JP2017067450A - Positional relation acquisition system, method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique to obtain positional relation between a vehicle and a control target spot over a long-distance section with high accuracy.SOLUTION: A positional relation acquisition system comprises: a starting spot acquisition unit that acquires a starting spot of distance in vehicle control; a control target spot acquisition unit that acquires a control target spot in the vehicle control; and a positional relation acquisition unit that acquires positional relation between a vehicle and the control target spot by first method not using GPS if distance from the starting spot is equal to or less than a threshold value, and acquires positional relation between the vehicle and the control target spot by second method using GPS if distance from the starting spot is larger than the threshold value.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a positional relationship acquisition system, method, and program for acquiring a positional relationship between a vehicle and a control target point.

  Conventionally, in a navigation device using road-to-vehicle communication such as DSSS (Driving Safety Support Systems), a technique for displaying a warning screen according to a distance to a target point that is a target of road traffic information is known (for example, Patent Document 1). Various techniques are known as techniques for obtaining the distance. For example, Patent Document 1 discloses absolute position information of the vehicle by GPS satellites and various sensors (sensors attached to wheels) mounted on the vehicle. Etc.) is disclosed that uses the relative position information of the vehicle according to the output of the above.

Japanese Patent Laying-Open No. 2015-1917

In the prior art, the accuracy of the acquired distance may be insufficient. For example, in the configuration in which the distance is acquired based on the output pulse of the sensor attached to the wheel, the distance error increases as the distance increases. Therefore, in the case where vehicle control is performed on a traffic signal over a long distance (several kilometers) by road-to-vehicle communication that has been developed in recent years, the accuracy of the distance may be insufficient due to an error.
The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique for acquiring a positional relationship between a vehicle and a control target point with high accuracy over a long distance section.

  In order to achieve the above object, the positional relationship acquisition system includes a calculation point acquisition unit that acquires a calculation point of a distance in vehicle control, a control target point acquisition unit that acquires a control target point in vehicle control, and If the distance is less than or equal to the threshold value, the positional relationship between the vehicle and the control target point is acquired by the first method that does not use GPS. If the distance from the starting point is greater than the threshold value, the second method that uses GPS A positional relationship acquisition unit that acquires a positional relationship with the control target point.

  In order to achieve the above object, the positional relationship acquisition method includes a starting point acquisition step of acquiring a starting point of distance in vehicle control, a control target point acquiring step of acquiring a control target point in vehicle control, and a starting point If the distance from the vehicle is less than or equal to the threshold, the positional relationship between the vehicle and the control target point is obtained by the first method that does not use GPS. If the distance from the starting point is greater than the threshold, the second method that uses GPS A positional relationship acquisition step of acquiring a positional relationship between the vehicle and the control target point.

  Furthermore, in order to achieve the above object, the positional relationship acquisition program includes a starting point acquisition function for acquiring a starting point of a distance in vehicle control, a control target point acquiring function for acquiring a control target point in vehicle control, and a starting point If the distance from the vehicle is less than or equal to the threshold, the positional relationship between the vehicle and the control target point is obtained by the first method that does not use GPS. If the distance from the starting point is greater than the threshold, the second method that uses GPS A computer is made to realize a positional relationship acquisition function for acquiring a positional relationship between a vehicle and a point to be controlled.

  As described above, the positional relationship acquisition system, method, and program do not use GPS when the distance from the starting point is short, and use the GPS when the distance from the starting point is long. And the positional relationship between the control target points. That is, in the first method that does not use GPS (GPS signal), for example, the technology that specifies the distance from the starting point based on the output of the in-vehicle sensor without using the GPS, it accumulates as the distance from the starting point increases. The error also increases. Accordingly, when the distance from the starting point is short, the error is small, and the positional relationship between the vehicle and the control target point can be obtained very accurately by using the first method.

  On the other hand, in the second method using GPS, although the accuracy of position identification may fluctuate due to the influence of multipath or the like, as long as the GPS signal can be acquired, the error does not continue to increase cumulatively with the distance. . Therefore, when the second method is used, the positional relationship between the vehicle and the control target point can be acquired with accuracy within the upper limit error, whether the distance from the calculation point is short or long. it can.

  Therefore, when the distance from the starting point is short, the first method is more accurate than the second method, and when the distance from the starting point is long, the second method is more accurate than the first method. Can be considered. Therefore, in the positional relationship acquisition system, method, and program, based on the threshold value, the first method is used when the first method is more accurate, and the second method is used when the second method is more accurate. The configuration is adopted. As a result, it is possible to acquire the positional relationship between the vehicle and the control target point with high accuracy over a long distance section.

It is a block diagram of the navigation terminal containing a positional relationship acquisition system. It is a flowchart which shows a vehicle control process. FIG. 3A is a flowchart showing a flag setting process, and FIG. 3B is a diagram showing a control section.

Here, embodiments of the present invention will be described in the following order.
(1) Configuration of navigation terminal:
(2) Vehicle control processing:
(2-1) Flag setting process:
(3) Other embodiments:

(1) Configuration of navigation terminal:
FIG. 1 is a block diagram showing a configuration of a navigation terminal 10 including a positional relationship acquisition system according to the present invention. The navigation terminal 10 is provided in a vehicle, and includes a control unit 20 including a CPU, a RAM, a ROM, and the like, and a recording medium 30. The navigation terminal 10 can execute a program stored in the recording medium 30 or the ROM by the control unit 20. Map information 30a is recorded in the recording medium 30 in advance. The map information 30a is information used to specify the position of the vehicle and the point to be controlled, and specifies node data indicating the position of the node set on the road on which the vehicle travels, and the shape of the road between the nodes. This includes shape interpolation point data indicating the position of the shape interpolation point, etc., link data indicating connection between nodes, feature data indicating the position of the feature existing on the road and its surroundings, and the like.

  Moreover, in the map information 30a in this embodiment, the information regarding a signalized intersection is matched with node data. That is, when there is a traffic light at the intersection indicated by the node, the intersection is defined as a signal intersection, and the node data is associated with information indicating whether or not the intersection is a signal intersection. At least a part of the signalized intersection is associated with information indicating that the intersection is a signalized intersection with periodic information indicating the timing at which the traffic signal changes. Note that the period information can be acquired in various modes, and may be included in the map information 30a in advance as in the present embodiment, or may be acquired from an external device through various communications.

  Furthermore, the vehicle in the present embodiment includes a GPS receiver 41, a vehicle speed sensor 42, a gyro sensor 43, a beacon communication unit 44, and a user I / F unit 45. The GPS receiver 41 receives a radio wave from a GPS satellite and outputs a signal indicating a signal for calculating the current position of the vehicle via an interface (not shown). The control unit 20 acquires this signal and acquires the current position of the vehicle. The vehicle speed sensor 42 outputs a pulse signal corresponding to the rotation of the wheels provided in the vehicle.

  The control unit 20 acquires this signal via an interface (not shown), and acquires the vehicle speed based on the number of pulses per time. The gyro sensor 43 detects angular acceleration about turning in the horizontal plane of the vehicle, and outputs a signal corresponding to the direction of the vehicle. The control unit 20 acquires this signal and acquires the traveling direction of the vehicle. The vehicle speed sensor 42, the gyro sensor 43, and the like are used for specifying the travel locus of the vehicle. In the present embodiment, the current position is specified based on the departure position and the travel locus of the vehicle, and the departure position and the travel are determined. The current position of the vehicle specified based on the trajectory is corrected based on the output signal of the GPS receiver 41. As described above, the method of specifying the current position of the vehicle based on the output signals of the GPS receiver 41, the vehicle speed sensor 42, and the gyro sensor 43 is the second method.

  The beacon communication unit 44 is a device that performs two-way communication with a communication device installed on a road, receives a signal transmitted from the communication device, and outputs a signal including arbitrary information to the communication device. can do. In the present embodiment, an optical (optical beacon system) communication device is employed, but other systems may be used.

  The user I / F unit 45 is an interface unit for providing various information to the driver, and includes a display unit, a voice output unit, an input unit, and the like (not shown). The control unit 20 can perform route guidance for traveling along the planned travel route to the driver of the vehicle using the current position of the vehicle and the map information 30a by the function of a navigation program (not shown). It is.

  In the present embodiment, the function of the navigation program can perform vehicle control for assisting the driver for the purpose of reducing the frequency of stopping at signalized intersections. Specifically, when the periodic information of the traffic light is associated with the map information 30a about the signalized intersection existing in front of the vehicle, the control unit 20 can pass without stopping by the traffic signal of the signalized intersection. Provide support for changing the vehicle speed. The said vehicle control is implement | achieved by the vehicle control program 21 with which a navigation program is provided. The vehicle control program 21 includes a counting point acquisition unit 21a, a control target point acquisition unit 21b, a positional relationship acquisition unit 21c, and a vehicle control unit 21d.

  The starting point acquisition unit 21a is a program module that causes the control unit 20 to realize a function of acquiring a starting point of distance in vehicle control. In the present embodiment, the control unit 20 acquires a position on the road that is regarded as the position of a communication device installed on the road as a starting point. The position on the road can be specified by various methods, and in the present embodiment, the control unit 20 performs the GPS reception unit 41, the vehicle speed sensor 42, the gyro sensor at the timing when the beacon communication unit 44 communicates with the communication device. Based on the output signal 43, the current position of the vehicle is specified, and a starting point is acquired by providing a margin determined beforehand by statistics or the like for the current position.

  The control target point acquisition unit 21b is a program module that causes the control unit 20 to realize a function of acquiring a control target point in vehicle control. That is, the control unit 20 refers to the map information 30a, and acquires a signalized intersection associated with the period information and existing in front of the vehicle as a control target point.

  The positional relationship acquisition unit 21c acquires the positional relationship between the vehicle and the control target point by the first method that does not use GPS when the distance from the calculation point is equal to or less than the threshold value, and the distance from the calculation point is greater than the threshold value. A program module that causes the control unit 20 to realize the function of acquiring the positional relationship between the vehicle and the control target point by the second method using GPS.

  In the present embodiment, the travel distance for each pulse output from the vehicle speed sensor 42 is specified in advance. Therefore, if the control unit 20 counts the pulses output from the vehicle speed sensor 42 after the starting point, the control unit 20 can acquire the travel distance of the vehicle after the starting point. And if the position of the control target point is specified, the relationship between the control target point and the counting point becomes clear. Therefore, the control unit 20 specifies the distance from the counting point and determines the position of the vehicle and the control target point. The positional relationship of can be clarified. The position of the control target point may be specified by various methods. For example, the position of the signal intersection or stop line as the control target point may be specified based on the map information 30a, or a signal from the beacon communication unit 44 may be specified. You may specify by acquiring the distance to an intersection and a stop line. The above method is a method for acquiring a positional relationship with reference to a starting point that is a position of a vehicle specified by optical beacon communication (road-to-vehicle communication). In this embodiment, this method is the first method. It is.

  On the other hand, in the present embodiment, as described above, the current position of the vehicle can be acquired based on the output signals of the GPS receiver 41, the vehicle speed sensor 42, and the gyro sensor 43. Therefore, if the control unit 20 specifies the position of the control target point (signal intersection) based on the map information 30a, the positional relationship between the vehicle and the control target point can be acquired. In the present embodiment, this method is the second method. The above method specifies the current position of the vehicle by correcting the relative position acquired based on the output signals of the vehicle speed sensor 42 and the gyro sensor 43 with the absolute position acquired based on the output signal of the GPS receiver 41. The position of the vehicle is specified based on the relative position based on the absolute position. In this method, the absolute position is acquired based on the output signal of the GPS receiver 41, and this method is a method of acquiring the positional relationship based on the position of the vehicle specified by the GPS signal. In the present embodiment, this method is the second method.

  When the above first method and the second method are compared, the distance dependency of the error is different. That is, in the first method that does not use GPS, an error factor can increase with an increase in travel distance, so that an accumulated error also increases with an increase in distance from the starting point. Accordingly, when the distance from the starting point is short, the error is small, and the positional relationship between the vehicle and the control target point can be obtained very accurately by using the first method.

  On the other hand, in the second method using GPS, although the accuracy of position identification may fluctuate due to the influence of multipath or the like, as long as the GPS signal can be acquired, the error does not continue to increase cumulatively with the distance. . Therefore, when the second method is used, the positional relationship between the vehicle and the control target point can be acquired with accuracy within the upper limit error, whether the distance from the calculation point is short or long. it can. Therefore, when the distance from the starting point is short, the first method is more accurate than the second method, and when the distance from the starting point is long, the second method is more accurate than the first method. Can be considered.

  Therefore, in the present embodiment, the control unit 20 specifies whether or not the distance from the calculation point is short by comparing the distance with a threshold value. That is, in the present embodiment, the error per unit distance that occurs in the first method is specified in advance by statistics, and the maximum error (the radius of the error circle) that occurs in the second method is specified in advance by statistics. A distance value at which the error in the first method becomes worse than the error in the second method is specified in advance as a threshold and recorded on the recording medium 30 (not shown).

  Then, the control unit 20 compares the distance from the calculation point with a threshold value, and if the distance from the calculation point is equal to or less than the threshold value, acquires the positional relationship between the vehicle and the control target point using the first method that does not use GPS. If the distance from the starting point is larger than the threshold, the positional relationship between the vehicle and the control target point is acquired by the second method using GPS. According to the above configuration, the vehicle and the vehicle are controlled by a method with a relatively small error between the first method and the second method both when the distance from the calculation point is equal to or smaller than the threshold and when the distance is larger than the threshold. The positional relationship with the target point is acquired. As a result, it is possible to acquire the positional relationship between the vehicle and the control target point with high accuracy over a long distance section.

  The vehicle control unit 21d is a program module that causes the control unit 20 to execute a function of executing vehicle control based on the positional relationship between the vehicle and the control target point. That is, when the positional relationship between the vehicle and the control target point is acquired by the processing of the positional relationship acquisition unit 21c, the control unit 20 refers to the map information 30a and displays the traffic signal at the signalized intersection as the control target point. Identify when to change. Moreover, the control part 20 acquires the present vehicle speed of a vehicle based on the output signal etc. of the vehicle speed sensor 42, and pinpoints the timing which arrives at the signal intersection as a control object point, when drive | working with the present vehicle speed. Then, the control unit 20 outputs a control signal to the user I / F unit 45 when the display at the timing is a display that can pass the signalized intersection, and performs control when the speed is maintained. A guide indicating that the vehicle can pass without stopping at the signalized intersection as the target point is output.

  On the other hand, when the indication at the timing of reaching the signalized intersection is an indication that the signalized intersection cannot be passed, the control unit 20 performs the deceleration within the specified range to perform the signalized intersection at a timing that can pass through the signalized intersection. Whether or not can be reached. For example, the control unit 20 controls the user I / F unit 45 and the like to prompt the vehicle to decelerate, and when the vehicle is decelerated, by maintaining the vehicle speed after decelerating, at the signalized intersection as the control target point This can be realized by, for example, determining whether or not the vehicle can pass without stopping at regular intervals. In addition, if it is not determined that the vehicle can pass without stopping at the signalized intersection as the control target point before reaching the point within the predetermined distance to the signalized intersection as the control target point, It can be determined that it must stop at the signalized intersection. The control unit 20 outputs a control signal to the user I / F unit 45 to output guidance corresponding to each determination result. As a result, it is possible to prompt the driver to perform driving so that the number of stops is as small as possible.

(2) Vehicle control processing:
Next, the vehicle control process by the vehicle control program 21 will be described along the example shown in FIG. 3B. FIG. 2 is a flowchart showing the positional relationship acquisition process executed by the vehicle control program 21. FIG. 3B schematically shows a road with a solid line, and shows an example in which the communication device Pb and signalized intersections I ₁ , I ₂ , and I ₃ exist in front of the current location C of the vehicle. Here, it is assumed that the map information 30a includes the cycle information indicating the cycle of the traffic light at all the signalized intersections I ₁ , I ₂ , and I ₃ . Of course, as described above, the period information may be included in the transmission information of the beacon communication unit 44.

  When the vehicle starts to travel, the control unit 20 executes the vehicle control process shown in FIG. 2 every predetermined period (for example, 100 ms). When the vehicle control process is started, the control unit 20 controls the beacon communication unit 44 by the process of the starting point acquisition unit 21a, and executes a process for receiving a beacon signal (step S100). That is, the control unit 20 controls the beacon communication unit 44 and attempts to communicate with a communication device installed on the road. When a communication device exists in the communicable range, the control unit 20 receives a beacon signal output from the communication device. In the example shown in FIG. 3, when the vehicle reaches the communicable range of the communication device Pb, the control unit 20 receives a beacon signal in step S100.

  Next, the control part 20 determines whether the signal was able to be received appropriately by the process of the calculation point acquisition part 21a (step S105). That is, the control unit 20 determines whether or not a beacon signal has been received without occurrence of a communication error in step S100, and determines that the signal has not been properly received when a communication error has occurred. When the beacon signal can be received without causing a communication error, the control unit 20 determines whether or not the beacon signal includes information related to vehicle control. If the beacon signal is included, the control unit 20 appropriately receives the signal. Judge that it was made. If it is not determined in step S105 that the signal has been properly received, the control unit 20 ends the vehicle control process.

On the other hand, when it determines with having received the signal appropriately in step S105, the control part 20 analyzes a beacon signal by the process of the starting point acquisition part 21a and the control object point acquisition part 21b (step S110). Specifically, first, the control unit 20 acquires information included in the beacon signal. In the present embodiment, when the section ahead of the communication device Pb is a control section to be subjected to vehicle control, the beacon signal includes information indicating a signal intersection as a control target point, information indicating the position of the communication device, and the like. The control section is between the position of the communication device and the frontmost signalized intersection. In the example shown in FIG. 3, the section Z is a control section. Therefore, when the vehicle approaches the communication device Pb and the beacon signal is properly received, the control unit 20 determines the position of the communication device Pb based on the information included in the beacon signal by the process of the starting point acquisition unit 21a. Identify and get as a starting point. The control unit 20 uses the processing of the control target point obtaining unit 21b, the signalized intersection I ₁ based on the information contained in the beacon signal, I _2, I ₃ identifies that the controlled object point. In this case, the section from the position of the communication device Pb to the position of the signalized intersection I ₃ is specified as the control section.

  Next, the control unit 20 determines whether or not the vehicle has entered the control section by the processing of the positional relationship acquisition unit 21c (step S115). That is, the control unit 20 specifies the current position of the vehicle based on the output signals of the GPS receiving unit 41, the vehicle speed sensor 42, and the gyro sensor 43, and the position of the communication device that is the start point of the control section acquired in step S110. Is determined to have entered the control section. If it is not determined in step S115 that the vehicle has entered the control section, the control unit 20 ends the vehicle control process (in this case, it is determined that the vehicle has entered the control section when the vehicle control process is executed next). Is possible).

  On the other hand, if it is determined in step S115 that the vehicle has entered the control section, the control unit 20 causes the vehicle control unit 21d to output an in-control icon (step S120). That is, the control unit 20 outputs a control signal to the user I / F unit 45, and causes an icon indicating that the vehicle is currently being controlled to be output on the display.

  Next, the control unit 20 acquires the positional relationship between the vehicle and the control target point by the processing of the positional relationship acquisition unit 21c (step S125). Specifically, when it is determined in step S115 that the vehicle has entered the control section, the control unit 20 starts measuring the distance from the starting point by the positional relationship acquisition unit 21c. That is, the control unit 20 starts a process of acquiring the cumulative travel distance after the position of the communication device that is the starting point based on the output signal of the vehicle speed sensor 42. Next, the control unit 20 starts the flag setting process shown in FIG. 3A in order to switch the method for specifying the positional relationship based on the distance from the starting point by the processing of the positional relationship acquisition unit 21c.

(2-1) Flag setting process:
In the flag setting process, a threshold value to be compared with the distance from the starting point is set and a comparison based on the threshold value is performed. As described above, the distance value at which the error in the first method is worse than the error in the second method is set as the threshold value in the map information 30a, and this value becomes the initial value of the threshold value. When the flag setting process is started, the control unit 20 sets the flag to 0 (step S200). Since flag 0 indicates that the first method is to be used and flag 1 indicates that the second method is to be used, initially, the first method should be used. Set to

  When the flag is set to 0, the control unit 20 determines whether or not the vehicle has stopped (step S205). In the present embodiment, the vehicle speed is smaller than a predetermined value that can be regarded as a stop of the vehicle, and the time until the value is exceeded again is regarded as one stop. Therefore, the control unit 20 specifies the vehicle speed based on the output signal of the vehicle speed sensor 42, and determines whether or not the vehicle is considered to be in the state of the stop.

  When it is determined in step S205 that the vehicle has stopped, the control unit 20 increments a variable indicating the number of stops (initial value is 0) (step S210), and corrects the threshold (step S215). In the present embodiment, the correction is performed so that the threshold value becomes smaller according to the number of times the vehicle is stopped between the calculation point and the control target point. That is, in the first method that does not use GPS, when the number of stops of the vehicle increases with an increase in the travel distance of the vehicle, the error increases with an increase in the number of stops. Therefore, the error of the first method is estimated to increase as the number of stops increases, and in this embodiment, an increase in error for each stop is defined in advance.

  Therefore, every time the vehicle stops, the control unit 20 performs a process of subtracting the increase in error for each stop from the threshold value. According to this configuration, it is possible to set the distance value at which the error in the first method is worse than the error in the second method as a threshold in a state where the change in error due to the stop is taken into account. If it is not determined in step S205 that the vehicle has stopped, control unit 20 skips steps S210 and S215.

  When it is not determined in step S205 that the vehicle has stopped, or when step S215 is executed, the control unit 20 determines whether or not the distance from the starting point is greater than the threshold (step S220). In step S220, when it is not determined that the distance from the starting point is greater than the threshold value, the control unit 20 repeats the processes after step S200. That is, the first method is set to be used. On the other hand, if it is determined in step S220 that the distance from the starting point is greater than the threshold, the control unit 20 sets the flag to 1 (step S225). In other words, the second method is set to be used.

  If it is determined in step S115 that the vehicle has entered the control section, the method for acquiring the positional relationship between the vehicle and the control target point is determined by the flag setting process described above. Therefore, in step S125, the control unit 20 acquires the positional relationship between the vehicle and the control target point using the determined method.

Specifically, when the first method is to be used, the control unit 20 determines from the start point of the control section to each control target point based on the map information 30a, the output information of the beacon communication unit 44, and the like. The distance (L ₁ , L ₂ , L _{3 in the} example shown in FIG. 3) is acquired. Then, by subtracting the distance from the starting point acquired based on the output signal of the vehicle speed sensor 42 from each distance, the vehicle and each control target point (I ₁ , I ₂ , I _{3 in the} example shown in FIG. ₃ ). Is obtained as a positional relationship.

  On the other hand, when the second method is to be used, the control unit 20 acquires the current position of the vehicle based on the output signals of the GPS receiving unit 41, the vehicle speed sensor 42, and the gyro sensor 43. Moreover, the control part 20 acquires the position of each control object point with reference to the map information 30a. Then, the distance between the current position of the vehicle and each control target point is acquired as a positional relationship.

  Next, the control part 20 determines whether the control about each control object point should be started by the process of the vehicle control part 21d (step S130). The trigger for starting control can be defined by various aspects. In the present embodiment, the trigger is that the distance to the control target point is equal to or less than a predetermined distance. Therefore, the control unit 20 determines whether or not the positional relationship acquired in step S125, that is, whether the distance between the vehicle and each control target point is equal to or less than the predetermined distance. When it is determined that the distance between the vehicle and each control target point is equal to or less than a predetermined distance for any one of the control target points, it is determined that the control should be started.

For example, in the example shown in FIG. 3, when the predetermined distance is L ₀ , the control unit 20 should start control on the signalized intersection I ₁ when the vehicle passes the position P _1. Is determined. Further, when the vehicle passes through the position P ₂ , the control unit 20 determines that the control for the signalized intersection I ₂ should be started, and when the vehicle passes through the position P ₃ , the control unit 20 , It is determined that the control for the signalized intersection I ₃ should be started. The distance L ₀ may be determined in advance and may be a fixed value or a value that varies depending on various conditions. Examples of the latter include a configuration in which the distance L ₀ varies according to the current vehicle speed of the vehicle.

  In Step S130, when it is determined that the control should be started, the control unit 20 outputs guidance information by the process of the vehicle control unit 21d (Step S135). That is, the control unit 20 refers to the map information 30a, acquires the period information of the signalized intersection as the control target point determined to start the control in step S130, and the timing at which the indication of the traffic light at the signalized intersection changes. Is identified.

  Further, the control unit 20 determines whether or not the vehicle can pass without stopping at the signalized intersection by maintaining or decelerating the vehicle speed based on the current vehicle speed of the vehicle. When it is possible, the control unit 20 outputs a control signal to the user I / F unit 45 to output an icon for prompting maintenance or deceleration of the vehicle speed. If it is not determined that the vehicle can pass without stopping at the signalized intersection by maintaining or decelerating the vehicle speed, the control unit 20 outputs a control signal to the user I / F unit 45 and An icon indicating that the current display is red is output.

  Next, the control part 20 acquires the positional relationship between a vehicle and a control target point by the process of the vehicle control part 21d (step S140). Here, the control unit 20 acquires the positional relationship by acquiring the distance between the signalized intersection as the target point for vehicle control started after the determination in step S130 and the vehicle. Of course, the technique used when acquiring the positional relationship is the technique indicated by the flag set in the process shown in FIG. 3A.

Next, the control unit 20 determines whether or not the control for any one of the control target points should be terminated by the process of the vehicle control unit 21d (step S145). That is, the control unit 20 determines that the vehicle has passed a signalized intersection as one of the control target points based on the positional relationship acquired in step S140 (the distance between the vehicle and the control target point is 0 or less). When it becomes, it determines with the control about the said control target point should be complete | finished. For example, in the example illustrated in FIG. 3, when the vehicle passes the signalized intersection I ₁ , the control unit 20 determines that the control for the signalized intersection I ₁ should be terminated.

  If it is determined in step S145 that the control for any one of the control target points should be terminated, the control unit 20 erases the guidance information by the process of the vehicle control unit 21d (step S150). That is, the control unit 20 outputs a control signal to the user I / F unit 45 and deletes the icon related to the control target point for which the control should be terminated.

When step S150 is executed, or when it is not determined in step S145 that the control for any control target point should be terminated, or in step S130, the control for any control target point is started. When it is not determined that it should be, the control unit 20 determines whether or not the vehicle has left the control section by the process of the vehicle control unit 21d (step S155). That is, the control unit 20 specifies the positional relationship between the vehicle and the end point of the control section (the frontmost control target point) by the method determined by the process shown in FIG. 3A, and the vehicle determines the end point of the control section. When it passes, it determines with having left the control section. For example, in the example illustrated in FIG. 3, when the vehicle passes the signalized intersection I ₃ , the control unit 20 determines that the vehicle has left the control section.

  In step S155, when it is not determined that the vehicle has left the control section, the control unit 20 determines whether or not the control for any one of the control target points is being executed by the process of the vehicle control unit 21d ( Step S165). Then, when it is determined in step S165 that the control for any one of the control target points is being executed, the control unit 20 repeats the processes after step S140. On the other hand, when it is not determined in step S165 that the control for any one of the control target points is being executed, the control unit 20 repeats the processes in and after step S130.

  If it is determined in step S155 that the vehicle has left the control section, the control unit 20 deletes the in-control icon (step S160). That is, the control unit 20 outputs a control signal to the user I / F unit 45 to delete the icon indicating that the vehicle is being controlled from the display. As described above, in the present embodiment, in steps S125, S140, and the like, a process of acquiring the positional relationship between the vehicle and the control target point is performed. Switching is performed according to the magnitude relationship between the distance and the threshold. Therefore, whether the vehicle and the control target point are accurately acquired even if the distance from the starting point is short or long, whether the vehicle can pass without stopping at the signalized intersection, etc. It is possible to reduce the fact that this determination is an erroneous determination.

(3) Other embodiments:
The above embodiment is an example for carrying out the present invention, and various other embodiments can be used as long as the method of acquiring the positional relationship between the vehicle and the control target point is switched based on the distance from the starting point. It can be adopted. For example, the navigation terminal 10 may be fixedly mounted on the vehicle, or the portable navigation terminal 10 may be brought into the vehicle and used.

  Further, some or all of the counting point acquisition unit, the control target point acquisition unit, the positional relationship acquisition unit, and the vehicle control unit may be executed by another terminal, for example, a vehicle control ECU. Furthermore, a configuration in which the correction of the threshold based on the number of stops is omitted may be employed.

  The starting point acquisition unit only needs to be able to acquire the starting point of the distance in the vehicle control, and the distance is at least the positional relationship in the configuration in which the vehicle control is performed based on the positional relationship between the vehicle and the control target point. What is necessary is just to be used in order to determine the method for acquiring. Of course, the distance may be used to acquire the positional relationship. The starting point may be an arbitrary point where the vehicle has traveled, and may be specified by various methods. For example, when specific information is acquired in road-to-vehicle communication, the position of the vehicle at the acquisition timing, the position where a margin is provided at the position, or the like may be set as the starting point. Further, the starting point may be specified based on the position of the feature on or around the road, and various configurations can be adopted.

  Vehicle control is control of an arbitrary device that is performed to change the state of the vehicle. For the purpose of changing the state of the vehicle, a device provided in the vehicle or a device (such as a portable terminal) used in the vehicle is used. Be controlled. When changing the state of the vehicle, the state of the vehicle may be changed automatically, or the state of the vehicle may be changed through the driving operation of the driver by prompting the driver or the like.

  Examples of the control for automatically changing the state of the vehicle include control for accelerating / decelerating the vehicle by controlling the throttle valve and the fuel injection amount. Such control may be executed before the signalized intersection, or may be executed in relation to other control target points, for example, the start point of the curve section, the position of the stop line, or the like. More specifically, as deceleration control, it is necessary to stop at the control target point (when it is estimated that the signal intersection is red), or without deceleration at the control target point. For example, when the vehicle can pass through a signalized intersection, control for decelerating to a predetermined speed before the control target point can be given.

  As control for changing the state of the vehicle through the driver's driving operation, for example, for the purpose of accelerating / decelerating the vehicle through the driver's operation, the display may output information for supporting acceleration / deceleration. The structure etc. which control a navigation system are mentioned. In addition to the above-described embodiments, various configurations can be adopted as specific examples of such a configuration. For example, in a state where the vehicle is stopped by a red signal in front of a signalized intersection, a configuration for performing start preparation (acceleration preparation) guidance by guiding the time until the signal changes to a green signal may be used.

  The control target point acquisition unit only needs to be able to acquire a control target point in vehicle control. That is, vehicle control is control performed using a control target point, and a control target point acquisition part acquires a control target point in order to perform vehicle control. Various points can be assumed as control target points related to vehicle control. For example, a control start point or a control end point may be a control target point, or a point for determining a parameter related to control such as a vehicle speed may be a control target point. Examples of the latter include vehicle control that determines the vehicle speed in front of the control target point based on the current signal at the control target point.

  The positional relationship acquisition unit acquires the positional relationship between the vehicle and the control target point by the first method that does not use GPS when the distance from the calculation point is equal to or less than the threshold, and when the distance from the calculation point is greater than the threshold, It is only necessary that the positional relationship between the vehicle and the control target point can be acquired by the second method using GPS. That is, the positional relationship acquisition unit only needs to be able to switch the method for acquiring the distance from the starting point and acquiring the positional relationship based on the comparison between the distance and the threshold value between the first method and the second method.

  The distance from the starting point may be acquired by various methods, for example, a configuration that specifies the travel distance of the vehicle from the starting point based on a sensor or the like. In addition, since acquisition of distance and acquisition of the positional relationship between points can be realized with substantially the same technology, the distance from the starting point using either the first method or the second method or other methods May be acquired.

  The positional relationship between the vehicle and the control target point may be defined directly or indirectly. As the former, the structure etc. which are prescribed | regulated by the distance of the position of a vehicle and a control object point are mentioned, for example. Examples of the latter include a configuration defined by the distance from the starting point. That is, when the starting point and the control target point are clear, when the distance from the starting point is specified, the position of the vehicle and the control target point are reduced by subtracting the distance from the distance between the starting point and the control target point. It is possible to specify the distance. The positional relationship may be defined by the required time between points in addition to the position and distance.

  Various methods can be adopted as the method for acquiring the positional relationship, and the method is classified into at least two methods depending on whether or not GPS is used. As a 1st method which does not use GPS, the method of pinpointing the distance from a starting point and the position of a vehicle based on the output of the sensor with which the terminal used in a vehicle or a vehicle is mentioned, for example. One or more various sensors can be assumed as the sensor, and examples thereof include a vehicle speed sensor (such as a sensor that outputs a pulse as the wheel rotates) attached to the wheel. Of course, the vehicle speed sensor and another sensor such as a gyro sensor may be used in combination.

  The second method using GPS is a method of specifying the position of the vehicle based on the GPS signal, and the positional relationship acquisition unit can acquire the GPS signals output from a plurality of GPS satellites and specify the position of the vehicle. It ’s fine. In the first method and the second method, the value of the maximum error changes depending on the distance from the starting point, and the first method is more accurate if the distance from the starting point is less than or equal to the threshold, and the distance from the starting point If the value is larger than the threshold value, the first method may be a method with lower accuracy. Since the accuracy changes depending on the distance from the starting point as described above when the presence / absence of GPS is different, the positional relationship is determined by using the first method as the method that does not use GPS and the second method as the method that uses GPS. One embodiment of an acquisition system can be configured.

  Further, the first method is a method for acquiring a positional relationship based on the position of the vehicle specified by road-to-vehicle communication, and the second method is for acquiring the positional relationship based on the position of the vehicle specified by the GPS signal. The structure which is a technique to do may be used. That is, the first method and the second method may be distinguished from each other when the reference position is determined by GPS and when the GPS is not used when determining the reference position.

  The reference specified by the road-to-vehicle communication only needs to be regarded as the position of the vehicle when the road-to-vehicle communication is performed. For example, the communication in which the position of the vehicle when the road-to-vehicle communication is performed performs the road-to-vehicle communication. The case where it is considered that it is equivalent to the position of a machine (beacon etc.), the case where it is considered that it is the position which provided the margin in the position of a communication apparatus, etc. are mentioned. In this way, when the reference is specified, the positional relationship between the vehicle and the control target point is obtained by using the reference as a starting point and acquiring the distance from the starting point by acquiring the travel distance of the vehicle thereafter. It becomes possible to specify. The position of the vehicle specified by the GPS signal may be the position of the vehicle indicated by the GPS signal (system including the GPS system (navigation system)), or the position of the vehicle indicated by the output signal of the GPS signal and other sensors. It may be.

  Furthermore, a configuration may be employed in which the distance value at which the error in the first method is worse than the error in the second method is a threshold value. That is, when the distance from the starting point increases, the error increases in the first method, but the error in the second method has an upper limit. Therefore, when the behavior of the error corresponding to the distance from the starting point is evaluated by the first method and the second method, it is possible to define a distance such that the error in the first method is worse than the error in the second method. This distance can be used as a threshold value. According to this configuration, the vehicle and the object to be controlled by a method with a relatively small error between the first method and the second method both when the distance from the calculation point is equal to or smaller than the threshold and when the distance is larger than the threshold. The positional relationship with the point is acquired. The distance value at which the error in the first method is worse than the error in the second method may be defined in advance. For example, an error per unit distance that occurs in the first method is specified by statistics or the like. The maximum error (such as the radius of the error circle) generated in the two methods is specified by statistics or the like, and the threshold value can be specified by comparison.

  Furthermore, the threshold value may be reduced according to the number of stops of the vehicle between the calculation point and the control target point. That is, when measuring the travel distance of the vehicle in the first method, if the number of stops of the vehicle statistically increases as the travel distance of the vehicle increases, the error may increase as the number of stops increases. . For example, when a sensor for detecting the rotation of the wheel is attached to the wheel, the accuracy of detection by the sensor decreases when the vehicle stops or when the vehicle travels at a low speed equivalent to the stopped state. There is a case.

  Therefore, the error in the first method can be estimated to increase as the number of stops increases, and if an increase in error for each number of stops is defined in advance, the error in the first method becomes the error in the second method. It is possible to specify the relationship between the distance worsening and the number of stops. And if it is set as the structure which specifies the degree to which a threshold value becomes small according to the frequency | count of a stop of the vehicle between a calculation point and a control object point based on the said relationship, the threshold value which also considered the change of the error by a stop will be set. It becomes possible.

  Furthermore, the structure which switches the method of acquiring the positional relationship of a vehicle and a control object point based on the distance from a calculation point like this invention is applicable also as a program or a method. In addition, the above-described device, program, and method may be realized as a single device or may be realized by using components shared with each part of the vehicle, and include various aspects. It is a waste. For example, it is possible to provide a navigation terminal, a method, and a program provided with the above devices. Further, some changes may be made as appropriate, such as a part of software and a part of hardware. Furthermore, the invention is also established as a recording medium for a program for controlling the apparatus. Of course, the software recording medium may be a magnetic recording medium, a magneto-optical recording medium, or any recording medium to be developed in the future.

DESCRIPTION OF SYMBOLS 10 ... Navigation terminal, 20 ... Control part, 21 ... Vehicle control program, 21a ... Counting point acquisition part, 21b ... Control object point acquisition part, 21c ... Positional relationship acquisition part, 21d ... Vehicle control part, 30 ... Recording medium, 30a ... Map information, 41 ... GPS receiver, 42 ... Vehicle speed sensor, 43 ... Gyro sensor, 44 ... Beacon communication part, 45 ... User I / F part

Claims (6)

A starting point acquisition unit for acquiring a starting point of distance in vehicle control;
A control target point acquisition unit for acquiring a control target point in the vehicle control;
When the distance from the starting point is less than or equal to the threshold, the positional relationship between the vehicle and the control target point is obtained by the first method not using GPS, and when the distance from the starting point is larger than the threshold, the GPS is used. A positional relationship acquisition unit that acquires a positional relationship between the vehicle and the control target point by a second method;
A positional relationship acquisition system comprising: The first method is:
It is a method for obtaining the positional relationship based on the position of the vehicle specified by road-to-vehicle communication,
The second method is:
A method of acquiring the positional relationship with reference to the position of the vehicle specified by a GPS signal.
The positional relationship acquisition system according to claim 1. The threshold is a distance value at which an error in the first method is worse than an error in the second method.
The positional relationship acquisition system in any one of Claim 1 or Claim 2. The threshold is reduced according to the number of stops of the vehicle between the calculation point and the control target point.
The positional relationship acquisition system in any one of Claims 1-3. A starting point acquisition step of acquiring a starting point of distance in vehicle control;
A control target point acquisition step of acquiring a control target point in the vehicle control;
When the distance from the starting point is less than or equal to the threshold, the positional relationship between the vehicle and the control target point is obtained by the first method not using GPS, and when the distance from the starting point is larger than the threshold, the GPS is used. A positional relationship acquisition step of acquiring a positional relationship between the vehicle and the control target point by a second method;
The positional relationship acquisition method containing. A starting point acquisition function for acquiring a starting point of distance in vehicle control;
A control target point acquisition function for acquiring a control target point in the vehicle control;
When the distance from the starting point is less than or equal to the threshold, the positional relationship between the vehicle and the control target point is obtained by the first method not using GPS, and when the distance from the starting point is larger than the threshold, the GPS is used. A positional relationship acquisition function for acquiring a positional relationship between the vehicle and the control target point by a second method;
A positional relationship acquisition program that enables a computer to realize the above.

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