JP2016223895A - Road gradient acquisition system, road gradient acquisition method and road gradient acquisition program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique capable of improving road gradient calculation accuracy.SOLUTION: A road gradient acquisition system comprises: an object position acquisition section to acquire an object position of an object for which a gradient is calculated; a bifurcation determination section to determine whether or not a bifurcation, where a plurality of connecting roads are connected to an object road which includes the object position, exists within a predetermined distance from the object position; a reference road acquisition section which selects the connection road having a gradient closest to an estimated gradient of the object road as a reference road when the bifurcation exists or the object road as the reference road when the bifurcation does not exist; a reference position acquisition section to acquire reference positions, on the reference road, a predetermined distance forward and backward from the object position; and a gradient acquisition section to acquire a gradient of the object position on the basis of elevations of the reference points.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a road gradient acquisition system, a road gradient acquisition method, and a road gradient acquisition program.

  Conventionally, a technique for acquiring a road gradient based on the altitude of the road is known. For example, in Patent Document 1, two acquisition target points that are separated from each other by a separation distance D before and after the calculation target point are specified, and a road gradient at the calculation target point is calculated based on altitude information corresponding to the two points. Is disclosed.

JP 2013-178133 A

In the prior art, there are cases where the road gradient cannot be calculated accurately. That is, when there is a branch in the range within the separation distance D from the calculation target point, it is not clear from which connecting road connected to the branch the altitude information should be referred to. Therefore, when the road gradient of the calculation target point is calculated with reference to the elevation information of the connection road having a road gradient that is significantly different from the actual road gradient of the calculation target point, the road gradient of the calculation target point can be accurately calculated. Can not.
The present invention has been made in view of the above problems, and an object thereof is to provide a technique capable of improving the calculation accuracy of a road gradient.

  In order to achieve the above object, a road gradient acquisition system includes a target position acquisition unit that acquires a target position that is a target position for acquiring a gradient, and a plurality of connecting roads with respect to the target road where the target position exists. A branch determination unit that determines whether or not a branch to be connected is within a predetermined distance from the target position, and if a branch exists, a connection road having a slope closest to the estimated slope of the target road is set as a reference road. A reference road acquisition unit that acquires the target road as a reference road when there is no branch, a reference position acquisition unit that acquires a reference position on a reference road that is a predetermined distance away from the target position, and a reference position And a gradient acquisition unit that acquires the gradient of the target position based on the altitude.

  In order to achieve the above object, the road gradient acquisition method includes a target position acquisition step of acquiring a target position, which is a target position for acquiring the gradient, and a plurality of connections to the target road where the target position exists. A branch determination step for determining whether or not a branch to which the road is connected is within a predetermined distance from the target position, and if there is a branch, refer to a connected road having a slope closest to the estimated slope of the target road. When the road is a road and there is no branch, a reference road acquisition step of acquiring the target road as a reference road, a reference position acquisition step of acquiring a reference position on the reference road that is a predetermined distance away from the target position in advance and A gradient acquisition step of acquiring a gradient of the target position based on the altitude of the reference position.

  Furthermore, in order to achieve the above object, the road gradient acquisition program includes a target position acquisition function for acquiring a target position, which is a target position for acquiring the gradient, and a plurality of connections to the target road where the target position exists. A branch determination function that determines whether or not a branch to which a road is connected is within a predetermined distance from the target position, and if there is a branch, refer to the connected road with the slope closest to the estimated slope of the target road A reference road acquisition function for acquiring a target road as a reference road, a reference position acquisition function for acquiring a reference position on a reference road that is a predetermined distance away from the target position, A gradient acquisition function for acquiring the gradient of the target position based on the altitude of the reference position is realized by a computer.

  That is, in the road gradient acquisition system, method, and program, the gradient of the target position is acquired based on the altitude of the reference position on the reference road that is a predetermined distance away from the target position. In this configuration, when a branch exists within a predetermined distance from the target position, a connection road having a gradient closest to the estimated gradient of the target road is set as a reference road. Therefore, even if there is a branch, a road with a small gradient change from the target road becomes a reference road. As a result, the gradient of the target position can be accurately calculated based on the reference position on the reference road.

It is a block diagram which shows a road gradient acquisition system. It is a flowchart of a road gradient acquisition process. (3A) is a diagram schematically showing a downward slope, and (3B) is a diagram schematically showing the periphery of the target road.

Here, embodiments of the present invention will be described in the following order.
(1) Configuration of road gradient acquisition system:
(2) Road gradient acquisition processing:
(3) Other embodiments:

(1) Configuration of road gradient acquisition system:
FIG. 1 is a block diagram showing a configuration of a road gradient acquisition system 10 according to the present invention. The road gradient acquisition system 10 includes a control unit 20 including a CPU, a RAM, a ROM, and the like, and a recording medium 30, and the control unit 20 can execute a program stored in the recording medium 30 and the ROM. In this embodiment, the road gradient acquisition program 21 can be executed as this program. The road gradient acquisition program 21 causes the control unit 20 to execute a function of acquiring the current position of the vehicle and specifying the gradient of the current position of the vehicle.

  A vehicle in which the road gradient acquisition system 10 is used includes a GPS receiver 41, a vehicle speed sensor 42, a gyro sensor 43, a transmission unit 44, and a braking unit 45. The GPS receiver 41 receives radio waves from GPS satellites and outputs a signal for calculating the current position of the vehicle via an interface (not shown). The vehicle speed sensor 42 outputs a signal corresponding to the rotational speed of the wheels provided in the vehicle. The control unit 20 acquires this signal via an interface (not shown) and acquires the vehicle speed. 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 control unit 20 acquires the current position of the vehicle by specifying the travel locus of the vehicle based on output signals from the vehicle speed sensor 42 and the gyro sensor 43 and the like. The output signal of the GPS receiver 41 is used for correcting the current position of the vehicle specified by the vehicle speed sensor 42, the gyro sensor 43, and the like.

  The transmission unit 44 includes a stepped torque converter having a plurality of speed stages such as a total of 6 speeds for forward and a total of 1 speed for reverse, and adjusts the rotational speed with a gear ratio corresponding to each speed. Can be transmitted to the wheels of the vehicle. The control unit 20 outputs a control signal for switching the gear position via an interface (not shown), and the transmission unit 44 can acquire the control signal and switch the gear position. Therefore, the control unit 20 can decelerate the vehicle by outputting a control signal to the transmission unit 44 to change the gear position and apply an engine brake to the vehicle. In the present embodiment, the gear ratio is configured to become smaller as the gear position becomes higher gear, such as forward 1st speed to forward 6th speed.

  The braking unit 45 includes a device that controls the pressure of the wheel cylinder that adjusts the degree of deceleration by the brake mounted on the wheel of the vehicle, and the control unit 20 outputs a control signal to the braking unit 45 to output the wheel cylinder. It is possible to adjust the pressure. Therefore, when the control unit 20 outputs a control signal to the braking unit 45 to increase the pressure of the wheel cylinder, the braking force by the brake is increased and the vehicle is decelerated.

  As described above, the control unit 20 can decelerate the vehicle by outputting control signals to the transmission unit 44 and the braking unit 45. In the present embodiment, the control unit 20 can execute a deceleration control program (not shown), and the processing of the deceleration control program allows the control unit 20 to prevent the vehicle speed from becoming excessive vehicle speed on a gradient road. Is reduced below the target speed. Here, the target speed is determined based on the road gradient. For example, the control unit 20 determines the target speed at the entrance of the downward slope based on the acceleration acting on the vehicle at the downward slope so as not to become an excessive speed even if acceleration by the acceleration is performed. Then, the control unit 20 performs deceleration control, for example, by decelerating the vehicle by a constant acceleration linear motion before the entrance of the descending slope, and decelerating the vehicle speed to the target speed at the entrance of the descending slope.

  Map information 30a is recorded in the recording medium 30 in advance. The map information 30a includes node data indicating the position of a node set at an intersection on the road on which the vehicle travels, shape interpolation point data for specifying the shape of the road between the nodes, link data indicating the connection between the nodes, It contains facility data indicating facilities that exist around the road. In the present embodiment, the map information 30a includes altitude data indicating the altitude for each predetermined distance on the road. The altitude data indicates the altitude value at each position on the road. The elevation data may be defined to indicate the elevation of the node or shape interpolation point.

  In the present embodiment, the control unit 20 executes a process of specifying the gradient of the current position of the vehicle by the road gradient acquisition program 21 in order to perform the deceleration control as described above. The road gradient acquisition program 21 includes a target position acquisition unit 21a, a branch determination unit 21b, a reference road acquisition unit 21c, a reference position acquisition unit 21d, and a gradient acquisition unit 21e.

  The target position acquisition unit 21a is a program module that causes the control unit 20 to realize a function of acquiring a target position that is a target position from which a gradient is acquired. In the present embodiment, the control unit 20 acquires the current position of the vehicle as the target position. That is, the control unit 20 acquires the current position of the vehicle based on the map information 30a and the output signals of the GPS receiving unit 41, the vehicle speed sensor 42, and the gyro sensor 43, and regards the current position as the target position.

  The branch determination unit 21b determines whether or not a branch connecting a plurality of connecting roads to a target road where the target position exists is within a predetermined distance (also referred to as a predetermined distance) from the target position. It is a program module that causes the control unit 20 to realize the function. That is, the control unit 20 regards the road where the target position exists as the target road, and determines whether or not a node exists within the range of the predetermined distance ahead and behind the target position along the target road based on the map information 30a. Judgment. And when a node exists within the range of the predetermined distance ahead and behind the target position, the controller 20 determines that there is a branch connecting a plurality of connected roads to the target road within the predetermined distance from the target position. judge.

In addition, the control unit 20 regards roads other than the target road among the roads connected to the branch indicated by the node as connection roads. In the present embodiment, the control unit 20 regards the intersection as an end point of the road. Therefore, for example, as shown in FIG. 3B, in a situation where the target position C exists on the target road R ₁ (FIG. 3B is a view looking down from above), a branch I exists behind the target position C. Roads R ₂ and R ₃ are connecting roads.

  The reference road acquisition unit 21c is a program module that causes the control unit 20 to realize a function of acquiring a reference road to be referred to when acquiring the gradient of the target position. In the present embodiment, the control unit 20 selects a reference road for referring to the altitude from the target road itself or the connection road. That is, if there is no branch, the control unit 20 regards the target road as a reference road. On the other hand, if there is a branch within a predetermined distance from the target position, the control unit 20 selects a reference road from the connection roads connected to the branch. Here, the control unit 20 selects a road most suitable as a road for determining the gradient of the target road from a plurality of connection roads, and sets it as a reference road.

  That is, in the configuration in which the gradient is acquired based on the elevation before and after the target position, it is desirable to refer to the elevation at the reference position that is a predetermined distance away from the target position in order to reduce the influence of the information error indicating the elevation. . Since it is practically impossible to exclude errors from the altitude data included in the map information 30a, it should be considered that a certain degree of error is included in the word altitude indicated by the altitude data. Therefore, in the case of interpolating the gradient of the target position between two reference positions from the altitude, if the reference position is too close, the gradient becomes a very inaccurate value due to the influence of the error.

For example, FIG. 3A is a diagram schematically showing a downward gradient, schematically showing a change in horizontal position in the horizontal direction, and schematically showing a change in elevation (vertical position) in the vertical direction. In such a gradient, if the target position is the position Pi and the altitude error is ± d, if the reference position is too close to the target position Pi, such as positions P _r3 and _r4 , the gradient may vary depending on the error. The gradient can be obtained with the sign reversed. Therefore, in order to prevent such erroneous calculation of the gradient, the reference position is set to positions P _r1 and P _r2 with a predetermined distance L before and after the target position. With such a configuration, the gradient of the target position can be calculated more accurately as the gradient moves away from the 0 (horizontal) state.

  However, if a sufficiently long distance is set as the default distance, there may be a plurality of reference position candidates due to a branch included in the range of the default distance from the target position. Therefore, the reference road acquisition unit 21c selects a connection road having a gradient closest to the estimated gradient of the target road as a reference road. For this reason, the control unit 20 acquires the estimated gradient of the target road and the estimated gradient of the connected road based on the map information 30a, and selects the connected road having the estimated gradient closest to the estimated gradient of the target road. According to this configuration, it is possible to select a connection road that can acquire the gradient of the target road more accurately from a plurality of connection roads.

  The estimated gradient can be specified by various configurations, and when the estimated gradient of the target road is specified, the control unit 20 specifies the estimated section on the target road and the estimated section on the connection road according to a specific rule. The estimated gradient of each road is acquired based on the altitude of each estimated section. According to this configuration, it is possible to easily determine an estimation gradient acquisition target.

  The reference position acquisition unit 21d is a program module that causes the control unit 20 to realize a function of acquiring a reference position on a reference road that is a predetermined distance away from the target position. That is, the control unit 20 specifies a position on the reference road that is a predetermined distance along the road starting from the target position based on the map information 30a, and acquires it as the reference position. For example, when there is no branch ahead of the target road, the target road and the reference road coincide with each other. Therefore, the control unit 20 refers to the map information 30a and determines a position that is a predetermined distance along the target road from the target position. Get as reference position. When there is a branch behind the target road, the control unit 20 refers to the map information 30a and uses a position that is a predetermined distance away from the target position along the target road and the reference road (selected connection road) as a reference position. get. The predetermined distance only needs to be determined in advance as a value that can reduce the influence of the error in the information indicating the altitude. In the present embodiment, the predetermined distance is a fixed value (for example, 50 m).

  The gradient acquisition unit 21e is a program module that causes the control unit 20 to realize a function of acquiring the gradient of the target position based on the altitude of the reference position. That is, the control unit 20 specifies the position and altitude of the reference position acquired by the processing of the reference position acquisition unit 21d based on the map information 30a. Then, the control unit 20 sets the elevation difference / horizontal distance as a gradient value based on the elevation difference between the reference positions and the horizontal distance between the reference positions.

  According to the present embodiment configured as described above, the gradient of the target position can be acquired based on the altitude of the reference position on the reference road that is a predetermined distance away from the target position. In this configuration, even if there is a branch within a predetermined distance from the target position, the reference position is specified with the connection road having the gradient closest to the estimated gradient of the target road as the reference road. Accordingly, it is possible to accurately calculate the gradient of the target position based on the reference position.

(2) Road gradient acquisition processing:
Next, the road gradient acquisition process will be described in detail. FIG. 2 is a flowchart showing the road gradient acquisition process. In the present embodiment, the control unit 20 executes the road gradient acquisition process at a predetermined start timing (for example, every 100 ms). In the road gradient acquisition process, the control unit 20 acquires the current position as the target position by the process of the target position acquisition unit 21a (step S100). That is, the control unit 20 acquires the current position of the vehicle based on the map information 30a and the output signals of the GPS receiving unit 41, the vehicle speed sensor 42, and the gyro sensor 43, and regards the current position as the target position. For example, in the example shown in FIG. 3B, if there is a vehicle at the position C on the road R _1, the control unit 20 obtains the position C as a target position.

  Next, the control unit 20 specifies the position of the predetermined distance before and after the target position by the process of the branch determination unit 21b (step S105). In this embodiment, the control part 20 performs the process which pinpoints the position of predetermined distance back and forth from a target position along the target road where a target position exists. Therefore, when a branch exists at a position before reaching the position of the predetermined distance from the target position, the position is unknown.

For example, the control unit 20 in the example shown in Figure 3B refers to the front of the information of the target position C indicated by the map information 30a, the branch is present in the range of predetermined distance L in front of the target position C on the road R ₁ It is determined whether or not to do. In the example shown in FIG. 3B, since there is no branch in the range, the control unit 20 determines that there is no branch. In this case, the control unit 20 specifies a position P ₁ having a predetermined distance L ahead of the target position C on the target road R ₁ . The control unit 20 determines whether reference to the rear of the information of the target position C indicated by the map information 30a, there is branching in the range of predetermined distance L behind the target position C on the road R ₁ To do. In the example illustrated in FIG. 3B, since a branch exists in the range, the control unit 20 determines that a branch exists. In this case, the control unit 20 considers that the position of the predetermined distance L behind the target position C is unknown.

  Next, the control unit 20 determines whether or not there is a branch within a predetermined distance by the processing of the branch determination unit 21b (step S110). That is, the control unit 20 specifies the reference road by a different method depending on whether or not a branch exists at a position before reaching the position of the predetermined distance from the target position. In step S110, when it is determined that there is a branch within the predetermined distance, the control unit 20 specifies a connection road through the process of the reference road acquisition unit 21c (step S115). That is, the control unit 20 refers to the map information 30a and identifies a road that is connected to the branch identified by the processes in steps S105 and S110. And the road which excluded the object road from the road connected to the branch is specified as a connection road.

For example, in the example shown in FIG. 3B, since the branch I exists behind the target position C, the control unit 20 determines the roads R ₁ , R ₂ , R ₃ connected to the branch I based on the map information 30a. Identify. In this example, since the road R ₁ is the target road, the control unit 20 regards the roads R ₂ and R ₃ as connection roads.

  Next, the control unit 20 acquires the estimated gradient of the connected road by the process of the reference road acquisition unit 21c (step S120). In the present embodiment, the estimated gradient of the connection road is calculated based on information indicating the altitude between the position of the predetermined distance from the target position and the branch. Therefore, the control unit 20 refers to the map information 30a and identifies the position of the branch identified by the processing in steps S105 and S110. Further, the control unit 20 refers to the map information 30a regarding the connection road connected to the branch, and specifies a position on the connection road and a predetermined distance from the target position. And the control part 20 acquires the gradient of the said section based on the information (for example, the position of two places in the said area) which shows the altitude of the area between the said position and a branch with reference to the map information 30a. To do. The control part 20 acquires the estimated gradient of each connection road by performing the said process about each connection road.

  Next, the control unit 20 performs processing for acquiring the estimated gradient of the target road. For this purpose, the control unit 20 specifies an estimation section for estimating the estimated gradient on the target road. In the present embodiment, the length of the estimated section is made dependent on the target position. Various configurations can be adopted as the configuration for making the length of the estimation section depend on the target position. In the present embodiment, the control unit 20 sets the length of the estimation section to the relationship between the branch and the target position. Change based on. Specifically, in the present embodiment, a threshold value for evaluating the length of the section from the branch to the target position is determined in advance.

  Therefore, in order to perform the evaluation, the control unit 20 acquires the distance between the target position and the branch by the processing of the reference road acquisition unit 21c (step S125). That is, the control unit 20 specifies the target position acquired in step S100 and the branch position acquired in steps S105 and S110 based on the map information 30a, and acquires the distance between the two. For example, in the example illustrated in FIG. 3B, the control unit 20 acquires the distance Ls.

  Next, the control unit 20 determines whether or not the distance between the target position and the branch is larger than the threshold value by the process of the reference road acquisition unit 21c (step S130). If it is determined in step S130 that the distance between the target position and the branch is greater than the threshold, the control unit 20 acquires a section between the target position and the branch as an estimated section (step S135). On the other hand, if it is not determined in step S130 that the distance between the target position and the branch is greater than the threshold, the control unit 20 acquires a section obtained by extending the section between the target position and the branch to the opposite side of the branch as an estimated section. (Step S140).

  In other words, the estimated section is a section set for evaluating the gradient of the connecting road connected to the branch. Therefore, it is preferable that the estimated section is set so that a connection road close to the estimated gradient of the estimated section can be specified. Therefore, in the present embodiment, the control unit 20 sets the section from the branch to the target position as the estimated section when the distance between the target position and the branch is larger than the threshold. On the other hand, when the distance between the target position and the branch is less than or equal to the threshold value, it is easily affected by a decrease in gradient acquisition accuracy due to an elevation error, and it is not appropriate to set the section from the branch to the target position as the estimated section. . Therefore, the control unit 20 acquires a section obtained by extending a section from the branch to the target position to the opposite side of the branch as an estimated section. The extension distance may be determined in advance, and in the present embodiment, the extension distance is ½ of the predetermined distance.

  For example, in the example shown in FIG. 3B, when the distance Ls from the branch to the target position is larger than the threshold, the estimated section is a section from the branch to the target position. When the distance Ls from the branch to the target position is equal to or less than the threshold value, the estimated section is a section between the branch and a position at a distance of L / 2 forward from the target position. With the above configuration, it is possible to set an estimation section having a sufficient length for evaluating the estimated gradient of the target position. According to the above configuration, the estimated section can be acquired by adjusting the length or position to be an appropriate length based on the relationship between the branch and the target position.

  In any case, next, the control unit 20 acquires the estimated gradient of the target road by the processing of the reference road acquisition unit 21c (step S145). That is, the control unit 20 refers to the map information 30a, and acquires the gradient of the estimated section based on information indicating the elevation of the estimated section (for example, elevation information of the two most distant positions in the section). To do. Next, the control unit 20 acquires a connection road having an estimated gradient closest to the estimated gradient of the target road by the processing of the reference road acquisition unit 21c (step S150). That is, the control unit 20 compares the estimated gradient of the target road acquired in step S145 with the estimated gradient of the connected road acquired in step S120, and determines the connected road having the estimated gradient closest to the estimated gradient of the target road. get.

For example, in the example shown in FIG. 3B, the control unit 20 compares the estimated gradient of the connection road R ₂ and the connection road R _{3 with} the estimated gradient of the target road R ₁ , and the estimated gradient close to the estimated gradient of the target road R _1. Get connected roads. Next, the control part 20 sets a connection road to a reference road by the process of the reference road acquisition part 21c (step S155). That is, the control unit 20 regards the connection road acquired in step S150 as a reference road. Note that if there is no branch in either the front or the rear of the vehicle, the control unit 20 regards the target road as the reference road for the direction in which no branch exists. For example, in the example shown in FIG. 3B, the front of the reference road branch I is not present a target road R _1.

  On the other hand, when it is not determined in step S110 that a branch exists within the predetermined distance, the control unit 20 sets the target road as a reference road by the process of the reference road acquisition unit 21c (step S160). That is, in this case, there is no branch on the target road within a predetermined distance before and after the target road. Therefore, the control unit 20 regards the target road as a reference road.

If step S155 or S160 is performed, the control part 20 will acquire the reference position on a reference road by the process of the reference position acquisition part 21d (step S165). That is, the control unit 20 refers to the map information 30a, specifies a position at a predetermined distance from the target position on the reference road, and acquires the position as a reference position. For example, in the example shown in FIG. 3B, since the front of the vehicle there is no branching, the position P ₁ on the road R ₁ is the reference position. In the example shown in FIG. 3B, when the connecting road R ₂ is a reference road, a position P _{2 at a} distance L from the target position C is a reference position, and when the connecting road R ₃ is a reference road, a position at a distance L from the target position C. P ₃ is the reference position.

  Next, the control unit 20 acquires the gradient of the target road based on the altitude of the reference position by the processing of the gradient acquisition unit 21e (step S170). That is, the control unit 20 acquires the altitude of the reference position based on the map information 30a (if the altitude of the reference position itself does not exist in the map information 30a, it acquires the altitude of the reference position by interpolation or the like). Moreover, the control part 20 acquires the horizontal distance between reference positions based on the map information 30a. And the control part 20 acquires the altitude difference of a reference position / the horizontal distance of a reference position as a gradient value.

(3) Other embodiments:
The above embodiment is an example for carrying out the present invention, as long as a connected road having a gradient closest to the estimated gradient of the target road is specified, and the gradient of the target road is obtained by referring to the gradient of the connected road. Various other embodiments can be adopted. For example, the road gradient acquisition system 10 may be a terminal mounted on a vehicle or a terminal carried by a vehicle user. In addition, at least some of the functions of the target position acquisition unit 21a, the branch determination unit 21b, the reference road acquisition unit 21c, the reference position acquisition unit 21d, and the gradient acquisition unit 21e may be realized by a control entity different from the above-described embodiment. .

  Some functions may be omitted. Further, the control executed based on the gradient information is not limited to the deceleration control described above. For example, gradient information may be used for acceleration control, suspension control, auto cruise control, headlight direction control, and the like.

  The target position acquisition part should just be able to acquire the target position which is the position of the object which acquires a gradient. The target position may be determined by various methods, and may be configured such that the target position changes in accordance with the position change of a moving body such as a vehicle. The target position may be determined in advance, such as a position at a certain distance. The target position may be determined based on a rule. In the former case, the position of the moving body itself may be the target position, or the target position (for example, the front and rear positions) may be determined based on the position of the moving body.

  The branch determination unit only needs to be able to determine whether or not a branch where a plurality of connecting roads are connected to a target road where the target position exists is within a predetermined distance from the target position. That is, the branch determination unit can reproduce the position of the road and the road network based on the information indicating the road (such as map information), and the position of any road and the branch on each road based on the information. It is possible to identify connecting roads that connect to branches.

  Therefore, if the branch determination unit specifies the target position and the branch position based on the information, it is possible to determine whether there is a branch within a predetermined distance from the target position. . When there is a branch on the target road, a connection road is connected to the opposite side of the target road when viewed from the branch. Such roads are assumed to be various roads, for example, roads where three or more road sections are connected at one branch (intersection), or roads where one or more road sections are connected to the main line. Is done.

  The reference road acquisition unit only needs to be able to acquire the connection road having the gradient closest to the estimated gradient of the target road as the reference road when there is a branch, and to acquire the target road as the reference road when there is no branch. That is, the reference road acquisition unit acquires a reference road to be referred to when acquiring the gradient of the target position.

  Here, the reference road is a road for referring to an altitude for determining the gradient of the target road, which is the target road itself or a road continuous from the target road. If a branch exists within a predetermined distance from the target position, the reference road acquisition unit selects a road most suitable as a road for determining the gradient of the target road from a plurality of connected roads. A reference road. That is, in the configuration in which the gradient is acquired based on the elevation before and after the target position, the elevation at the reference position that is a predetermined distance away from the target position is referred to in order to reduce the influence of the information error indicating the elevation. It is desirable.

  For example, when the actual gradient of the target position is 1 m per unit horizontal distance and the altitude error is ± 1 m in the vertical direction, refer to the altitude at the reference position 1 m away from the target position in the horizontal distance. In such a case, the gradient may be reversed due to an error in altitude. Therefore, in order to prevent such erroneous calculation of the gradient, the reference position is set to a position at a predetermined distance before and after the target position. With such a configuration, the gradient of the target position can be calculated more accurately as the gradient moves away from the 0 (horizontal) state.

  In such a configuration, in order to reduce the influence of the altitude error, it is necessary to set the reference position at a position that is a predetermined distance away from the target position, but the reference position is away from the target position. As a result, there may be a plurality of reference position candidates behind (or in front of) the target position. In this case, since the altitudes of the plurality of reference positions do not always match, the gradient of the target road is incorrectly calculated depending on the selection of the reference position. Therefore, the reference road acquisition unit adopts a configuration in which a connection road having a gradient closest to the estimated gradient of the target road is selected as the reference road. According to this configuration, the gradient of the target road can be acquired more accurately. A connecting road can be selected from a plurality of connecting roads.

  The estimated gradient of the target road may be a value estimated as the gradient of the target road. That is, the estimated gradient is a value estimated in the sense that it is not a gradient acquired by the gradient acquisition unit because it is a value specified at a stage before acquisition of the gradient by the gradient acquisition unit. The estimated gradient acquisition method may be any method different from the gradient acquisition unit, and is preferably a simpler method than the gradient acquisition method by the gradient acquisition unit. For example, a configuration that acquires a gradient based on the altitude of at least two positions on the target road, a configuration that acquires a gradient based on the output value of a sensor provided in a moving body such as a vehicle, etc. can be adopted. It is.

  The reference position acquisition unit only needs to be able to acquire a reference position on a reference road that is a predetermined distance away from the target position. That is, the reference position acquisition unit specifies a position on the reference road that is a predetermined distance along the road from the target position based on information indicating the road (such as map information), and acquires the position as a reference position. I can do it. The predetermined distance may be determined in advance as a value that can reduce the influence of the error in the information indicating the altitude, and may be a variable value or a fixed value. Further, the predetermined distance may be the same before and after the target position, or may be a different value.

  The gradient acquisition unit only needs to be able to acquire the gradient of the target position based on the altitude of the reference position. That is, since at least one reference position is specified before and after the target position, the gradient acquisition unit specifies the altitude of each reference position based on information indicating the road (such as map information), and based on the altitude It is sufficient that the gradient of the target position between the reference positions can be specified. For example, a configuration in which the elevation difference / horizontal distance is a gradient value based on the elevation difference between the reference positions and the horizontal distance between the reference positions can be employed. Of course, the gradient may be specified by other units, for example, an angle.

  The estimated gradient can be specified by various configurations. For example, the estimated gradient may be acquired based on the altitude of the estimated section on the target road. That is, it is configured to be able to specify the estimated section according to a specific rule, and the reference road acquisition unit specifies the estimated section for an arbitrary target position, acquires a gradient based on the elevation of the estimated section, and estimates The gradient. Since the estimated section exists on the target road, it exists on the target position side of the branch. According to this configuration, it is possible to easily determine an estimation gradient acquisition target.

  Various rules can be adopted as the specific rule for defining the estimation section. A fixed-length section may be used as the estimation section, or a variable-length section may be used as the estimation section. Further, at least one of the length and the position of the estimated section may be configured to depend on the target position. According to this configuration, it is possible to set the estimation section according to the target position. Note that various configurations can be adopted as the configuration in which the position of the estimated section depends on the target position, and examples include a configuration in which the end point of the estimated section changes based on the target position.

  Furthermore, at least one of the length and the position of the estimated section may change based on the relationship between the branch and the target position. According to this configuration, the estimated section can be acquired by adjusting the length or position to be an appropriate length based on the relationship between the branch and the target position. As an example in which at least one of the length and position of the estimated section changes based on the relationship between the branch and the target position, at least one of the length and position of the estimated section based on the length of the section from the branch to the target position It is possible to adopt a configuration or the like that changes. That is, you may employ | adopt the structure which changes at least one of the length and position of an estimation area with the case where a branch and the object position are not separated enough.

  As a more specific example, for example, when the length of the section from the branch to the target position is larger than the threshold, the section from the branch to the target position is the estimated section, and the length of the section from the branch to the target position When is less than or equal to a threshold value, a configuration in which a section obtained by extending a section from a branch to a target position on the opposite side of the branch may be an estimated section. That is, the estimated section is set in order to evaluate the gradient of the connecting road connected to the branch. Therefore, it is preferable that the estimated section is set so that a connection road close to the estimated gradient of the estimated section can be specified.

  Therefore, if the section from the branch to the target position is the estimated section, the estimated section and the connected road exist continuously, and the estimated section is targeted so that the connected road close to the estimated slope of the estimated section can be identified. Can be set on the road. However, even in this configuration, if the section from the branch to the target position is too short, it is easily affected by a decrease in gradient acquisition accuracy due to an altitude error, and the section from the branch to the target position is regarded as the estimated section. It is not appropriate to do. Therefore, a threshold value for evaluating whether or not the section from the branch to the target position is excessively short is determined in advance, and whether or not the length of the section from the branch to the target position is larger than the threshold value. If the reference road acquisition unit is configured to change the estimated section, it is possible to set an estimated section having a sufficient length for evaluating the estimated gradient of the target position.

  Furthermore, when there is a branch, a method for identifying a connected road having a gradient closest to the estimated gradient of the target road and obtaining the gradient of the target road by referring to the gradient of the connected road is a method for performing this process or It can also be applied as a program. The road gradient acquisition system, method, and program as described above may be realized as a single device or as a plurality of devices. Moreover, it may be realized using parts shared with each part provided in the vehicle, or may be realized in cooperation with each part not mounted on the vehicle, and includes various aspects. 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 road gradient acquisition system. 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 ... Road gradient acquisition system, 20 ... Control part, 21 ... Road gradient acquisition program, 21a ... Target position acquisition part, 21b ... Branch determination part, 21c ... Reference road acquisition part, 21d ... Reference position acquisition part, 21e ... Gradient acquisition , 30 ... recording medium, 30a ... map information, 41 ... GPS receiver, 42 ... vehicle speed sensor, 43 ... gyro sensor, 44 ... speed change part, 45 ... braking part

Claims (7)

A target position acquisition unit for acquiring a target position of a target for acquiring a gradient;
A branch determination unit that determines whether a branch connecting a plurality of connecting roads to a target road where the target position exists is within a predetermined distance from the target position;
When the branch exists, the connection road of the gradient closest to the estimated gradient of the target road as a reference road, and when the branch does not exist, a reference road acquisition unit that acquires the target road as a reference road;
A reference position acquisition unit that acquires a reference position on the reference road that is a predetermined distance away from the target position in front and back;
A gradient acquisition unit that acquires a gradient of the target position based on an altitude of the reference position;
A road gradient acquisition system comprising: The estimated gradient is
Obtained based on the elevation of the estimated section on the target road,
The road gradient acquisition system according to claim 1. At least one of the length and position of the estimated section is
Depends on the target position,
The road gradient acquisition system according to claim 2. At least one of the length and position of the estimated section is
Change based on the relationship between the branch and the target position;
The road gradient acquisition system according to any one of claims 2 and 3. If the length of the section from the branch to the target position is greater than a threshold, the estimated section is a section from the branch to the target position;
When the length of the section from the branch to the target position is equal to or less than the threshold, the estimated section is a section obtained by extending the section from the branch to the target position on the opposite side of the branch.
The road gradient acquisition system according to any one of claims 2 to 4. A target position acquisition step of acquiring a target position that is a position of a target for acquiring a gradient;
A branch determination step of determining whether or not a branch connecting a plurality of connecting roads to a target road where the target position exists is within a predetermined distance from the target position;
A reference road acquisition step of acquiring the target road as a reference road when the branch is present, and using the connecting road having a gradient closest to the estimated gradient of the target road as a reference road;
A reference position acquisition step of acquiring a reference position on the reference road that is a predetermined distance away from the target position in front and back;
A gradient acquisition step of acquiring a gradient of the target position based on an altitude of the reference position;
Road gradient acquisition method including A target position acquisition function for acquiring a target position that is a target position for acquiring a gradient;
A branch determination function for determining whether a branch connecting a plurality of connecting roads to a target road where the target position exists is within a predetermined distance from the target position;
When the branch exists, the connection road of the gradient closest to the estimated gradient of the target road as a reference road, and when the branch does not exist, a reference road acquisition function for acquiring the target road as a reference road;
A reference position acquisition function for acquiring a reference position on the reference road at a predetermined distance away from the target position;
A gradient acquisition function for acquiring a gradient of the target position based on an altitude of the reference position;
A road gradient acquisition program that makes computers realize.

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