processing load on the data distribution server.
[0015]
Further, a second program for moving the divided data to another relay device when the scheduled traveling time of the vehicle is shifted is added to the divided data distributed to the above-described relay device, and the divided data is transmitted to the relay device. It is desirable that the second program be executed when is distributed. This makes it possible to autonomously move the divided data distributed to each relay device to another relay device in accordance with the traveling state of the vehicle, thereby reducing the processing load on the data distribution server and reliably dividing the data. Data can be delivered to the terminal device.
[0016]
In addition, it is desirable that the above-described movement of the divided data is performed with respect to the relay device arranged along the scheduled traveling route of the vehicle. As a result, it becomes possible to respond flexibly to a change in the speed of the vehicle that changes according to the road condition or the like.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a data distribution system according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram illustrating an overall configuration of a data distribution system according to the present embodiment. As shown in FIG. 1, the data distribution system according to the present embodiment includes access points (APs) 400 installed at a plurality of locations, and wireless communication is performed between the access points 400 and the vehicle 100. . Each access point 400 is connected to the data distribution server 200 via a predetermined network 300, and various data distributed by the data distribution server 200 are transmitted to the vehicle via each access point 400 as a relay device. 100.
[0018]
FIG. 2 and FIG. 3 are diagrams showing an outline of an operation of distributing various data performed in the present embodiment. FIG. 2 shows a positional relationship between the vehicle 100 and each access point 400, and FIG. 3 shows a specific method of data distribution.
A plurality of access points 400 are arranged along the traveling route of the vehicle 100. In the example illustrated in FIG. 2, nine access points 400A to 400I are arranged around the vehicle 100, and among these, the access points 400A, 400D, 400E, 400F, and 400C sequentially move through the communication area of the vehicle 100 in the order of the access points 400A, 400D, 400E, 400F, and 400C. Shall pass.
[0019]
For example, when the vehicle 100 enters the communication area of the access point 400A, the vehicle 100 (accurately, an in-vehicle terminal device mounted on the vehicle 100) and the access point 400A are connected by a wireless line, and a wireless LAN is formed. . By the way, since the communication area of the wireless LAN is smaller than the communication area of a base station of a general mobile phone or the like, if the amount of data to be distributed is large, the entire data is distributed while passing through the communication area of the access point 400A. Does not end. For this reason, in the present embodiment, the vehicle 100 receives distribution of a plurality of divided data via the plurality of access points 400A, 400D, 400E, 400F, and 400C arranged along the route to be traveled.
[0020]
Specifically, as shown in FIG. 3, after a data distribution request is issued from the vehicle 100 ((1)), the data distribution server 200 divides the distribution target data A into four divided data sets A1, A2, A3. , A4 ((2)), and each divided data is distributed in advance to a plurality of access points 400D, 400E, 400F, 400C arranged along the route on which the vehicle 100 is to travel ((3)). . Thereafter, the vehicle 100 receives the divided data A1 while passing through the communication area of the access point 400D ((4)). When the receiving operation is completed, a predetermined notification is sent from vehicle 100 to data distribution server 200 ([5]). Similarly, while the vehicle 100 is passing through the communication areas of the other access points 400E, 400F, and 400C, the divided data A2, A3, and A4 are received. In this manner, the vehicle 100 can receive the data A of a large data size via a plurality of access points.
[0021]
The distribution system according to the present embodiment uses a technique called “mobile agent”. A mobile agent is a program that moves autonomously between computers. It moves between computers while maintaining the execution state of the program, and resumes work performed on the source computer on the destination computer. (6).
[0022]
FIG. 4 is a diagram showing a structure of a data capsule introduced in the present embodiment in which the divided data has a function of a mobile agent. As shown in FIG. 4, in the present embodiment, the divided data from the data distribution server 200 to each access point 400 using a data capsule composed of a program area, a data area, and an execution state area in association with each divided data. Delivery.
[0023]
The “program area” stores a distribution program for transmitting and moving the divided data after being distributed to the access point. Divided data is stored in the “data area”. The “execution state area” stores the execution state when the execution of the distribution program is interrupted. When a data capsule having such contents is distributed to each access point 400, a distribution program is automatically executed at each access point 400, and when the vehicle 100 enters the communication area thereafter, the vehicle 100 When the divided data included in the data capsule needs to be transmitted from another access point 400 due to transmission of the divided data or a change in the traveling schedule of the vehicle 100, the data capsule itself is transferred to another access point 400. Is performed.
[0024]
Next, each component of the data distribution system shown in FIG. 1 will be described in detail.
FIG. 5 is a diagram illustrating a configuration of an in-vehicle device mounted on the vehicle 100. As shown in FIG. 5, the vehicle 100 includes an in-vehicle terminal device 10, a GPS device 20, an autonomous navigation sensor 22, a navigation device 30, and an in-vehicle computer 50.
[0025]
The in-vehicle terminal device 10 is a wireless LAN terminal that performs wireless communication with each access point 400, and transmits and receives data to and from each access point 400 via a wireless line. For this purpose, the in-vehicle terminal device 10 includes a terminal control unit 11, a memory 12, a transmission unit 13, a reception unit 14, and an antenna switching unit 15.
[0026]
The terminal control unit 11 controls the overall operation of the in-vehicle terminal device 10 by executing a predetermined operation program stored in the memory 12. Also, the terminal control unit 11 sends a data distribution request to the data distribution server 200 to perform a series of distribution processing for receiving distribution of each divided data via each access point 400; A route data acquisition unit 18 that performs a process of acquiring the travel route of the vehicle 100 itself from the navigation device 30 at the time of this distribution request.
[0027]
The memory 12 stores distribution data (divided data) transmitted from each access point 400 in addition to the operation program executed by the terminal control unit 11.
The transmission unit 13 performs a predetermined modulation process on the transmission data output from the terminal control unit 11, and transmits the data from the antenna 16 via the antenna switching unit 15 to the access point 400 where the vehicle 100 is traveling in the communication area. Perform transmission processing. In addition, the receiving unit 14 receives the radio wave transmitted from the access point 400 and reaching the antenna 16 via the antenna switching unit 15, and transmits data after performing predetermined demodulation processing to the terminal control unit 11. The antenna switching unit 15 selectively connects the antenna 16 to the transmission unit 13 or the reception unit 14 based on the transmission / reception switching signal input from the terminal control unit 11.
[0028]
The navigation device 30 performs a process of displaying a map image around the traveling position of the vehicle 100, searching for a traveling route to a destination, and guiding the traveling of the vehicle 100 along the traveling route. The GPS device 20 and the autonomous navigation sensor 22 are connected to the navigation device 30. However, these may be provided inside the housing of the navigation device 30 and need not necessarily be connected outside the housing. The GPS device 20 includes a GPS antenna and a calculation unit that analyzes a satellite radio wave received by the GPS antenna, and outputs the position (longitude and latitude) of the vehicle 100. The position information of the vehicle 100 output from the GPS device 20 is also sent to the in-vehicle terminal device 10. The autonomous navigation sensor 22 includes a distance sensor and a direction sensor (gyro), and the navigation device 30 calculates the position of the vehicle 100 based on the output of these sensors.
[0029]
FIG. 6 is a diagram illustrating a detailed configuration of the navigation device 30. As shown in FIG. 6, the navigation device 30 includes a navigation control unit 31, a map storage unit 32, a display 33, an amplifier 34, a speaker 35, and an operation unit 36.
[0030]
The navigation control unit 31 controls the entire navigation device 30, and its function is realized by executing a predetermined operation program using a CPU, a ROM, a RAM, and the like.
The map storage unit 32 stores map data necessary for map display processing and route search processing. For example, the configuration can be made using a hard disk device, but a drive device that reads map data stored on a CD or DVD may be used. The display 33 displays a map image or the like around the own vehicle position based on the drawing data output from the navigation control unit 31. The amplifier 34 amplifies an audio signal such as a guidance audio output from the navigation control unit 31 and outputs the amplified audio signal from the speaker 35. The operation unit 36 includes various operation switches, operation keys, and the like, and outputs a signal corresponding to the operation content of the user to the navigation control unit 31.
[0031]
As shown in FIG. 6, the navigation control unit 31 includes a vehicle position calculation unit 37, a map drawing unit 38, a traveling route processing unit 39, and a traveling route storage unit 40. The vehicle position calculation unit 37 calculates the own vehicle position of the vehicle 100 based on the data output from the GPS device 20 and the autonomous navigation sensor 22, and when the calculated own vehicle position is not on the road on the map, the vehicle position is calculated. A map matching process for correcting the position of the own vehicle based on the shape and the traveling locus is performed. The map drawing unit 38 draws a map image around the own vehicle position calculated by the vehicle position calculation unit 37 and a cursor position specified by the operation unit 36.
[0032]
The traveling route processing unit 39 searches for a traveling route that connects the departure point and the destination according to a predetermined search condition, and displays an image of the obtained traveling route on a map or turns right and left intersections. A drawing process for creating a guide image and a guide voice for guiding the travel of the vehicle 100 along the travel route by voice are created. The travel route storage unit 40 stores data (travel route data) for specifying the travel route by the route search by the travel route processing unit 39. The traveling route data includes scheduled passage times at a plurality of locations along the traveling route.
FIG. 7 is a diagram illustrating a detailed configuration of the data distribution server 200. As shown in FIG. 7, the data distribution server 200 includes a server control unit 210, a database (DB) 220, and a communication processing unit 230. The server control unit 210 performs a process of dividing and distributing data to be distributed when a data distribution request is sent from the in-vehicle terminal device 10 mounted on the vehicle 100. It comprises a unit 212, a data capsule creation unit 214, and a distribution processing unit 216. The server control unit 210 performs a predetermined control operation by executing a predetermined program stored in a CPU, a ROM, and a RAM.
[0033]
Data dividing section 212 calculates a data size that can be transmitted at each of a plurality of access points 400 through which vehicle 100 passes. For example, the distance of a traveling route in the communication area of the vehicle 100 passing through the communication area, the communication speed of wireless communication between the in-vehicle terminal device 10 and the access point 400, the speed of the vehicle 100 passing through the communication area, The data size of each of the plurality of divided data is determined based on the time required for the vehicle 100 to pass through the communication area.
[0034]
The data capsule creating unit 214 creates a data capsule having the structure shown in FIG. 4 for each of the plurality of divided data created by the data dividing unit 212. The program area of each data capsule includes a procedure for extracting the divided data from the data area of the data capsule distributed to the access point 400 and transmitting the divided data to the vehicle 100, and a procedure for transmitting the divided data at the access point 400 scheduled to be transmitted. A distribution program describing a processing procedure such as how to cope with the case where transmission of the URL is impossible is stored.
[0035]
The distribution processing unit 216 sends an operation instruction to the data division unit 212 and the data capsule creation unit 214 when a data distribution request is sent from the vehicle 100, and sends a notification to the effect that each divided data has been received from the vehicle 100. Receive this when there is. Further, when a notification that the traveling route has been changed is received from vehicle 100, the contents of this change are notified to data capsules already distributed to each access point 400.
[0036]
The communication processing unit 230 performs processing necessary for the data distribution server 200 to perform data communication with the vehicle 100 via the access point 400 via the network 300.
FIG. 8 is a diagram showing a detailed configuration of the access point 400. As shown in FIG. 8, the access point 400 includes an access point control unit 410, a wireless processing unit 420, and a communication processing unit 430.
[0037]
The access point control unit 410 controls the entire access point 400, and performs a predetermined control operation by executing a predetermined program stored in a CPU, a ROM, and a RAM. When the data capsule is distributed from the data distribution server 200 to the access point 400, the program stored in the program area of the data capsule is executed by the access point control unit 410 and becomes resident in the access point control unit 410. . In the present embodiment, a mobile agent that operates in response to a data capsule will be described as a “delivery agent”. In the present embodiment, the distribution agent 412 is resident in the access point control unit 410 until the transmission of the divided data to the vehicle 100 is completed or the mobile station moves to another access point 400.
[0038]
The data dividing unit 212 described above serves as a data dividing unit, the distribution processing unit 216 serves as a first distribution processing unit, the distribution processing unit 17 serves as a second distribution processing unit, the travel route processing unit 39 serves as a travel route processing unit, The distribution programs stored in the program area of the data capsule correspond to the first and second programs, respectively.
[0039]
The data distribution system of the present embodiment has such a configuration, and its operation will be described next.
(1) Operation of navigation device
FIG. 9 is a flowchart showing an operation procedure of the navigation device 30, showing an operation procedure related to data distribution.
[0040]
When transmitting a data distribution request from the vehicle 100 to the data distribution server 200, prior to the transmission of the distribution request, the in-vehicle terminal device 10 requests the navigation device 30 to transmit the traveling route data of the vehicle 100 from the vehicle. Is done.
The travel route processing unit 39 of the navigation control unit 31 determines whether or not travel route data has been requested from the terminal control unit 11 (step 100). If the travel route data has not been requested, a negative determination is made and this determination is made. repeat. In addition, when there is a request for the traveling route data from the terminal control unit 11, an affirmative determination is made in step 100, and then the traveling route processing unit 39 determines whether or not the traveling route is set (step 101). . If the vehicle 100 is traveling along the travel route obtained by the route search process, an affirmative determination is made in this determination, and otherwise, a negative determination is made in this determination.
[0041]
When a negative determination is made (when the travel route is not set), the travel route processing unit 39 displays a route search screen (step 102), and after the search data is input by the user (step 102). 103), it is determined whether or not a search instruction has been issued (step 104). The search data is data necessary for a route search such as a destination and search conditions. When the user is inputting search data, a negative determination is made in the determination in step 104, and the process returns to step 103 to return to the search data. Input is continued.
[0042]
When the input of the search data is completed and the route search is instructed by the user, an affirmative determination is made in the determination of step 104, and then the traveling route processing unit 39 performs a route search process to reach the destination. An optimal travel route is set (step 105), and data (travel route data) relating to the set travel route is output to the in-vehicle terminal device 10 (step 106). As described above, the travel route data includes data necessary for specifying a route such as a node (or link) that constitutes the travel route, and the estimated time of passage at each point on the travel route. I have.
[0043]
If the travel route has already been set at the time when the travel route data is requested from the terminal control unit 11, after the affirmative determination is made in the determination of step 101, the process immediately proceeds to step 106, where the travel route is set. A process of reading the travel route data from the route storage unit 40 and outputting the data to the in-vehicle terminal device 10 is performed.
[0044]
After the traveling route data is output to the in-vehicle terminal device 10 in this manner, a data distribution request is sent from the in-vehicle terminal device 10 to the data distribution server 200. In parallel with this, the traveling route processing unit 39 determines whether or not the traveling route has been changed (Step 107). While the vehicle 100 is traveling along the set traveling route, a negative determination is made, and then the traveling route processing unit 39 determines whether the vehicle 100 has arrived at the destination (Step 108). ). If the vehicle has not arrived, a negative determination is made, and the process returns to step 107 to repeat the operation after determining whether or not there is a change in the traveling route.
[0045]
When the travel route is changed, an affirmative determination is made in the determination of step 107, and the changed travel route data is output to the in-vehicle terminal device 10 (step 109). For example, when the user himself / herself operates the operation unit 36 to change the destination and instructs a route search again, or when the vehicle 100 traveling along the currently set traveling route is in the middle of this setting, If the vehicle travels on a route deviating from the travel route and is automatically searched for a return route to the original travel route, it is determined that the travel route has been changed, and an affirmative determination is made in the determination of step 107. Be done. However, if the output of the traveling route data is repeated when the distance of the searched return route is short, the processing in the navigation device 30 and the in-vehicle terminal device 10 becomes complicated, and in this case, the traveling route is not changed. It is desirable to treat as. Thereafter, the flow returns to step 107 again, and the operation after the determination of the presence / absence of the change of the traveling route is repeated.
[0046]
When the vehicle 100 arrives at the destination, an affirmative determination is made in the determination at step 108, and the operation related to data distribution in the navigation device 30 ends.
(2) Operation of in-vehicle terminal device
FIG. 10 is a flowchart showing the operation procedure of the in-vehicle terminal device 10. The distribution processing unit 17 in the terminal control unit 11 determines whether to make a data distribution request to the data distribution server 200 (Step 200). For example, a negative determination is made in the determination at step 200 until data distribution is instructed by the user using an operation unit (not shown) provided in the vehicle-mounted terminal device 10, and this determination is repeated. In addition, when data distribution is instructed by the user, an affirmative determination is made in the determination in step 200, and then the route data acquisition unit 18 sends a request for traveling route data output to the navigation device 30 ( Step 201), it is determined whether or not the traveling route data has been returned from the navigation device 30 (step 202). A negative determination is made until it is sent back, and this determination is repeated.
[0047]
When the travel route data is returned from the navigation device 30 (operation of step 106 in FIG. 9), an affirmative determination is made in the determination of step 202, and then the distribution processing unit 17 sends the data to the data distribution server 200. Is transmitted (step 203). The distribution request includes travel route data output from the navigation device 30 together with data for specifying data to be distributed (for example, a file name when a program distribution is requested in file units).
[0048]
Thereafter, an operation of receiving each divided data distributed from the data distribution server 200 is performed. The distribution processing unit 17 determines whether or not the divided data transmitted from any of the access points 400 has been received while the vehicle 100 is traveling (Step 204), and if not received, a negative determination is made. Then, it is determined whether or not the travel route has been changed (step 205). If there is no change, a negative determination is made, and the process returns to step 204 to repeatedly determine whether or not divided data has been received. When the changed travel route data is output from the navigation device 30 (operation of step 109 in FIG. 9), an affirmative determination is made in the determination of step 205, and then the distribution processing unit 17 determines that the travel route is The data distribution server 200 is notified of the change (step 206). This notification includes the changed travel route data output from the navigation device 30. Upon completion of the notification, the process returns to step 204, and the determination of the presence / absence of divided data reception is repeated.
[0049]
On the other hand, when the divided data transmitted from any of the access points 400 is received, an affirmative determination is made in the determination of step 204, and then the distribution processing unit 17 notifies the data distribution server 200 that the divided data has been received. Is sent (step 207). This notification includes information for specifying the received divided data (for example, if each divided data has a serial number, this serial number) and the position and time at which the divided data was received.
[0050]
Next, the distribution processing unit 17 determines whether or not all divided data has been received (step 208). If there is unreceived divided data, a negative determination is made, and the process returns to step 204 to perform division. The determination of the presence or absence of data reception is repeated. If all the divided data have been received, an affirmative determination is made in the determination at step 208, and a series of operations for receiving the distribution of the divided data is completed. Each of these divided data is sent to the navigation device 30, the in-vehicle computer 50, or other in-vehicle devices (not shown).
[0051]
(3) Operation of data distribution server
FIG. 11 is a flowchart showing the operation procedure of the data distribution server 200. The distribution processing unit 216 in the server control unit 210 determines whether there is a data distribution request from any of the vehicles 100 (step 300), and makes a negative determination if there is no data distribution request. Leveraging is repeated. If a data distribution request is sent from any of the vehicles 100, an affirmative determination is made in the determination of step 300, and then the data division unit 212 transmits the data to be distributed from the distribution data 222 in the database 220. Is read (step 301), the read data is divided based on the traveling route data sent from the vehicle 100 (step 302). This division processing is based on the traveling route data included in the distribution request sent from the vehicle 100, the route on which the vehicle 100 is to travel, the estimated passage times at various points along this route, and the access points in the database 220. Setting the data size based on the communication area calculated based on the installation position of each access point 400 stored in the table 224 and the communication speed in wireless communication performed between the vehicle 100 and the access point 400 It is performed by.
[0052]
Next, the data capsule creation unit 214 creates a data capsule for each divided data (step 303), and the distribution processing unit 216 uses the created data capsules for each access along the traveling route of the vehicle 100. The data is transmitted to the point 400 (step 304). When the data capsule is transmitted to each access point 400 in this way, in each of these access points 400, the autonomous transmission operation of the divided data by the distribution agent 412 causes the vehicle 100 to change the communication area of each access point 400. It is performed at the timing of passing.
[0053]
After the transmission of each data capsule is completed, the distribution processing unit 216 determines whether or not a notification has been received from the in-vehicle terminal device 10 of the vehicle 100 (step 305). Repeat the judgment. If a notification has been received from the in-vehicle terminal device 10, an affirmative determination is made in step 305, and then the distribution processing unit 216 needs to instruct each access point 400 to change the data capsule that has been transmitted. It is determined whether or not there is (Step 306). As described with reference to FIG. 10, there are two types of notifications transmitted from the communication terminal device 10 to the data distribution server 200. One is a notification transmitted when the reception of the divided data is completed (the notification transmitted in step 207 of FIG. 10), and the other is a notification that the travel route has been changed and the travel after the change. This is a notification including a route (a notification transmitted in step 206 of FIG. 10).
[0054]
If a notification transmitted from the vehicle 100 is received after receiving the divided data, no change is necessary, so a negative determination is made in the determination of step 306, and then the distribution processing unit 216 determines all divided It is determined whether the data distribution has been completed (step 307). If there is divided data for which distribution has not been completed, a negative determination is made, and the process returns to step 305 to repeat the notification reception determination operation.
[0055]
Further, when a notification transmitted from the vehicle 100 is received when the traveling route is changed, it is necessary to reflect this change in the data capsule (operation of the distribution agent 412) sent to each access point 400. After an affirmative determination is made in the determination of 306, the distribution processing unit 216 instructs the data capsule of the access point 400 to change the travel route (step 308). For example, an instruction to move the data capsule to the access point 400 arranged along the changed route is sent. Thereafter, the process proceeds to step 307, where it is determined whether the distribution of all the divided data has been completed.
[0056]
When the distribution of all the divided data is completed, an affirmative determination is made in the determination of step 307, and a series of operations relating to the distribution of the data is completed.
(4) Operation of distribution agent (data capsule)
FIG. 12 is a flowchart showing an operation procedure of the distribution agent 412 in the access point 400 to which the data capsule has been transmitted. Upon starting operation at access point 400, distribution agent 412 determines whether vehicle 100 has entered the communication area of access point 400 (step 400). If it has not entered, a negative determination is made, and then the distribution agent 412 determines whether or not the allowable waiting time has passed (step 401). For example, a standby allowable time obtained by adding a predetermined time to the scheduled time of entering the communication area of the access point 400 is set. Until this time has elapsed, a negative determination is made in the determination of step 401. In this case, next, the distribution agent 412 determines whether or not movement has been instructed by the data distribution server 200 in accordance with the change of the traveling route (step 402). If the vehicle 100 is traveling along a preset traveling route, no movement is instructed, so a negative determination is made in the determination of step 402, and the process returns to step 400 to return the vehicle 100 to the communication area. The determination as to whether or not the vehicle has entered is repeated.
[0057]
If the vehicle 100 has entered the communication area of the access point 400, an affirmative determination is made in the determination of step 400, and then the distribution agent 412 determines whether the on-board terminal device 10 of the vehicle 100 is ready for reception. It is determined whether or not it is (step 403). If the preparation is complete, an affirmative determination is made, and then the distribution agent 412 transmits the divided data stored in the data area of the data capsule to the in-vehicle terminal device 10 (step 404). When this transmission operation ends, the distribution agent 412 corresponding to the divided data ends a series of operations.
[0058]
If the vehicle 100 does not enter the communication area of the access point 400 and the allowable standby time has passed, an affirmative determination is made in the determination of step 401. For example, the vehicle 100 is traveling on a traveling route as planned, but if the vehicle 100 gets caught in a heavy traffic before entering the communication area of the access point 400, the allowable standby time will have passed. In such a case, next, the distribution agent 412 stores the execution state of its own program in the execution state area of the data capsule (step 405), and then positions this data capsule forward along the traveling route. The user is moved toward the access point 400 (step 406). Thereafter, the distribution agent 412 repeats the processing from the beginning (returning to step 400) at the access point 400 of the movement destination.
[0059]
If the vehicle 100 has entered the communication area of the access point 400, but the vehicle-mounted terminal device 10 of the vehicle 100 is not ready for reception, a negative determination is made in the determination of step 403. For example, when some of the functions of the in-vehicle terminal device 10 do not operate due to radio interference or some malfunction in the vehicle 100, or when the previous divided data is being received, the divided data may be transmitted. It cannot be received normally. In such a case, it is determined that the in-vehicle terminal device 10 is not ready for reception, and then the distribution agent 412 determines whether the vehicle 100 is traveling in the communication area of the access point 400. (Step 407) If the vehicle is traveling in the communication area, an affirmative determination is made, and the process returns to Step 403 to repeat this determination until preparation for reception is completed. If the vehicle 100 leaves the communication area in a state in which it is not ready for reception, a negative determination is made in the determination of step 407, and then the distribution agent 412 changes the execution state of its own program to the execution of the data capsule. After the data capsule is stored in the status area (step 408), the data capsule is moved along the traveling route toward the access point 400 located behind (step 409). Thereafter, the distribution agent 412 repeats the processing from the beginning (returning to step 400) at the access point 400 of the movement destination.
[0060]
Further, when the movement is instructed from the data distribution server 200, an affirmative determination is made in the determination in step 402, and then the distribution agent 412 stores the execution state of its own program in the execution state area of the data capsule ( (Step 410), the data capsule is moved toward the designated access point 400 (Step 411). Thereafter, the distribution agent 412 repeats the processing from the beginning (returning to step 400) at the access point 400 of the movement destination.
[0061]
As described above, in the data distribution system according to the present embodiment, each divided data is created so that distribution is completed while the vehicle 100 is passing through the communication area of each access point 400, and distribution of each divided data to the in-vehicle terminal device 10 is performed. Is performed, the distribution process is not interrupted even when the access point 400 capable of communicating with the in-vehicle terminal device 10 is switched. For this reason, there is no need to perform processing for resuming the interrupted distribution operation on the data distribution server 200 side, and the burden on the data distribution server 200 can be reduced. In addition, since the distribution operation is not interrupted when the access point 400 switches, it is possible to reliably perform data distribution.
[0062]
Further, the distance of the traveling route of the vehicle 100 passing through the communication area, the communication speed of wireless communication between the in-vehicle terminal device 10 and the access point 400, the speed of the vehicle 100 passing through the communication area, and the communication speed of the vehicle 100 Since the data size of the plurality of divided data is determined based on the time required for passing through the area, the specific data size that the vehicle 100 can deliver while passing through the communication area of each access point 400 is determined. It becomes possible to set.
[0063]
Further, when the data distribution request is transmitted from the in-vehicle terminal device 10 to the data distribution server 200, the traveling route data of the vehicle 100 is also transmitted. It becomes possible to specify. In addition, by including, in the travel route data, the scheduled passage times at which the vehicle 100 passes through a plurality of points on the scheduled travel route, the timing at which each divided data can be transmitted from the access point 400 to the on-board terminal device 10 can be determined. The time at which the vehicle 100 passes through the communication area of each access point 400 can be known in the data distribution server 200, and the data size of each divided data can be set, and each divided data can be reliably distributed to the in-vehicle terminal device 10. It is possible to set to which access point 400 the transmission should be performed.
[0064]
In addition, since the travel route data is created by the navigation device 30, it is easy to create accurate travel route data. In addition, the navigation device 30 includes a travel route processing unit 39 that sets a travel route to a destination by route search processing, creates travel route data, and guides the vehicle to travel along the travel route. Since the travel route data used for actually guiding the vehicle 100 in the navigation device 30 can be used, the access point 400 is divided into the in-vehicle terminal devices 10 along the route on which the vehicle 100 actually travels. Data can be delivered.
[0065]
Further, in the present embodiment, each access point 400 to which the divided data is distributed in advance holds the divided data until the vehicle 100 enters the communication area, and stores the divided data after the vehicle 100 enters the communication area. Since the data is transmitted to the device 10, the data distribution server 200 only needs to first distribute the divided data to each access point 400, and the processing load on the data distribution server 200 can be further reduced.
[0066]
In addition, a distribution program for transmitting the divided data to the in-vehicle terminal device 10 of the vehicle 100 passing through the communication area is added to the divided data distributed to each access point 400. Is transmitted, the distribution program is executed, and the distribution agent 412 starts operating. As a result, the divided data distributed to each access point 400 can be autonomously transmitted to the in-vehicle terminal device 10 at an appropriate timing, and the processing load on the data distribution server 200 can be further reduced.
[0067]
Further, a distribution program for moving the divided data to another access point 400 when the scheduled travel time of the vehicle 100 is shifted is added to the divided data distributed to each access point 400, and the divided data is distributed to the access point 400. When the data is distributed, the distribution program is executed and the distribution agent 412 starts operating. Thereby, the divided data distributed to each access point 400 can be autonomously moved to another access point 400 in accordance with the traveling state of the vehicle 100, and the processing load on the data distribution server 200 can be reduced. As a result, the divided data can be reliably delivered to the in-vehicle terminal device 10. In particular, when the divided data is moved, by moving the divided data to another access point 400 arranged along the planned traveling route of the vehicle 100, the change in the speed of the vehicle 100 that changes according to the road condition or the like can be adjusted. It is possible to respond to adaptation.
[0068]
Note that the present invention is not limited to the above embodiment, and various modifications can be made within the scope of the present invention. In the above-described embodiment, the travel route data obtained by performing the route search processing in the navigation device 30 mounted on the vehicle 100 is transmitted to the data distribution server 200 when a data distribution request is made. The position, the destination, and the conditions for the route search may be sent, and the data distribution server 200 may execute the route search process to create the travel route data. Thus, the amount of data transmitted from the in-vehicle terminal device 10 to the data distribution server 200 can be reduced.
[0069]
【The invention's effect】
As described above, according to the present invention, each divided data is created such that distribution is completed while the vehicle is passing through the communication area of each relay device, and distribution of each divided data to the terminal device is performed. Even when the relay device is switched, there is no interruption of the distribution process. For this reason, there is no need to perform processing for resuming the interrupted distribution processing on the data distribution server side, and the burden on the data distribution server can be reduced. In addition, since the distribution process is not interrupted when the relay device switches, it is possible to reliably execute data distribution.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an overall configuration of a data distribution system according to an embodiment.
FIG. 2 is a diagram showing an outline of an operation of distributing various data performed in the embodiment.
FIG. 3 is a diagram showing an outline of an operation of distributing various data performed in the embodiment.
FIG. 4 is a diagram illustrating a structure of a data capsule introduced in the present embodiment in which a divided data has a function of a mobile agent.
FIG. 5 is a diagram showing a configuration of an in-vehicle device mounted on a vehicle.
FIG. 6 is a diagram showing a detailed configuration of a navigation device.
FIG. 7 is a diagram showing a detailed configuration of a data distribution server.
FIG. 8 is a diagram showing a detailed configuration of an access point.
FIG. 9 is a flowchart showing an operation procedure of the navigation device.
FIG. 10 is a flowchart showing an operation procedure of the in-vehicle terminal device.
FIG. 11 is a flowchart showing an operation procedure of the data distribution server.
FIG. 12 is a flowchart showing an operation procedure of a distribution agent at an access point to which a data capsule has been transmitted.
[Explanation of symbols]
10 In-vehicle terminal device
11 Terminal control unit
12 memory
13 Transmission section
14 Receiver
15 Antenna switching unit
16 Antenna
17, 216 distribution processing unit
18 Route data acquisition unit
20 GPS device
22 Autonomous navigation sensor
30 Navigation device
31 Navigation control unit
39 Travel route processing unit
40 travel route storage
50 In-vehicle computer
100 vehicles
200 Data distribution server
210 Server control unit
212 Data division unit
214 Data capsule creation unit
220 Database (DB)
400 access points
410 access point control unit
412 Delivery Agent
420 wireless processing unit

Claims (16)

A terminal device mounted on a vehicle, a plurality of relay devices having communication areas connectable to the terminal device by wireless communication and having different locations from each other, and the relay device via any one of the plurality of relay devices. A data distribution system comprising: a data distribution server connected to the terminal device;
The data distribution server,
A data dividing unit that divides data to be distributed so as to complete transmission in the communication area where the vehicle is scheduled to pass and generates a plurality of divided data,
First distribution processing means for distributing each of the plurality of divided data generated by the data division means to the plurality of relay devices that the vehicle is to pass through the communication area;
A data distribution system comprising: In claim 1,
The data distribution system according to claim 1, wherein the data dividing unit determines a data size of the plurality of divided data based on a distance of a traveling route of the vehicle passing through the communication area. In claim 1 or 2,
The data distribution system according to claim 1, wherein the data division unit determines a data size of the plurality of pieces of the divided data based on a communication speed of wireless communication between the terminal device and the relay device. In any one of claims 1 to 3,
The data distribution system according to claim 1, wherein the data dividing unit determines a data size of the plurality of divided data based on a speed of the vehicle passing through the communication area. In any one of claims 1 to 4,
The data distribution system according to claim 1, wherein the data dividing unit determines a data size of the plurality of divided data based on a time required for the vehicle to pass through the communication area. In any one of claims 1 to 5,
The terminal device includes a second distribution processing unit that requests the data distribution server to distribute data, and that transmits, to the data distribution server, travel route data specifying a planned travel route of the vehicle at the time of the request. Characteristic data distribution system. In claim 6,
The data distribution system, wherein the travel route data includes a scheduled passage time at which the vehicle passes a plurality of points on the scheduled travel route. In claim 6 or 7,
The data distribution system, wherein the vehicle includes a navigation device that creates the travel route data. In claim 8,
The navigation device sets a travel route to a destination by a route search process, creates the travel route data, and includes a travel route processing unit that guides the vehicle to travel along the travel route. And a data distribution system. In any one of claims 1 to 9,
The first distribution processing means distributes each of the plurality of divided data to the relay device before entering the communication area,
Each of the plurality of relay devices to which the divided data has been distributed holds the divided data until the vehicle enters the communication area corresponding to the own device, and performs the division after the vehicle enters the communication area. A data distribution system for transmitting data to the terminal device. In claim 10,
A first program for transmitting the divided data to the terminal device mounted on the vehicle passing through the communication area is added to the divided data distributed to the relay device,
The data distribution system, wherein the first program is executed when the divided data is transmitted to the relay device. In claim 10 or 11,
The divided data distributed to the relay device, a second program that moves the divided data to another relay device when the scheduled traveling time of the vehicle is shifted, is added,
The data distribution system, wherein the second program is executed when the divided data is distributed to the relay device. In claim 12,
The data distribution system according to claim 1, wherein the movement of the divided data is performed with respect to the relay device arranged along a scheduled route of the vehicle. Data to be distributed is divided so that a vehicle equipped with a terminal device connectable by wireless communication with each of the plurality of relay devices can be distributed while passing through the communication area of each of the plurality of relay devices. Creating a plurality of split data;
Distributing each of the plurality of divided data to the plurality of relay devices in a distributed manner;
When the vehicle is passing through the communication area of each of the plurality of relay devices, transmitting the divided data from the relay device to the terminal device,
A data distribution method comprising: In claim 14,
A first program for transmitting the divided data to the terminal device mounted on the vehicle passing through the communication area is added to the divided data distributed to the relay device,
The data distribution method, wherein the first program is executed when the divided data is transmitted to the relay device. In claim 14 or 15,
The divided data distributed to the relay device, a second program that moves the divided data to another relay device when the scheduled traveling time of the vehicle is shifted, is added,
The data distribution method, wherein the second program is executed when the divided data is distributed to the relay device.

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