JP2007034790A - Travel history collection system and travel history collection method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve accuracy of travel history data. <P>SOLUTION: This travel history collection system has: a present location detection part detecting a present location; a passage speed calculation processing means calculating a passage speed when passing a road link specified on the basis of the present location; a decision criterion change processing means changing a decision criterion of the travel history data on the basis of a road situation in the prescribed road link and the passage speed; and a travel history data calculation processing means calculating the travel history data on the basis of the changed decision criterion. In that case, the decision criterion of the travel history data is changed on the basis of the road situation in the prescribed load link and the passage speed when passing the load link to improve the accuracy of the travel history data. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  Conventionally, in a navigation device, for example, the current position of a vehicle, that is, the current position is detected by GPS (Global Positioning System), and the direction of the vehicle, that is, based on the turning angle of the vehicle detected by a gyro sensor, that is, The vehicle direction is detected, map data is read from the data recording unit, a map screen is formed on the display unit, the vehicle position indicating the current location, a map around the vehicle position, and the vehicle The direction is displayed. Therefore, the driver who is an operator can drive the vehicle according to the vehicle position displayed on the map screen, the map around the vehicle position, and the vehicle direction.

  When the driver inputs a destination and sets search conditions, a route search process is performed based on the search conditions, and a route from the starting point represented by the current location to the destination is searched according to the map data. Is done. Then, the searched route, that is, the searched route is displayed on the map screen together with the vehicle position, and guidance for the searched route, that is, route guidance is performed. Therefore, the driver can drive the vehicle along the displayed search route.

By the way, in the navigation apparatus, travel data representing the travel performance of the vehicle on the road on which the vehicle traveled is read, travel history data representing the travel history of the vehicle is created based on the travel data, and the data recording unit Is recorded and collected. The travel history data is sent to the information center as probe data as needed, and is provided from the information center to another vehicle, that is, another vehicle (see, for example, Patent Document 1).
JP 2001-209883 A

  However, in the conventional navigation device, as the travel history data, for example, when creating a traffic congestion degree indicating the degree of traffic congestion for each road link, the actual state depends on the road situation to which the road link belongs, that is, the road situation. A degree of congestion that is different from the degree of congestion may be created.

  FIG. 2 is a diagram illustrating an example of road conditions, and FIG. 3 is a diagram illustrating a conventional congestion degree determination table.

  In FIG. 2, L1 to L3 are road links, and each road link L1 to L3 belongs to a mountainous road whose road type is a general road, road links L1 and L3 are straight lines, and road link L2 is Constructs a corner with a small radius of curvature.

In this case, when the passage speed when passing through the road links L1 to L3 is V1 to V3, the road links L1 and L3 are in a straight line portion, so the passage speeds V1 and V3 are increased, and the road link L2 has a curvature. Since it is in a corner with a small radius, the passing speed V2 becomes low, for example,
V1 = 50 [km / h]
V2 = 17 [km / h]
V1 = 50 [km / h]
become. As a result, when the general road recording area of the congestion degree determination table in FIG. 3 is referred to, the congestion degrees of the roads L1 to L3 are empty, congested, and empty, respectively.

  In this way, the degree of congestion is determined by the respective passing speeds V1 to V3. Therefore, when the passing speed V2 is low as in the road link L2, the actual road link L2 has a small amount of traffic and the congestion level is empty. Although it should be determined, it is determined to be crowded. As a result, the accuracy of the travel history data is lowered.

  It is an object of the present invention to provide a travel history collection system and a travel history collection method that can solve the problems of the conventional navigation device and increase the accuracy of travel history data.

  Therefore, in the travel history collection system of the present invention, a current position detection unit that detects the current position, a passing speed calculation processing unit that calculates a passing speed that passes through the road link specified based on the current position, the passing speed and Judgment criteria change processing means for changing the judgment criteria of travel history data based on road conditions on a predetermined road link, and travel history data calculation processing means for calculating travel history data based on the changed judgment criteria. .

  According to the present invention, since the determination criterion of the travel history data is changed based on the passing speed passing through the road link and the road condition on the predetermined road link, the accuracy of the travel history data can be increased.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram showing a navigation system according to the first embodiment of the present invention.

  In the figure, reference numeral 10 denotes an automatic transmission control unit as a power train control unit. The automatic transmission control unit 10 is a power train that performs a shift at a predetermined gear ratio, for example, a continuously variable transmission as an automatic transmission. (CVT), stepped transmission (automatic transmission), electric drive device, etc. are controlled.

  Reference numeral 14 is an information terminal, for example, a navigation device as an in-vehicle device mounted on a vehicle, 63 is a network, 51 is an information center as an information provider, and the automatic transmission control unit 10, the navigation device 14, the network 63, the information center 51 and the like constitute a navigation system.

  The navigation device 14 includes a GPS sensor 15 as a current location detection unit for detecting a current location, a data recording unit 16 as an information recording unit in which various information is recorded in addition to map data, and navigation based on the input information. A navigation processing unit 17 that performs various arithmetic processing such as processing, a direction sensor 18 that serves as a direction detection unit that detects the vehicle direction, and a first input for performing predetermined input when operated by a driver as an operator. An operation unit 34 as an input unit, various displays by an image displayed on a screen (not shown), a display unit 35 as a first output unit for notifying the driver, and a predetermined input by voice A voice input unit 36 as a second input unit, a voice output unit 3 as a second output unit for performing various displays by voice and notifying the driver , And a communication unit 38 as a transmission / reception unit functioning as a communication terminal. The navigation processing unit 17 includes a GPS sensor 15, a data recording unit 16, an orientation sensor 18, an operation unit 34, a display unit 35, a voice input unit 36, An audio output unit 37 and a communication unit 38 are connected.

  The navigation processing unit 17 is attached to the automatic transmission control unit 10, a predetermined position at the front end of the vehicle, and a front monitoring device 48 for monitoring the front of the vehicle, and a predetermined position at the rear end of the vehicle. The rear camera (rear monitoring camera) 49 as an imaging device that captures the rear of the vehicle and an accelerator as an engine load detection unit that detects the operation of the accelerator pedal by the driver based on the accelerator opening A sensor 42, a brake sensor 43 as a braking detection unit that detects the operation of the brake pedal by the driver by a brake depression amount, a vehicle speed sensor 44 as a vehicle speed detection unit that detects the vehicle speed S, and the like are connected. The accelerator sensor 42, the brake sensor 43, and the like constitute a vehicle operation information detection unit for detecting vehicle operation information by the driver.

  The GPS sensor 15 detects the current location on the earth by receiving radio waves generated by an artificial satellite, and also detects the time. In the present embodiment, the GPS sensor 15 is used as the current position detection unit, but a distance sensor, a steering sensor, an altimeter, etc. (not shown) are used alone or in combination instead of the GPS sensor 15. You can also Further, a gyro sensor, a geomagnetic sensor, or the like can be used as the direction sensor 18.

  The data recording unit 16 includes a map database including map data files, and map data is recorded in the map database. The map data includes intersection data relating to intersections, node data relating to nodes, road data relating to road links, driving lanes, search data processed for searching, facility data relating to facilities, and other features related to features. Contains data. The data recording unit 16 also records data for outputting predetermined information by the audio output unit 37.

  Further, the data recording unit 16 is formed with a statistical database composed of statistical data files, a traveling history database composed of traveling history data files, and the like. Statistical data as statistical information is stored in the statistical data file as the traveling history data file. Each of the travel history data as the travel history is recorded as performance data.

  The statistical data is a history of traffic information provided in the past, that is, history information representing a history, and a road traffic information center (not shown) such as a VICS (registered trademark: Vehicle Information and Communication System) center as an information provider. The road traffic census information that is the traffic information provided in the past by the Ministry of Land, Infrastructure, Transport and Tourism, the road traffic census information that is the data representing the traffic volume provided by the Ministry of Land, Infrastructure, Transport and Tourism, the road timetable information provided by the Ministry of Land, Infrastructure, Transport and Tourism, etc. Alternatively, they are used in combination, processed as necessary, and subjected to statistical processing. It is possible to add traffic jam prediction information for predicting traffic jams to the statistical data. In that case, in creating the statistical data, detailed conditions such as date and time, day of the week, weather, various events, seasons, facility information (presence / absence of large facilities such as department stores and supermarkets) are added to the history information.

  The data items of the statistical data include a link number for each road link, a direction flag that represents a traveling direction, an information type that represents a type of information, a congestion level at each predetermined timing when traveling on each road link, It consists of a link required time indicating a required time at every predetermined timing when traveling on a road link, average data for each day of the link required time (for example, day average data), and the like.

  The travel history data is created based on travel data representing the actual travel of the vehicle on the road on which the vehicle has traveled, and is recorded and collected in the data recording unit 16.

  The data items of the travel history data include a link required time at each predetermined timing when traveling on each road link, a degree of congestion at each predetermined timing when traveling on each road link, and the like. Note that travel history data can be added to the statistical data. In the present embodiment, the congestion level is used as a congestion index that represents the degree of congestion, and is represented by congestion, congestion, and free space.

  The travel history data is sent as probe data to the information center 51 as necessary, and is provided from the information center 51 to other vehicles, that is, other vehicles. In this case, of the traveling history data, the own vehicle history data is constituted by the traveling history data of the own vehicle and the other vehicle history data is constituted by the traveling history data of the other vehicle.

  The data recording unit 16 includes a disk (not shown) such as a hard disk, a CD, a DVD, and an optical disk in order to record the various data, and also reads / writes for reading and writing various data. A head (not shown) such as a head is provided. A memory card or the like can be used for the data recording unit 16.

  In the present embodiment, the data recording unit 16 is provided with the map database, statistical database, travel history database, and the like. However, in the information center 51, the map database, statistical database, travel history, etc. A history database or the like can also be provided.

  The navigation processing unit 17 is a control device that performs overall control of the navigation device 14 and a CPU 31 as an arithmetic device, a RAM 32 that is used as a working memory when the CPU 31 performs various arithmetic processes, In addition to the above program, a ROM 33 in which various programs for searching for a route to the destination, route guidance and the like are recorded, and a flash memory (not shown) used for recording various data, programs and the like are provided. .

  In the present embodiment, various programs can be recorded in the ROM 33 and various data can be recorded in the data recording unit 16, but the programs, data, and the like can also be recorded on a disk or the like. In this case, the program, data, etc. can be read from a disk or the like and written to the flash memory. Therefore, the program, data, etc. can be updated by exchanging the disk or the like. Further, the control program, data, and the like of the automatic transmission control unit 10 can be recorded on the disk or the like. Further, the program, data, and the like can be received via the communication unit 38 and written into the flash memory of the navigation processing unit 17.

  The operation unit 34 is operated by the driver to correct the current location at the start of traveling, to input a departure point and a destination, to input a passing point, and to activate the communication unit 38. As the operation unit 34, a keyboard, a mouse, or the like disposed independently of the display unit 35 can be used. Further, as the operation unit 34, a predetermined input operation is performed by touching or clicking a screen operation unit such as various keys, switches, and buttons displayed as images on the screen formed on the display unit 35. It is possible to use a touch panel that can be used.

  A display is used as the display unit 35. Then, on various screens formed on the display unit 35, the current position of the vehicle is displayed as the vehicle position, the vehicle direction is displayed as the vehicle direction, a map, a search route, guidance information along the search route, traffic In addition to displaying information and the like, displaying the distance to the next intersection on the searched route, and the traveling direction at the next intersection, operations on the screen operation unit, operation unit 34, voice input unit 36, etc. It is possible to display guidance, operation menus, key guidance, FM multiplex broadcast programs, and the like.

  The voice input unit 36 includes a microphone (not shown) and the like, and can input necessary information by voice. Further, the voice output unit 37 includes a voice synthesizer and a speaker (not shown), and the search route, guidance information, traffic information, and the like are output from the voice output unit 37, for example, as voice synthesized by the voice synthesizer. .

  The communication unit 38 transmits various information such as current traffic information and general information transmitted from the road traffic information center to radio wave beacons via radio wave beacon devices, optical beacon devices and the like arranged along the road. A beacon receiver for receiving as an optical beacon, an FM receiver for receiving as an FM multiplex broadcast via an FM broadcast station, and the like. The traffic information includes traffic jam information, regulation information, parking lot information, traffic accident information, service area congestion status information, and the like, and general information includes news, weather forecasts, and the like. Further, the beacon receiver and the FM receiver are unitized and arranged as a VICS receiver, but can be arranged separately.

  The traffic information includes an information type that indicates the type of information, a mesh number for specifying a mesh, a road link that connects two points (for example, intersections), and a link that indicates whether it is up / down. Number, including link information representing the content of information provided corresponding to the link number. For example, when the traffic information is traffic jam information, the link information is a distance from the start point of the road link to the head of the traffic jam Congestion head data representing traffic congestion degree, congestion section, traffic jam length representing the distance from the beginning of the traffic jam to the end of the traffic jam, link required time representing the time required to travel on the road link, and the like.

  And the communication part 38 can receive various information, such as traffic information and general information other than data, such as the said map data, statistical data, and driving history data, from the said information center 51 via the network 63. .

  For this purpose, the information center 51 includes a server 53, a communication unit 57 connected to the server 53, a database (DB) 58 as an information recording unit, and the like. A CPU 54, a RAM 55, a ROM 56, etc. are provided as devices. The database 58 records data similar to the various data recorded in the data recording unit 16, for example, the map data, statistical data, travel history data, and the like. Further, the information center 51 provides various information such as current traffic information and general information transmitted from the road traffic information center, and travel history data collected from a plurality of vehicles (own vehicle or other vehicles) in real time. can do.

  The navigation system, the navigation processing unit 17, the CPUs 31, 54, the server 53, and the like function as a computer singly or in combination of two or more, and perform arithmetic processing based on various programs, data, and the like. The data recording unit 16, RAMs 32 and 55, ROMs 33 and 56, database 58, flash memory, and the like constitute a recording medium. An MPU or the like can be used instead of the CPUs 31 and 54 as the arithmetic unit.

  Next, a basic operation of the navigation system having the above configuration will be described.

  First, when the operation unit 34 is operated by the driver and the navigation device 14 is activated, a navigation initialization processing unit (not shown) of the CPU 31 performs a navigation initialization process and detects the current location of the vehicle detected by the GPS sensor 15. The vehicle direction detected by the direction sensor 18 is read, and various data are initialized. Next, the matching processing means (not shown) of the CPU 31 performs matching processing, and based on the trajectory of the read current location and the shape, arrangement, etc. of each road link constituting the road around the current location, The current location is identified by determining whether it is located on the road link.

  Subsequently, a basic information acquisition processing unit (not shown) of the CPU 31 performs a basic information acquisition process and acquires the map data by reading it from the data recording unit 16 or receiving it from the information center 51 or the like via the communication unit 38. And get. In addition, when acquiring map data from the information center 51 etc., the said basic information acquisition process means downloads the received map data to flash memory.

  A display processing unit (not shown) of the CPU 31 performs display processing and forms various screens on the display unit 35. For example, the map display processing means of the display processing means performs a map display process, forms a map screen on the display unit 35, displays a surrounding map on the map screen, and sets the current position as the vehicle position and the direction of the vehicle. Is displayed as the vehicle direction.

  Accordingly, the driver can drive the vehicle according to the map, the vehicle position, and the vehicle direction.

  Further, when the driver operates the operation unit 34 to input a destination, a destination setting processing unit (not shown) of the CPU 31 performs a destination setting process to set the destination. Note that the departure place can be input and set as necessary. Moreover, a predetermined point can be registered in advance, and the registered point can be set as a destination. Subsequently, when the driver operates the operation unit 34 to input a search condition, a search condition setting processing unit (not shown) of the CPU 31 performs a search condition setting process to set the search condition.

  When the destination and the search condition are set in this way, the route search processing unit (not shown) of the CPU 31 performs the route search process, reads the current location, the destination, the search condition, and the like from the data recording unit 16. Based on the current location, the destination, and the search data, a route from the departure point to the destination represented by the current location is searched based on the search condition, and route data representing the searched route is output. At this time, the route with the smallest total link cost assigned to each road link is set as the searched route.

  When a plurality of lanes are formed on the road and a traveling lane is detected, the route search processing means searches for a search route for each lane. In this case, the route data includes the lane number of the traveling lane.

  Subsequently, a guidance processing means (not shown) of the CPU 31 performs guidance processing and provides route guidance. For this purpose, the route display processing means of the guidance processing means performs route display processing, reads the route data, and displays the searched route on the map screen according to the route data. When a search route for each lane is searched, route guidance for each lane is performed at a predetermined point, for example, a guidance intersection, and a travel lane for which route guidance is being performed is displayed in the enlarged intersection view. If necessary, the voice output processing means of the guidance processing means performs voice output processing, and outputs a search route by voice from the voice output unit 37 to provide route guidance.

  The information center 51 can perform a route search process. In that case, the CPU 31 transmits the current location, the destination, search conditions, and the like to the information center 51. When the information center 51 receives the current location, destination, search conditions, etc., the route search processing means (not shown) of the CPU 54 performs route search processing similar to that of the CPU 31 and reads the search data from the database 58 to obtain the current location, destination. Based on the location and the search data, a route from the departure point to the destination is searched under the search conditions, and route data representing the searched route is output. Subsequently, a transmission processing unit (not shown) of the CPU 54 performs transmission processing and transmits the route data to the navigation device 14. Therefore, in the navigation device 14, when the basic information acquisition processing means receives the route data from the information center 51, the guidance processing means performs route guidance as described above.

  And when a guidance intersection exists on the searched route, when the vehicle reaches a route guidance point in front of the guidance intersection by a predetermined distance (for example, X [m]), the intersection enlarged map display processing means of the guidance processing means Performs an enlarged intersection map display process, forms an enlarged intersection map as described above in a predetermined area of the map screen, provides route guidance by the enlarged intersection map, and displays the map around the guided intersection in the enlarged intersection map. When the route guidance for the lane unit is being performed, the travel lane or the like is displayed. Further, if necessary, the voice output processing means outputs a voice such as “This is X [m] to the left” from the voice output unit 37 and performs route guidance.

  By the way, as described above, in the navigation device 14, travel data representing the travel results of the vehicle on the road on which the vehicle traveled is read, travel history data is created based on the travel data, and the data recording unit Is recorded and collected. For this purpose, the travel history collection processing means (not shown) of the CPU 31 performs travel history collection processing, records the travel history, and corrects the travel history as necessary.

  FIG. 4 is a main flowchart showing the operation of the travel history collection processing means in the first embodiment of the present invention.

  First, the initialization processing means of the traveling history collection processing means performs initialization processing and initializes each variable of traveling data. Subsequently, the travel history recording processing means of the travel history collection processing means performs travel history recording processing, reads travel data, calculates travel history data based on the travel data, and records it. Next, the travel history correction processing means of the travel history collection processing means performs travel history correction processing to correct and change the recorded travel history data. In the present embodiment, the degree of congestion in the travel history data is corrected.

  The traveling history collection processing means determines whether the accessory switch is turned off by the driver turning off the ignition switch. When the accessory switch is turned off, the driving history collection processing means ends the process.

Next, the flowchart of FIG. 4 will be described.
Step S1: Variables are initialized.
Step S2 A travel history recording process is performed.
Step S3 A travel history correction process is performed.
Step S4: Determine whether the accessory switch has been turned off. If the accessory switch is turned off, the process ends. If not turned off (turned on), the process returns to step S2.

  Next, a subroutine for the travel history recording process in step S2 in FIG. 4 will be described.

  FIG. 5 is a diagram showing a subroutine for travel history recording processing in the first embodiment of the present invention, FIG. 6 is a diagram showing a subroutine for passage speed calculation processing in the first embodiment of the present invention, and FIG. The figure which shows the example of the road condition in 1st Embodiment of invention, FIG. 8 is the figure which shows the example of the road data in 1st Embodiment of this invention, FIG. 9 is 1st Embodiment of this invention FIG. 10 is a diagram showing a congestion degree determination table in the first embodiment of the present invention.

  In FIG. 7, Li (i = 1, 2,...) Is a road link, and the road length of each road link Li is εi (i = 1, 2,. The radius of curvature as the situation index is Ri (i = 1, 2,...), The passing speed when the vehicle passes the road link Li is Vi (i = 1, 2,...), And the vehicle uses the road link Li. Let τi (i = 1, 2,...) Be the transit time when passing.

  In this case, each road link Li belongs to a road in a mountainous area whose road type is a general road. For example, the road links L1 and L3 form a straight line portion, and as shown in FIG. Whereas R3 is large, the road link L2 forms a corner and the curvature radius R2 is small.

  First, the road link specifying processing means of the travel history recording processing means performs road link specifying processing, reads the current location from the GPS sensor 15, specifies the road link on which the vehicle is driving, It is determined whether or not the vehicle has changed, that is, whether or not the vehicle has traveled one road link ahead in the traveling direction of the vehicle. When the road link on which the vehicle is currently traveling changes, the road link L [n] that is currently traveling is defined as LA in order to obtain the traveling data of the three consecutive links LA to LC. The road link L [n-1] that was traveling the last time is denoted as LB, and the road link L [n-2] that was traveled two times before is denoted as LC.

Subsequently, the passing speed calculation processing means of the travel history recording processing means performs a passing speed calculation process to calculate the passing speed Vi of the road link Li. Therefore, the passing speed calculation processing means, for example, when the vehicle passes a predetermined road link Li, for example, the time when the vehicle reaches the end point pe of the road link Li in FIG. te (i) is read and passing time τi when passing through the road link Li
τi = te (i) −te (i−1) is calculated.

The passage speed calculation processing means reads the link length εi of the road link Li in the road data, and passes the passage speed Vi.
Vi = εi / τi
Is calculated.

  Next, the travel data recording processing means of the travel history recording processing means performs travel data recording processing, and as shown in FIG. 9, the travel data file set in the data recording unit 16 with the passing speed Vi as travel data. To record.

  Subsequently, the travel history data calculation processing means of the travel history recording processing means performs a travel history data calculation process, and a congestion degree determination table shown in FIG. 10 preset in the data recording unit 16 as a determination criterion of the congestion degree. Referring to FIG. 4, the passage speed Vi in each road link Li and the road type to which the road link Li belongs, that is, the degree of congestion corresponding to each of the highway, toll road, and general road are calculated and determined. The congestion degree determination table represents a determination criterion for determining the congestion degree as the travel history data, and the first and second threshold (threshold) values of the passing speed Vi for each congestion degree. The minimum speed Vmin and the maximum speed Vmax are set, and it is determined whether or not the passing speed Vi is equal to or higher than the minimum speed Vmin and lower than the maximum speed Vmax.

  For example, as shown in the first time in FIG. 9, when the passing speeds V1 to V3 of the road links L1 to L3 are 50, 19, and 52 [km / h], the congestion degree determination table of FIG. When referring to the portion of the general road, the degree of congestion of the road links L1 to L3 becomes empty, congested and empty.

  Then, the travel history data recording processing means of the travel history recording processing means performs travel history data recording processing, and records the degree of congestion for each road link Li as travel history data in the travel history data file of the data recording unit 16. .

Next, the flowchart of FIG. 5 will be described.
Step S2-1: Read the current location.
Step S2-2: Determine whether the road link has changed. If the road link has changed, the process returns. If not, the process proceeds to step S2-3.
Step S2-3: Road link L [n] is set to road link LA, road link L [n-1] is set to road link LB, and road link L [n-2] is set to road link LC.
Step S2-4 A passing speed calculation process is performed.
Step S2-5 The degree of congestion is calculated.
Step S2-6: Record the degree of congestion and return.

Next, the flowchart of FIG. 6 will be described.
Step S2-4-1: Reads time te (i).
Step S2-4-2: The passage time τi of the road link Li is calculated.
Step S2-4-3: Read the link length εi.
Step S2-4-4: The passing speed Vi is calculated and the process returns.

  Next, the travel history correction processing subroutine in step S3 of FIG. 4 will be described.

  FIG. 11 is a diagram showing a subroutine for travel history correction processing in the first embodiment of the present invention, FIG. 12 is a diagram showing a subroutine for congestion degree determination table change processing in the first embodiment of the present invention, FIG. These are figures which show the example of the travel history data after the congestion degree determination table change process in the 1st Embodiment of this invention.

  In this case, for example, as shown in FIG. 7, when the road links L1 and L3 are in a straight portion and the road link L2 is in a corner, the passing speeds V1 and V3 when passing through the road links L1 and L3 When the difference from the passing speed V2 when passing through the road link L2 is large, the minimum speed at each degree of congestion at the time of determining the degree of congestion is lowered.

  For this purpose, the determination criterion change condition establishment determination processing means of the travel history correction processing means performs determination criterion change condition establishment determination processing, and whether or not the condition for changing the congestion degree determination table, that is, whether the determination criterion change condition is satisfied. Judging. In this case, the determination criterion change condition includes the first to third conditions, and the determination criterion change condition establishment determination processing unit determines that the determination criterion change condition is satisfied when the first to third conditions are satisfied, If any of the first to third conditions is not satisfied, it is determined that the determination criterion changing condition is not satisfied.

  First, the determination criterion change condition establishment determination processing means determines whether or not the first condition is satisfied depending on whether or not the change reliability is high when the congestion degree determination table is changed. For this purpose, the determination criterion change condition establishment determination processing means refers to the travel data file, the number of travel data for each road link Li recorded in the travel data file, and in this embodiment, the passing speed Vi. Is obtained, and it is determined whether or not the number M is equal to or greater than a threshold value Mth. If the number M is equal to or greater than the threshold value Mth, it is determined that the change reliability is high, and it is determined that the first condition is satisfied. If the number M is smaller than the threshold value Mth, it is determined that the change reliability is low, and it is determined that the first condition is not satisfied. In the present embodiment, the threshold value Mth is set to 3.

  When changing the congestion degree determination table, it is necessary to calculate the average of the passing speed Vi, that is, the average passing speed Vai. The reliability of the average passing speed Vai depends on the parameter of the passing speed Vi (the number of acquisitions). ) Increases as the value increases, and decreases as the parameter decreases. In the present embodiment, as shown in FIG. 9, the passage speed Vi calculated in the first to third passage speed calculation processing is recorded, and the average is calculated with three or more passage speeds Vi. The In the present embodiment, the number M is 3, the change reliability is high, and the first condition is satisfied.

  When the first condition is satisfied, the determination criterion change condition satisfaction determination processing unit determines whether or not the second condition is satisfied depending on whether or not the road condition is suitable for changing the congestion degree determination table. Therefore, in the present embodiment, the determination criterion change condition establishment determination processing unit reads the curvature radius Ri from the road data, determines whether the curvature radius Ri is smaller than a threshold value Rth (150 [m]), and calculates the curvature. When the radius Ri is smaller than the threshold value Rth, it is determined that the road condition is suitable for changing the congestion degree determination table, and it is determined that the second condition is satisfied. When the curvature radius Ri is equal to or greater than the threshold value Rth, it is determined that the road condition is not suitable for changing the congestion degree determination table, and it is determined that the second condition is not satisfied. In the present embodiment, for example, for the road links L1 and L3, since the curvature radii R1 and R3 are larger than the threshold value Rth, the road condition is not suitable for changing the congestion degree determination table, and the second condition Since the curvature radius R2 is smaller than the threshold value Rth for the road link L2, the road condition is suitable for changing the congestion degree determination table, and the second condition is satisfied.

  In this case, the highest lowest speed among the empty minimum speeds in the congestion degree determination table of FIG. 10 is 60 [km / h], and the design speed defined as a safe passing speed by law is 60 [km / h]. Since the radius of curvature of the road h] is 150 [m], the threshold Rth is set to 150 [m].

  Subsequently, when the first and second conditions are satisfied, the determination criterion change condition satisfaction determination processing means determines whether or not the third condition is satisfied depending on whether or not it is highly necessary to change the congestion degree determination table. to decide. Therefore, in this embodiment, the determination criterion change condition establishment determination processing means determines whether the third condition is established based on the relationship between the passage speed of a predetermined road link and the passage speed of an adjacent road link. Judging.

That is, the determination criterion change condition establishment determination processing means reads the average passing speed Vi in the three consecutive road links LA to LC as LB with the road link satisfying the second condition as LB, and sets the road link to VA to VC. It is determined whether or not the average passing speed VB in the link LB is lower than the average passing speeds VA and VC in the adjacent road links LA and LC. Then, the determination criterion conversion condition establishment determination processing means is a speed difference dv1 composed of an absolute value of the difference between the average passing speeds VA and VB.
dv1 = | VA-VB |
And a speed difference dv2 consisting of an absolute value of the difference between the average passing speeds VB and VC
dv2 = | VB-VC |
Is calculated, and it is determined whether at least one of the speed differences dv1 and dv2 is larger than threshold values ρv1 and ρv2 (20 km / h in the present embodiment), and the speed differences dv1 and dv2 When one of them is larger than the threshold values ρv1 and ρv2, it is determined that the necessity of changing the congestion degree determination table is high, and it is determined that the third condition is satisfied. Further, when both of the speed differences dv1 and dv2 are equal to or less than the threshold values ρv1 and ρv2, the determination criterion conversion condition establishment determination processing unit determines that the necessity of changing the congestion degree determination table is low, and the third It is determined that the condition is not satisfied. For example, when the road links L1 to L3 in FIG. 7 are road links VA to VC, the speed differences dv1 and dv2 are:
dv1 = 31.4 [km / h]
dv2 = 31.4 [km / h]
Since both are larger than 20 [km / h], the third condition is satisfied.

  In the present embodiment, the speed difference dv1 constitutes a first passing speed change index, and when the value is large, the change in the vehicle speed when entering the LB from the road link LA is large, and the corner at the road link LB is large. It is considered that the average passing speed VB has become low due to passing through the vehicle, and if the value is small, the change in the vehicle speed when entering the LB from the road link LA is small, regardless of whether the road link LB does not pass through the corner, It can be seen that the average passing speed VB has decreased. Similarly, the speed difference dv2 constitutes a second passing speed change index. When the value is large, the change in the vehicle speed when entering the LC from the road link LB is large, and the road link LB passes the corner. When the average passing speed VB is considered to be low and the value is small, the change in the vehicle speed when entering the LC from the road link LB is small, and the average passing speed VB is not related to passing through the corner at the road link LB. It turns out that it became low.

  In this case, in the congestion degree determination table of FIG. 10, the largest value of the speed difference between the lowest available speed and the lowest crowded speed is 20 [km / h], so the threshold values ρv1 and ρv2 are set to 20 [Km / h].

  In the present embodiment, whether or not the criterion conversion condition is satisfied is determined based on the difference between the average passage speeds VA and VB and the difference between the average passage speeds VB and VC. It is determined whether or not the criteria conversion condition is satisfied based on the ratio of the average passage speeds VA and VB and the ratio of the average passage speeds VB and VC, or the value of a predetermined function using the average passage speeds VA and VB as variables. And whether or not the criterion conversion condition is satisfied can be determined based on the value of a predetermined function having the average passing speeds VB and VC as variables.

  In this way, it is determined whether or not the first to third conditions are satisfied, and when the first to third conditions are satisfied and the determination reference change condition is satisfied, the determination reference change of the travel history correction processing means is performed. The congestion degree determination table change processing means as the processing means performs the congestion degree determination table change process as the determination reference change process, and changes the congestion degree determination table.

For this purpose, the threshold value change processing means of the congestion degree determination table change processing means performs threshold value change processing, and determines a predetermined speed from the average passing speed VB as the standard passing speed, in this embodiment 5 km / h. ] Is subtracted from the minimum free speed Vαmin for the corner.
Vαmin = VB-5
Is calculated. Further, the determination criterion change processing means multiplies the minimum speed Vαmin by a predetermined coefficient, in the present embodiment, 1/2, thereby reducing the corner congestion minimum speed Vβmin.
Vβmin = Vαmin / 2
Are respectively set in the congestion degree determination table of FIG. In the present embodiment, the minimum free speed Vαmin for the corner is
Vαmin = 18.6-5
≒ 14 [km / h]
The minimum congestion speed Vβmin for corners is Vβmin = 14/2
= 7 [km / h]
become. In this way, the congestion degree determination table can be changed.

  Subsequently, the travel history data calculation processing means of the travel history correction processing means performs a travel history data calculation process, refers to the changed traffic congestion degree determination table shown in FIG. 10, and the road links L1 and L3 are general. According to the road determination criteria, the road link L2 is calculated and read by reading out the degree of congestion according to the corner determination criteria. In the present embodiment, the average passing speeds VA and VC in the road links L1 and L3 are 20 [km / h] or more, and the average passing speed VB in the road link L2 is 14 [km / h] or more. The traffic congestion degree of each road link L1 to L3 becomes empty.

  Then, as shown in FIG. 13, the travel history data recording processing means overwrites the travel history data file of the data recording unit 16 and records the congestion degree as travel history data.

  In this way, the congestion degree determination table is changed based on the passing speed Vi and the road condition of each road link Li, and the congestion degree is calculated according to the actual traffic volume of the road, so that the accuracy of the travel history data is increased. be able to.

Next, the flowchart of FIG. 11 will be described.
Step S3-1: The number M of travel data is acquired.
Step S3-2: It is determined whether the number M is equal to or greater than the threshold value Mth. If the number M is greater than or equal to the threshold value Mth, the process proceeds to step S3-3. If the number M is smaller than the threshold value Mth, the process proceeds to step S3-12.
Step S3-3: The curvature radius Ri of the road link Li is read out.
Step S3-4: It is determined whether or not the radius of curvature Ri is smaller than the threshold value Rth. If the curvature radius R is smaller than the threshold value Rth, the process proceeds to step S3-5. If the curvature radius R is greater than or equal to the threshold value Rth, the process proceeds to step S3-12.
Step S3-5 Read the passing speed Vi.
Step S3-6: Average passing speeds VA to VC are calculated.
Step S3-7 The absolute value of the difference between the average passing speeds VA and VB is set to the speed difference dv1, and the absolute value of the difference between the average passing speeds VB and VC is set to the speed difference dv2.
Step S3-8: It is determined whether the speed difference dv1 is larger than the threshold value ρv1 or whether the speed difference dv2 is larger than the threshold value ρv2. If the speed difference dv1 is greater than the threshold value ρv1, or if the speed difference dv2 is greater than the threshold value ρv2, the process proceeds to step S3-9. Proceed to step S3-12.
Step S3-9 A congestion degree determination table changing process is performed.
Step S3-10 Calculate the degree of congestion.
Step S3-11 Overwrite the congestion degree.
Step S3-12 Increment the value n and return.

Next, the flowchart of FIG. 12 will be described.
Step S3-9-1: Calculate and set the minimum available speed Vαmin.
Step S3-9-2: Calculate, set, and return the minimum congestion speed Vβmin.

  Next, a second embodiment of the present invention will be described.

  In this case, the travel history recording processing means of the travel history collection processing means records the travel history and corrects and changes the travel history as necessary.

  FIG. 14 is a main flowchart showing the operation of the travel history collection processing means in the second embodiment of the present invention.

  First, the initialization processing means of the travel history collection processing means initializes each variable of travel data. Subsequently, the travel history recording processing means of the travel history collection processing means reads travel data, calculates travel history data based on the travel data, and records it.

  The traveling history collection processing means determines whether the accessory switch is turned off by the driver turning off the ignition switch. When the accessory switch is turned off, the driving history collection processing means ends the process.

Next, the flowchart of FIG. 14 will be described.
Step S11: Variables are initialized.
Step S12 A travel history recording process is performed.
Step S13: It is determined whether or not the accessory switch has been turned off. If the accessory switch is turned off, the process ends. If not turned off (turned on), the process returns to step S12.

  FIG. 15 is a diagram showing a subroutine of travel history recording processing according to the second embodiment of the present invention, FIG. 16 is a diagram showing a subroutine of congestion level table changing processing according to the second embodiment of the present invention, and FIG. The figure which shows the example of the road condition in the 2nd Embodiment of this invention, FIG. 18 is the figure which shows the congestion degree determination table in the 2nd Embodiment of this invention, FIG. 19 is the 2nd Embodiment of this invention It is a figure which shows the example of the travel history data after the congestion degree determination table change process in a form.

  In FIG. 17, Li (i = 1, 2,...) Is a road link, the road length of each road link Li is εi (i = 1, 2,...), And the road represents the road condition of each road link Li. The radius of curvature as the situation index is Ri (i = 1, 2,...), The passing speed when the vehicle passes the road link Li is Vi (i = 1, 2,...), And the vehicle uses the road link Li. Let τi (i = 1, 2,...) Be the transit time when passing.

  In this case, each road link Li belongs to a road in a mountainous area whose road type is a general road. For example, the road links L1 and L3 form a straight line portion, and as shown in FIG. Whereas R3 is large, the road link L2 forms a corner and the curvature radius R2 is small.

  First, the road link identification processing means of the travel history recording processing means reads the current location from the GPS sensor 15 (FIG. 1) as the current location detection unit, identifies the road link on which the vehicle is traveling, and currently travels the road. It is determined whether or not the link has changed, that is, whether or not the vehicle has traveled the next road link in the traveling direction of the vehicle. When the road link on which the vehicle is currently traveling changes, the road link L [n] that is currently traveling is defined as LA in order to obtain the traveling data of the three consecutive links LA to LC. The road link L [n-1] that was traveling the last time is denoted as LB, and the road link L [n-2] that was traveled two times before is denoted as LC.

  Subsequently, the passing speed calculation processing means of the travel history recording processing means calculates the passing time τi when passing through the road link Li and reads the link length εi in the same manner as in the first embodiment. The passage speed Vi of the link Li is calculated.

  Next, the congestion degree determination table change processing means as the determination reference change processing means of the travel history recording processing means changes the congestion degree determination table as the determination reference.

  Therefore, the determination criterion change condition establishment determination processing unit of the congestion degree determination table change processing unit determines whether or not the determination criterion change condition is satisfied depending on whether the road condition is suitable for changing the congestion degree determination table. To do. Therefore, in the present embodiment, the determination criterion change condition establishment determination processing means reads the curvature radius Ri from the road data, determines whether the curvature radius Ri is smaller than the threshold value Rth (150 [m]), and the curvature radius. When Ri is smaller than the threshold value Rth, it is determined that the road condition is suitable for changing the congestion degree determination table, and it is determined that the determination criterion changing condition is satisfied. If the curvature radius Ri is equal to or greater than the threshold value Rth, it is determined that the road condition is not suitable for changing the congestion degree determination table, and it is determined that the determination criterion change condition is not satisfied. In the present embodiment, for example, for the road links L1 and L3, since the curvature radii R1 and R3 are larger than the threshold value Rth, the road condition is not suitable for changing the congestion degree determination table, and the determination criterion change condition Since the curvature radius R2 is smaller than the threshold value Rth for the road link L2, the road condition is suitable for changing the congestion degree determination table, and the determination criterion change condition is satisfied.

  In this case, the highest minimum speed among the free minimum speeds in the congestion degree determination table of FIG. 18 is 60 [km / h], and the design speed defined as a safe passing speed by law is 60 [km / h]. Since the curvature radius of the road h] is 150 [m], the threshold Rth is set to 150 [m].

Subsequently, when the determination criterion change condition is satisfied, the threshold value change processing unit of the congestion degree determination table change processing unit, in the present embodiment, sets the curvature radius R2 of the road link L2 that satisfies the determination criterion change condition. Read out, the theoretical passing speed Vs as the standard passing speed so that the lateral acceleration of the road link L2 is 0.2 × g or less.
Vs = K × √ (0.2 × g · R2)
= 19.5 [km / h]
Is calculated. K is a coefficient for converting the unit and is 3.6. Moreover, g is a gravitational acceleration and is 9.8 [m / s ² ].

Next, the threshold value changing processing means subtracts a predetermined speed, in this embodiment, 5 [km / h] from the theoretical passing speed Vs of the road link L2, to thereby reduce the minimum free speed Vαmin for the corner.
Vαmin = Vs−5
= 19.5-5
≒ 15 [km / h]
Is calculated. Further, the threshold value changing processing means multiplies the minimum speed Vαmin by a predetermined coefficient, in this embodiment, 1/2, thereby reducing the corner congestion minimum speed Vβmin.
Vβmin = Vαmin / 2
= 15/2
≒ 8 [km / h]
Are respectively set in the congestion degree determination table of FIG. In the present embodiment, the minimum free speed Vαmin for the corner is
Vαmin = 15-5
≒ 14 [km / h]
The minimum congestion speed Vβmin for corners is Vβmin = 14/2
= 7 [km / h]
become. In this way, the congestion degree determination table can be changed.

  Subsequently, the travel history data calculation processing means of the travel history recording processing means refers to the changed traffic congestion degree judgment table shown in FIG. 18, and for the road links L1 and L3, the road link is determined according to the judgment criteria for general roads. L2 is calculated and read by reading out the degree of traffic jam according to the corner criterion. In the present embodiment, the average passing speeds VA and VC in the road links L1 and L3 are 20 [km / h] or more, and the average passing speed VB in the road link L2 is 15 [km / h] or more. The traffic congestion degree of each road link L1 to L3 becomes empty.

  Then, as shown in FIG. 19, the travel history data recording processing means records the degree of congestion as travel history data in the travel history data file of the data recording unit 16.

  In this way, the congestion degree determination table is changed based on the passing speed Vi and the road condition of each road link Li, and the congestion degree is calculated according to the actual traffic volume of the road, so that the accuracy of the travel history data is increased. be able to.

Next, the flowchart of FIG. 15 will be described.
Step S12-1 Read the current location.
Step S12-2: Determine whether the road link has changed. If the road link has changed, the process returns. If not, the process proceeds to step S12-3.
Step S12-3: Road link L [n] is set to road link LA, road link L [n-1] is set to road link LB, and road link L [n-2] is set to road link LC.
Step S12-4 A passing speed calculation process is performed.
Step S12-5 A congestion degree determination table changing process is performed.
Step S12-6: Calculate the degree of congestion.
Step S12-7: Record the degree of traffic jam and return.

Next, the flowchart of FIG. 16 will be described.
Step S12-5-1: The curvature radius Ri of the road link Li is read out.
Step S12-5-2: It is determined whether or not the radius of curvature Ri is smaller than the threshold value Rth. When the curvature radius Ri is smaller than the threshold value Rth, the process proceeds to S12-5-3, and when the curvature radius Ri is equal to or larger than the threshold value Rth, the process returns.
Step S12-5-3: Calculate and set an empty minimum speed Vαmin.
Step S12-5-4: Calculate, set and return the minimum congestion speed Vβmin.

  In the first and second embodiments, the determination criterion change condition establishment determination processing means determines whether the determination criterion change condition is satisfied based on the curvature radius Ri of each road link Li as a road condition index. As a road condition indicator, use the road width, the number of lanes to run, and the gradient of each road link Li to determine whether the criteria change condition is met. Can do.

  Next, a description will be given of a third embodiment of the present invention in which it is determined whether or not the determination criterion changing condition is satisfied using the width of the road in each road link Li, the number of traveling lanes, and the like.

  FIG. 20 is a diagram showing an example of road conditions in the third embodiment of the present invention, FIG. 21 is a diagram showing an example of road data in the third embodiment of the present invention, and FIG. 22 is a diagram of the third embodiment of the present invention. The figure which shows the example of the driving | running | working data in embodiment of this, FIG. 23 is a figure which shows the congestion degree determination table in the 3rd Embodiment of this invention.

  In FIG. 20, Li (i = 1, 2,...) Is a road link, and the road length of each road link Li is εi (i = 1, 2,...), And the road represents the road condition of each road link Li. The width as a situation index is Wi (i = 1, 2,...), The number of lanes, that is, the number of lanes is Ni (i = 1, 2,...), And the vehicle passes through the road link Li. Let the passing speed be Vi (i = 1, 2,...), And let the passing time when the vehicle passes through the road link Li be τi (i = 1, 2,...). A road width variable is constituted by the width Wi and the number of lanes Ni. The road width variable increases when the width Wi is large or when the number of lanes Ni is large, and decreases when the width Wi is small or the number of lanes Ni is small.

  In this case, each road link Li belongs to a road whose road type is a general road. For example, the road links L1 and L3 constitute a wide road portion, and as shown in FIG. 21, the width Wi is large or the lane Whereas the number Ni is large, the road link L2 forms a narrow road portion, and the width Wi is small or the lane number Ni is small.

  Next, a description will be given of a travel history correction process in which it is determined whether a criterion changing condition is satisfied based on the width Wi.

  In this case, when the difference between the passing speeds V1 and V3 when passing the road links L1 and L3 and the passing speed V2 when passing the road link L2 is large, The minimum speed in degrees is lowered.

  For this purpose, the determination criteria change condition establishment determination processing means of the travel history correction processing means performs determination criterion change condition establishment determination processing, and the condition for changing the congestion degree determination table as the determination reference, that is, the determination criterion change condition is Determine whether it is true. In this case, the determination criterion change condition includes the first to third conditions, and the determination criterion change condition establishment determination processing unit determines that the determination criterion change condition is satisfied when the first to third conditions are satisfied, If any of the first to third conditions is not satisfied, it is determined that the determination criterion changing condition is not satisfied.

  First, the determination criterion change condition establishment determination processing means refers to the travel data file as in the first embodiment, the number of travel data for each road link Li recorded in the travel data file, this embodiment In the embodiment, the number M of passage speeds Vi is acquired, and it is determined whether or not the number M is equal to or greater than a threshold value Mth. If the number M is equal to or greater than the threshold value Mth, it is determined that the first condition is satisfied.

  When the first condition is satisfied, the determination criterion change condition satisfaction determination processing unit determines whether or not the second condition is satisfied depending on whether or not the road condition is suitable for changing the congestion degree determination table. Therefore, in the present embodiment, the determination criterion change condition establishment determination processing means reads the width Wi from the road data, and the width Wi is set to a threshold value Wth (in the present embodiment, 6 [m]). If the width Wi is smaller than the threshold value Wth, it is determined that the road condition is suitable for changing the congestion degree determination table, and it is determined that the second condition is satisfied. When the width Wi is equal to or greater than the threshold value Wth, it is determined that the road condition is not suitable for changing the congestion degree determination table, and it is determined that the second condition is not satisfied. In the present embodiment, for example, for the road links L1 and L3, the widths W1 and W3 are larger than the threshold value Wth, so the road condition is not suitable for changing the congestion degree determination table, and the second condition is Since the width W2 is smaller than the threshold value Wth for the road link L2, the road condition is suitable for changing the congestion degree determination table, and the second condition is satisfied.

  Subsequently, when the first and second conditions are satisfied, the determination criterion change condition satisfaction determination processing means, as in the first embodiment, passes through a predetermined road link and the passage of an adjacent road link. It is determined whether the third condition is satisfied based on the relationship with the speed.

That is, the determination criterion change condition establishment determination processing means reads the average passing speed Vi in the three consecutive road links LA to LC as LB with the road link satisfying the second condition as LB, and sets the road link to VA to VC. It is determined whether or not the average passing speed VB in the link LB is lower than the average passing speeds VA and VC in the adjacent road links LA and LC. Then, the determination criterion conversion condition establishment determination processing means is a speed difference dv1 composed of an absolute value of the difference between the average passing speeds VA and VB.
dv1 = | VA-VB |
And a speed difference dv2 consisting of an absolute value of the difference between the average passing speeds VB and VC
dv2 = | VB-VC |
Is calculated, and it is determined whether at least one of the speed differences dv1 and dv2 is larger than threshold values ρv1 and ρv2 (20 km / h in the present embodiment), and the speed differences dv1 and dv2 When one of them is larger than the threshold values ρv1 and ρv2, it is determined that the necessity of changing the congestion degree determination table is high, and it is determined that the third condition is satisfied. Further, when both of the speed differences dv1 and dv2 are equal to or less than the threshold values ρv1 and ρv2, the determination criterion conversion condition establishment determination processing unit determines that the necessity of changing the congestion degree determination table is low, and the third It is determined that the condition is not satisfied. For example, when the road links L1 to L3 in FIG. 20 are road links VA to VC, the speed differences dv1, dv2 are:
dv1 = 21.4 [km / h]
dv2 = 26.4 [km / h]
Since both are larger than 20 [km / h], the third condition is satisfied.

  In this way, it is determined whether or not the first to third conditions are satisfied, and when the first to third conditions are satisfied and the determination reference change condition is satisfied, the determination reference change of the travel history correction processing means is performed. The congestion degree determination table change processing means as the processing means performs the congestion degree determination table change process as the determination reference change process, and changes the congestion degree determination table.

For this purpose, the threshold value change processing means of the congestion degree determination table change processing means performs threshold value change processing, and determines a predetermined speed from the average passing speed VB as the standard passing speed, in this embodiment 5 km / h. ] Is subtracted from the minimum free speed Vαmin for narrow roads.
Vαmin = VB-5
Is calculated. Further, the determination criterion change processing means multiplies the minimum speed Vαmin by a predetermined coefficient, in the present embodiment, 1/2, thereby reducing the minimum speed Vβmin of congestion for narrow roads.
Vβmin = Vαmin / 2
Are respectively set in the congestion degree determination table of FIG. In the present embodiment, the minimum free speed Vαmin for narrow roads is
Vαmin = 18.6-5
≒ 14 [km / h]
The minimum congestion speed Vβmin for a narrow road is Vβmin = 14/2
= 7 [km / h]
become. In this way, the congestion degree determination table can be changed.

  Subsequently, the travel history data calculation processing means of the travel history correction processing means performs a travel history data calculation process, refers to the changed traffic congestion degree determination table shown in FIG. 23, and is generally used for the road links L1 and L3. According to the road determination criteria, the road link L2 is calculated and read by reading out the degree of congestion according to the narrow road determination criteria. In the present embodiment, the average passing speeds VA and VC in the road links L1 and L3 are 20 [km / h] or more, and the average passing speed VB in the road link L2 is 14 [km / h] or more. The traffic congestion degree of each road link L1 to L3 becomes empty.

  In the present embodiment, it is determined whether or not the second condition is satisfied depending on whether or not the width Wi of the road width variable is smaller than the threshold value Wth. However, the lane number Ni is less than the threshold value Nth. Whether or not the second condition is satisfied can be determined based on whether or not the number is small.

  In addition, this invention is not limited to the said embodiment, It can change variously based on the meaning of this invention, and does not exclude them from the scope of the present invention.

It is a figure which shows the navigation system in the 1st Embodiment of this invention. It is a figure which shows the example of a road condition. It is a figure which shows the conventional congestion degree determination table. It is a main flowchart which shows operation | movement of the driving history collection process means in the 1st Embodiment of this invention. It is a figure which shows the subroutine of the travel history recording process in the 1st Embodiment of this invention. It is a figure which shows the subroutine of the passage speed calculation process in the 1st Embodiment of this invention. It is a figure which shows the example of the road condition in the 1st Embodiment of this invention. It is a figure which shows the example of the road data in the 1st Embodiment of this invention. It is a figure which shows the example of the driving | running | working data in the 1st Embodiment of this invention. It is a figure which shows the congestion degree determination table in the 1st Embodiment of this invention. It is a figure which shows the subroutine of the travel history correction process in the 1st Embodiment of this invention. It is a figure which shows the subroutine of the congestion degree determination table change process in the 1st Embodiment of this invention. It is a figure which shows the example of the travel history data after the congestion degree determination table change process in the 1st Embodiment of this invention. It is a main flowchart which shows operation | movement of the travel history collection process means in the 2nd Embodiment of this invention. It is a figure which shows the subroutine of the travel history recording process in the 2nd Embodiment of this invention. It is a figure which shows the subroutine of the congestion degree table change process in the 2nd Embodiment of this invention. It is a figure which shows the example of the road condition in the 2nd Embodiment of this invention. It is a figure which shows the congestion degree determination table in the 2nd Embodiment of this invention. It is a figure which shows the example of the travel history data after the congestion degree determination table change process in the 2nd Embodiment of this invention. It is a figure which shows the example of the road condition in the 3rd Embodiment of this invention. It is a figure which shows the example of the road data in the 3rd Embodiment of this invention. It is a figure which shows the example of the driving | running | working data in the 3rd Embodiment of this invention. It is a figure which shows the congestion degree determination table in the 3rd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Automatic transmission control part 14 Navigation apparatus 15 GPS sensor 31 CPU
51 Information Center 63 Network Li Road Link

Claims (7)

  Current position detection unit for detecting the current position, passing speed calculation processing means for calculating a passing speed passing through the road link specified based on the current position, and travel history data based on the passing speed and the road condition on the predetermined road link And a travel history data calculation processing means for calculating travel history data based on the changed determination criteria. A travel history collection system comprising:   In addition to having a determination criterion change condition establishment determination processing means for determining whether a determination criterion change condition representing a condition for changing the determination criterion is satisfied, the determination criterion change processing means, when the determination criterion change condition is satisfied, The travel history collection system according to claim 1, wherein a determination criterion for the travel history data is changed.   The travel history collection system according to claim 2, wherein the determination criterion change condition establishment determination processing unit determines whether the determination criterion change condition is satisfied based on whether or not the number of recorded passing speeds is equal to or greater than a threshold value.   The travel history collection system according to claim 2, wherein the determination criterion change condition establishment determination processing unit determines whether the determination criterion change condition is satisfied based on whether the radius of curvature is smaller than a threshold value.   The travel history collection system according to claim 2, wherein the determination criterion change condition establishment determination processing unit determines whether the determination criterion change condition is satisfied based on whether the road width index is smaller than a threshold value.   The determination criterion change condition establishment determination processing unit determines whether or not the determination criterion change condition is satisfied based on a relationship between a passing speed of a predetermined road link and a passing speed of an adjacent road link. Travel history collection system.   Calculate the passing speed passing through the road link specified based on the current location, change the judgment criteria of the travel history data based on the passing speed and the road condition on the predetermined road link, and based on the changed judgment criteria And running history data is calculated.

Images