JP2020204548A - Current place acquiring system, and current place acquiring program - Google Patents

Abstract

To provide a technique capable of improving a possibility to improve accuracy in identifying a current place.SOLUTION: In a navigation system, a current place acquiring program 21 comprises: a communication control unit 21a for communicating with a roadside device; a road attribute estimation unit 21b for estimating a road attribute of a road where a vehicle exists; and a current place identifying unit 21c that acquires an estimated position of a vehicle, acquires a candidate position which is a candidate for a current place of the vehicle on a road indicated by map information on the basis of the road attribute and the estimated position, and identifies the current place of the vehicle from the candidate position. The current place identifying unit identifies the current place of the vehicle without referring to the road attribute when communication with the roadside device is performed.SELECTED DRAWING: Figure 1

Description

The present invention relates to a current location acquisition system and a current location acquisition program.

An electronic toll collection system for automatically collecting toll road usage fees is widespread. For example, it is possible to collect a toll from a vehicle user by communicating with a communication device provided in a vehicle passing through a tollhouse on a toll road and a roadside machine near the tollhouse. Vehicles passing through tollhouses entering toll roads and tollhouses in the middle of toll roads are traveling on toll roads, so conventional tollhouses have been used to identify the road attributes on which vehicles are traveling. Has been done. For example, Patent Document 1 discloses a configuration for determining whether a vehicle's traveling road is a toll road or a general road based on the toll collection signal received by the toll collection signal receiving means.

Japanese Unexamined Patent Publication No. 2001-304785

In recent years, it is expected to provide various services using a communication device common to an electronic toll collection system. As one of these services, there is a service that collects tolls other than toll road tolls. For example, it is possible to install a roadside machine at the entrance or exit of a parking lot and collect the parking lot fee by communicating with the roadside machine. Such a parking lot may also exist at a position accessible from a general road. Therefore, if it is determined that the vehicle is traveling on a toll road based on communication with a roadside unit installed in a parking lot that is accessible from a general road, the current location of the vehicle Is erroneously identified.
The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique capable of increasing the possibility of improving the accuracy of specifying the current location.

In order to achieve the above purpose, the current location acquisition system acquires the communication control unit that communicates with the roadside unit, the road attribute estimation unit that estimates the road attribute of the road on which the vehicle exists, and the estimated position of the vehicle, and obtains the road. The current location identification unit is provided with a current location identification unit that acquires a candidate position of the vehicle's current location on the road indicated by map information based on attributes and an estimated position and identifies the vehicle's current location from the candidate position. , When communication with the roadside machine is performed, the current location of the vehicle is specified without referring to the road attribute.

Further, in order to achieve the above object, the current location acquisition program acquires the communication control unit that communicates with the roadside unit, the road attribute estimation unit that estimates the road attribute of the road on which the vehicle exists, and the estimated position of the vehicle. Then, based on the road attributes and the estimated position, the candidate position that is a candidate for the current location of the vehicle on the road indicated by the map information is acquired, and the current location that functions as the current location identification unit that identifies the current location of the vehicle from the candidate position is acquired. In the program, the current location identification unit causes the computer to function so as to identify the current location of the vehicle without referring to the road attribute when communication with the roadside aircraft is performed.

That is, in the current location acquisition system and program, the road attribute of the road on which the vehicle exists is estimated, and the candidate positions that are candidates for the current location where the vehicle exists are narrowed down based on the road attribute. However, when communication with a roadside machine is performed, it is assumed that the roadside machine is installed at a tollhouse on a toll road or at a position where communication is possible while driving on a general road. Toll. Therefore, the current location identification unit identifies the current location of the vehicle without referring to the road attributes when communication with the roadside aircraft is performed. According to this configuration, it is possible to prevent erroneous detection of the current location of the vehicle by limiting the road attributes, and it is possible to increase the possibility of improving the accuracy of identifying the current location.

It is a block diagram which shows the navigation system including the present location acquisition system. 2A-2C are diagrams for explaining the position by the road schematically shown. It is a flowchart of the present location identification process.

Here, embodiments of the present invention will be described in the following order.
(1) Navigation system configuration:
(2) Current location identification process:
(3) Other embodiments:

(1) Navigation system configuration:
FIG. 1 is a block diagram showing a configuration of a current location acquisition system mounted on a vehicle. In the present embodiment, the current location acquisition system is realized by the navigation system 10. The navigation system 10 includes a control unit 20 including a CPU, RAM, 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.

The vehicle according to this embodiment includes a GNSS receiving unit 41, a vehicle speed sensor 42, a gyro sensor 43, a communication unit 44, and a user I / F unit 45. The communication unit 44 is provided with a circuit that communicates with a roadside unit for collecting tolls installed at a tollhouse on a toll road or a roadside unit for collecting tolls in a parking lot other than a toll road. The control unit 20 can control the communication unit 44 to acquire the communication content with the roadside machine.

The user I / F unit 45 is an interface unit for inputting instructions from the user (driver) and providing various information to the user, and is an input unit such as a display unit or a switch composed of a touch panel display (not shown). It is equipped with an audio output unit such as a unit and a speaker. The user I / F unit 45 receives the control signal from the control unit 20 and displays an image for performing various guidance such as route guidance on the touch panel display.

The control unit 20 can execute the navigation program recorded in the ROM or the like. The navigation program is a program that allows the control unit 20 to realize a function of displaying a map including the current location of the vehicle on the display unit of the user I / F unit 45 and guiding the driver to the destination. That is, the control unit 20 acquires the destination instructed by the user via the user I / F unit 45 by the navigation program. Then, the control unit 20 searches for a route from the current location to the destination based on the map information 30a, and executes guidance for guiding the vehicle along the route. The navigation program includes a current location acquisition program 21 that realizes a function of acquiring the current location of the vehicle in order to guide the route and display the current location of the vehicle on the map.

Map information 30a is recorded on the recording medium 30. The map information 30a includes node data indicating the positions of nodes corresponding to the end points of the road section on which the vehicle travels, shape interpolation point data indicating the positions of shape interpolation points for specifying the shape of the road section between nodes, and the like. It includes link data indicating the connection between nodes, facility data indicating facilities existing around the road, and the like. In the present embodiment, a node that is an end point of a road section corresponds to an intersection.

Further, in the present embodiment, the link data is associated with information indicating the road attribute (road type, etc.) and link cost of each road section indicated by each link data, and the direction in which the vehicle can travel on the road section. In the present embodiment, the road attribute is a toll road or a general road, but of course, the road attribute may be further subdivided. Further, in the present embodiment, the road attribute of the access road for moving between the general road and the main line of the toll road is a toll road.

In addition, facility data includes facility attributes. The attributes of the facility include information such as stores and tollhouses. In the present embodiment, the tollhouse exists on the main line of the toll road or on the access road as the toll road. In the tollhouse of the present embodiment, a roadside machine capable of communicating with the traveling vehicle is installed in at least one lane in which the vehicle travels when passing through the tollhouse.

The communication control unit 21a included in the current location acquisition program 21 is a program module that causes the control unit 20 to execute a function of communicating with the roadside unit. That is, the control unit 20 can control the communication unit 44 by the function of the communication control unit 21a and communicate with the roadside unit around the vehicle. The roadside unit installed at the tollhouse on the toll road has a communication range set so that it can communicate with the communication unit 44 of the vehicle passing through the tollhouse through a specific lane.

The roadside unit installed at the tollhouse on the toll road can communicate with the communication unit 44 mounted on the vehicle by a predetermined communication method, and when a predetermined authentication is performed, it becomes a server (not shown) for billing. Communicate and have the vehicle user process the toll road usage fee. The roadside unit for collecting tolls for parking lots and the like other than the toll road also communicates with the communication unit 44 using the same communication standard as the roadside unit installed at the tollhouse of the toll road. The roadside machine is installed in a parking lot or the like accessible from a general road, and the roadside machine installed in the parking lot or the like can communicate with a communication unit 44 of a vehicle passing through a predetermined area (for example, a gate). The communication range is set so as to.

As described above, the communication unit 44 can communicate with both the roadside machine installed at the tollhouse of the toll road and the roadside machine installed at the parking lot or the like with the same communication standard. When communication is performed with the roadside unit, the control unit 20 records information (position, time, communication standard, etc.) indicating that the communication has been performed in the RAM or the recording medium 30.

In the present embodiment, the control unit 20 identifies the current location of the vehicle for route guidance, display of the current location of the vehicle on a map, and the like by the function of the navigation program. The navigation program includes the above-mentioned current location acquisition program 21 in order to realize a function of acquiring the current location of the vehicle and displaying it on the output unit of the user I / F unit 45. The current location acquisition program 21 includes a road attribute estimation unit 21b, a current location identification unit 21c, and an output control unit 21d in addition to the communication control unit 21a described above.

The road attribute estimation unit 21b is a program module that causes the control unit 20 to execute a function of estimating the road attribute of the road on which the vehicle exists. In the present embodiment, the control unit 20 estimates the road attribute of the road on which the vehicle is located based on the movement of the vehicle. As the operation of the vehicle, for example, the vehicle speed can be used. In this case, the control unit 20 acquires the vehicle speed history based on the output of the vehicle speed sensor 42 and records the vehicle speed on the recording medium 30 and the like. Based on the history of the vehicle speed, the control unit 20 specifies the average vehicle speed within the predetermined period before the present, and when the average vehicle speed is larger than the standard, it estimates that the current location of the vehicle is on the toll road. When the average vehicle speed is below the standard, the control unit 20 estimates that the current location of the vehicle is on a general road. Of course, the road attribute may be estimated by various other factors, and even if the average vehicle speed is below the standard, the road attribute is indefinite when traffic jams occur. May be good.

The current location identification unit 21c acquires the estimated position of the vehicle, acquires the candidate position that is a candidate for the current location of the vehicle on the road indicated by the map information based on the road attribute and the estimated position, and acquires the current location of the vehicle from the candidate position. This is a program module that causes the control unit 20 to execute a function of specifying the above. In the present embodiment, the control unit 20 identifies the current location by using the outputs of the GNSS receiving unit 41, the vehicle speed sensor 42, and the gyro sensor 43, the map information 30a, and the operation of the vehicle.

The GNSS receiving unit 41 is a device that receives signals from the Global Navigation Satellite System, receives radio waves from navigation satellites, and outputs a signal for calculating the current location of the vehicle to the control unit 20 via an interface (not shown). .. The vehicle speed sensor 42 outputs a signal corresponding to the rotation speed of the wheels included in the vehicle to the control unit 20. The gyro sensor 43 outputs a signal corresponding to the angular acceleration acting on the vehicle to the control unit 20.

The control unit 20 acquires the self-contained navigation locus, which is the locus of the vehicle position estimated based on the signals output from the vehicle speed sensor 42 and the gyro sensor 43, by the function of the current location identification unit 21c. That is, the control unit 20 specifies the relative movement distance and the relative change in the direction of the vehicle after the reference position (current location calculated based on the output of the GNSS receiving unit 41) by a predetermined period (distance or time length). It is acquired for each cycle), and the transition in the time series is acquired as an independent navigation trajectory. Therefore, the self-contained navigation locus is the locus of the position of the vehicle for each predetermined cycle, and in the present embodiment, the latest vehicle position acquired by the self-contained navigation locus is referred to as an estimated position.

In this embodiment, the output of the GNSS receiving unit 41 is used to acquire a candidate position based on the estimated position. That is, an error circle for evaluating the position error of the GNSS signal can be obtained from the signal acquired by the GNSS receiving unit 41. The control unit 20 narrows down the road section where the candidate position can exist based on the error circle.

FIG. 2A shows an example of a road. In FIG. 2A, the solid line is a general road and the broken line is a toll road. In the example shown in FIG. 2A, the vehicle can enter the toll road R3 from the general road R1 through the access road R2 which is a toll road. Further, in the example shown in FIG. 2A, the alternate long and short dash line indicates (a part of) the self-contained navigation locus, and the tip thereof is the latest vehicle position, that is, the estimated position Ps. Further, in FIG. 2A, the error circle Cr is indicated by a chain double-dashed line.

When the road attribute is estimated, the control unit 20 narrows down the road section by selecting the road section of the estimated road attribute from the error circle Cr and excluding the road section different from the estimated road attribute. That is, the control unit 20 refers to the map information 30a and identifies a road that matches the estimated road attribute from the roads existing in the error circle Cr. Then, the road is set as a road where a candidate position can exist. Do not select candidate locations from roads that do not match the estimated road attributes. When the road attribute of the road on which the vehicle exists is not estimated (or is undefined), the control unit 20 refers to the map information 30a, and a candidate position exists for any road existing in the error circle Cr. It is a possible road.

For example, in the example shown in FIG. 2A, when the road attribute of the road on which the vehicle exists is estimated to be a toll road, candidates are placed on the access road R2 and the toll road R3 which are toll roads existing in the error circle Cr. The position can exist. On the other hand, it is said that there is no candidate position on the general road R1 which is a general road existing in the error circle Cr. When the road attribute of the road on which the vehicle exists is estimated to be a general road, a candidate position may exist on the general road R1 which is a general road existing in the error circle Cr. On the other hand, it is said that there is no candidate position on the access road R2 and the toll road R3, which are toll roads existing in the error circle Cr.

Further, in the example shown in FIG. 2A, in the present embodiment, the road section included in the error circle Cr and where the candidate position can exist based on the road attribute is compared with the self-contained navigation locus. That is, the control unit 20 sets candidate positions for each of the road sections to be compared based on the estimated positions. The candidate position may be set by various methods. For example, the position closest to the estimated position on each road section may be the candidate position. With one or more candidate positions acquired in this way, the control unit 20 identifies the most probable position from the candidate positions and considers it as the current location.

The method for identifying the most probable position from the candidate position may be various methods, and for example, estimation by map matching processing is used. When performing the map matching process, the control unit 20 refers to the map information 30a and evaluates the degree to which the shape of the road section existing in the error circle matches the self-contained navigation locus. This evaluation is defined by, for example, the sum of the cost that decreases as the distance between the estimated position and the road section decreases and the cost that decreases as the deviation between the direction of the self-contained navigation locus and the direction of the road section decreases. That is, the control unit 20 considers that the candidate position on the road section having the smallest sum of costs described above is the most probable position, and specifies the candidate position as the current location.

In the present embodiment, the candidate positions are limited based on the road attributes as described above, and the current location of the vehicle is specified from the limited candidate positions. However, in order to reduce the false detection of the current location, the road It may be better not to limit the candidate positions by attributes. That is, the communication unit 44 can communicate with the roadside unit existing on or around the road, and the roadside unit can be installed at a tollhouse on a toll road or parked near a general road. It can be installed in a parking lot or the like.

In the example shown in FIG. 2A, the parking lot P exists near the intersection I1 which is the entrance of the access road R2, and the roadside machine Ma for collecting the parking fee is installed at the entrance / exit of the parking lot P. An example is shown. Further, in the example shown in FIG. 2B, the roadside machine Mb is installed at the tollhouse near the intersection I2 between the access road R2 and the toll road R3. In this example, the traveling direction on the access road R2 is the direction from the intersection I1 to the intersection I2. In such an example, there are a roadside machine Ma for collecting the parking fee and a roadside machine Mb installed at the tollhouse around the estimated position Ps of the vehicle.

Therefore, even if the communication unit 44 can communicate with the roadside unit by the leaked radio wave of the roadside unit at the estimated position Ps, the road attribute of the road on which the vehicle exists cannot be limited by itself. That is, communication with the roadside machine is performed when the vehicle is traveling on the general road R1 and is performed by a leaked radio wave from the roadside machine Ma, or when the vehicle is traveling on the attachment road R2 and the roadside machine. It may or may not have been done by approaching the Mb. Therefore, if the candidate positions are limited based on the road attributes when communicating with the roadside unit, the current location of the vehicle may be erroneously detected.

Therefore, in the present embodiment, the control unit 20 performs processing by the function of the current location identification unit 21c so that the possibility of erroneous detection occurring when communication with the roadside unit is reduced. Specifically, the control unit 20 identifies the current location of the vehicle without referring to the road attribute when communication with the roadside unit is performed by the function of the current location identification unit 21c. That is, the control unit 20 does not limit the road attribute of the road section in which the candidate position can exist, and makes the candidate position exist on the road of any road attribute. Therefore, when the control unit 20 narrows down the candidate positions based on the estimated positions, the control unit 20 is included in the error circle Cr of the GNSS receiving unit 41, and the road section of any road attribute is compared with the self-contained navigation locus. And.

Then, the control unit 20 calculates the cost based on the estimated position for each of the candidate positions set on the road of any road attribute in the error circle Cr, and the candidate position with the lowest cost is the current location of the vehicle. Consider that there is. For example, if communication with the roadside unit is performed in the example shown in FIGS. 2A and 2B, a candidate position is set on a road having an arbitrary road attribute existing in the error circle Cr. Therefore, the control unit 20 acquires the cost for each of the candidate positions Pc1, Pc2, and Pc3, and considers that the candidate position with the lowest cost is the current location of the vehicle.

As described above, in the present embodiment, when communication is performed with the roadside unit, the control unit 20 considers that the current location of the vehicle may be either a toll road or a general road, and limits the road attributes. Identify the current location of the vehicle without doing so. This configuration reduces the possibility that the vehicle is on a toll road but is considered to be on an open road. It also reduces the likelihood that the vehicle will be on a toll road even though it is on an open road. As a result, it is possible to increase the possibility of improving the accuracy of identifying the current location. When the current location of the vehicle is specified, the control unit 20 controls the output unit of the user I / F unit 45 by the function of the output control unit 21d to display the current location of the vehicle on the map.

(2) Current location identification process:
Next, an example of the current location identification process executed by the control unit 20 will be described with reference to FIG. When the navigation system 10 is started, the current location identification process is executed at regular intervals (for example, 100 ms).

When the current location identification process is started, the control unit 20 acquires the road attribute of the road on which the vehicle exists by the function of the road attribute estimation unit 21b (step S100). That is, the control unit 20 estimates the road attribute of the road on which the vehicle exists based on the movement of the vehicle. For example, when the vehicle speed is used as the operation of the vehicle, the control unit 20 estimates that the current location of the vehicle is on the toll road when the average vehicle speed within the predetermined period before the present is larger than the reference. When the vehicle speed is below the standard, the control unit 20 estimates that the current location of the vehicle is on a general road. For example, in the example shown in FIG. 2A, when the vehicle speed is equal to or lower than the reference value, the control unit 20 estimates that the road attribute of the road on which the vehicle is present is a general road.

Next, the control unit 20 acquires the estimated position of the vehicle by the function of the current location identification unit 21c (step S102). That is, the control unit 20 acquires the self-contained navigation locus based on the output signals of the vehicle speed sensor 42 and the gyro sensor 43, and acquires the latest vehicle position indicated by the self-contained navigation locus as an estimated position. For example, in the example shown in FIG. 2A, the latest position in the self-contained navigation locus shown by the alternate long and short dash line is acquired as the estimated position Ps.

Next, the control unit 20 acquires a candidate position by the function of the current location identification unit 21c (step S105). That is, the control unit 20 acquires an error circle from the signal acquired by the GNSS receiving unit 41. Further, the control unit 20 refers to the map information 30a, acquires a road section having a road attribute that is included in an error circle centered on the estimated position and is estimated to have a vehicle, as a road to be compared, and is a comparison target. Get the candidate position from the road. As a result, for example, in the example shown in FIG. 2A, when the road attribute of the road on which the vehicle exists is estimated to be a general road, the candidate position Pc3 on the road section existing in the error circle Cr is acquired. ..

Next, the control unit 20 identifies the current location (step S110). That is, for each candidate position, the control unit 20 determines the cost due to the distance between the estimated position and the candidate position acquired in step S102 and the cost due to the deviation between the direction of the self-contained navigation locus and the direction of the road where the candidate position exists. , Get the cost due to the operation of the vehicle (vehicle speed), and get the sum of the costs. Then, the control unit 20 specifies that the candidate position having the smallest sum of costs is the current vehicle location.

In the example shown in FIG. 2A, when the road attribute of the road on which the vehicle exists is estimated to be a general road, the candidate position on the road section existing in the error circle Cr is only the candidate position Pc3, so that the candidate is a candidate. The position Pc3 is specified as the current location. In the example shown in FIG. 2A, when the road attribute of the road on which the vehicle exists is estimated to be a toll road, the current location is specified from the candidate positions Pc1 and Pc2 on the road section existing in the error circle Cr.

Next, the control unit 20 determines whether or not communication with the roadside unit has been performed by the function of the current location identification unit 21c (step S115). That is, the control unit 20 acquires the communication start request transmitted from the roadside unit at an arbitrary timing via the communication unit 44 by the function of the communication control unit 21a, and communicates with the roadside unit. When communication is performed with the roadside unit, information indicating that the communication has been performed is recorded in the RAM or the recording medium 30. Therefore, the control unit 20 refers to the record, and if there is a history of communicating with the roadside unit in the predetermined period before the present, it determines that the communication with the roadside unit has been performed.

If it is not determined in step S115 that communication with the roadside unit has been performed, the control unit 20 skips the processes after step S120. In this case, the current location specified in step S110 is not corrected. Therefore, the current location displayed by the control unit 20 on the output unit of the user I / F unit 45 by the function of the output control unit 21d and the current location used for route guidance are the current locations specified in step S110.

On the other hand, when it is determined in step S115 that communication with the roadside unit has been performed, the road attribute of the road on which the vehicle exists may be a general road or a toll road. For example, in the example shown in FIG. 2B, the roadside machine Mb installed at the tollhouse and the roadside machine Ma for collecting the parking fee are nearby. Therefore, if the estimated position in the vehicle is the estimated position Ps, communication from any roadside unit can be established, but if the vehicle is traveling on the access road R2 which is a toll road, the road attribute is If it remains presumed to be a general road, the current location of the vehicle will not be accurately identified.

Therefore, when it is determined that the communication with the roadside unit has been performed, the control unit 20 resets the estimation of the road attribute in the present embodiment and specifies the current location again. When the current location is specified again, the estimation of the road attribute may be reset and the current location may be specified in a state where the candidate position can be set on the road of any road attribute, and other factors are taken into consideration. May be done. The flowchart shown in FIG. 3 determines whether or not evidence can be collected to support that the roadside aircraft is a roadside aircraft for collecting toll road tolls, and if evidence is collected, the candidate position on the toll road is determined. This is a process that increases the possibility of being the current location.

In order to perform the above processing, the control unit 20 determines whether or not the toll road exists within the predetermined range from the estimated position by the function of the current location identification unit 21c (step S120). That is, the control unit 20 refers to the map information 30a and identifies a road section existing within a predetermined range from the estimated position acquired in step S102. Then, the control unit 20 acquires the road attribute of the road section with reference to the map information 30a, and when the road section whose road attribute is a toll road is included, the toll road exists within the predetermined range from the estimated position. judge. For example, in the example shown in FIG. 2A, when the default range is the circle C indicated by the broken line, it is determined that the access road R2, which is a toll road, exists within the default range from the estimated position Ps. In this embodiment, the radius of the error circle Cr> the radius of the circle C.

If it is not determined in step S120 that the toll road exists within the predetermined range from the estimated position, the control unit 20 skips the processing after step S125. That is, if the toll road does not exist within the predetermined range from the estimated position, it is unlikely that the current location exists on the toll road. Therefore, in the present embodiment, when the current location is unlikely to exist on the toll road, the control unit 20 is not subjected to an unnecessary processing load by skipping the process of specifying the current location based on the position of the tollhouse. Can be done.

When it is determined in step S120 that the toll road exists within the predetermined range from the estimated position, the control unit 20 uses the function of the current location identification unit 21c to determine a candidate position where the distance from the tollhouse of the toll road is equal to or less than the threshold value. It is determined whether or not it exists (step S125). That is, the control unit 20 refers to the map information 30a and acquires a candidate position existing on the road existing in the error circle Cr. Then, the control unit 20 identifies the tollhouse existing on the road where the candidate position exists, and determines whether or not the distance between each candidate position and the tollhouse is equal to or less than the threshold value.

For example, in the example shown in FIGS. 2A and 2B, the control unit 20 acquires the candidate position Pc1 set on the access road R2. In this example, there is a tollhouse where the roadside machine Mb is installed on the access road R2 where the candidate position Pc1 exists. Therefore, the control unit 20 determines whether or not the candidate position exists within the range in which the distance from the position of the tollhouse where the roadside machine Mb is installed is equal to or less than the threshold value, based on the map information 30a. For example, in the example shown in FIG. 2C, since the candidate positions Pc1 and Pc2 exist in the circle Ct, the control unit 20 has the candidate positions Pc1 and Pc2 whose distance from the tollhouse on the toll road is equal to or less than the threshold value. Then it is determined. In this way, when communication with the roadside machine is performed, the roadside machine with which communication is performed is further determined by determining whether or not there is a candidate position having a small distance from the tollhouse on the toll road. It is possible to determine whether or not the vehicle is in a state where it is very likely that it is a roadside machine for collecting toll road tolls.

If it is not determined in step S125 that there is a candidate position whose distance to the tollhouse on the toll road is equal to or less than the threshold value, it cannot be determined whether or not the vehicle is likely to be traveling on the toll road. Therefore, the control unit 20 skips the processing after step S130. On the other hand, in step S125, when it is determined that there is a candidate position whose distance from the tollhouse on the toll road is equal to or less than the threshold value, the control unit 20 uses the function of the current location identification unit 21c to move the vehicle on the toll road. It is determined whether or not it matches the traveling direction of the vehicle in (step S130).

That is, since there are restrictions on the direction of travel that the vehicle should follow on the road, it can be considered that the road that cannot travel in the direction in which the vehicle is actually traveling does not become the current location of the vehicle. Therefore, the control unit 20 identifies the traveling direction in which the vehicle has traveled in the predetermined period before the present, based on the locus of the estimated position acquired in step S102, that is, the self-contained navigation locus. Further, the control unit 20 refers to the map information 30a, specifies the travelable direction on the toll road determined to have the candidate position in step S125, and acquires it as the traveling direction of the vehicle on the toll road.

Then, the control unit 20 acquires the minimum rotation angle required to rotate the current traveling direction of the vehicle indicated by the self-contained navigation trajectory to the traveling direction of the vehicle on the toll road where the candidate position exists, and rotates. If the angle is less than or equal to the reference angle, the two are considered to match. The reference angle may be an index for determining whether or not the traveling direction of the vehicle and the traveling direction on the road are inconsistent. For example, 15 °, 30 °, 45 °, 60. It is a value such as °, 75 ° 90 °, and the like.

In step S130, if it is not determined that the traveling direction of the vehicle matches the traveling direction of the vehicle on the toll road, the control unit 20 skips the processes after step S132. That is, if the direction of travel of the vehicle does not match the direction of travel of the vehicle on the toll road, it is unlikely that the current location is close to the tollhouse on the toll road. Therefore, in the present embodiment, when the traveling direction of the vehicle does not match the traveling direction of the vehicle on the toll road, it is considered that no evidence supporting the vehicle traveling on the toll road has been found, and step S132 or later. Skip the processing of.

When it is determined in step S130 that the traveling direction of the vehicle matches the traveling direction of the vehicle on the toll road, the control unit 20 determines that the road attribute is a general road in step S100 by the function of the current location identification unit 21c. It is determined whether or not it has been estimated (step S132).

If it is not determined in step S132 that the road attribute is presumed to be a general road, the control unit 20 skips the processing after step S133. That is, the current location specified in step S110 is not corrected. Therefore, the current location displayed by the control unit 20 on the output unit of the user I / F unit 45 by the function of the output control unit 21d and the current location used for route guidance are the current locations specified in step S110.

On the other hand, when it is determined in step S132 that the road attribute has already been estimated to be a general road, the control unit 20 resets the estimation of the road attribute by the function of the current location specifying unit 21c (step S133). That is, the control unit 20 performs the process for specifying the current location again without referring to the estimation result of step S100 that the road attribute is a general road.

In the flowchart shown in FIG. 3, in order to identify the current location, the current location of the vehicle is re-identified after collecting evidence that the roadside aircraft with which communication has been performed is a roadside aircraft installed at a tollhouse on a toll road. .. Therefore, in the re-identification, the control unit 20 specifies the current location based on the position of the tollhouse (step S135). Specifically, the control unit 20 executes the processes of steps S102 to S110 again, but the estimation of the road attribute is reset. Therefore, in step S105, candidates for roads with arbitrary road attributes within the error circle Cr are candidates. The position is acquired. For example, in the example shown in FIG. 2C, the candidate positions Pc1, Pc2, and Pc3 are acquired.

Then, when the step S110 is executed again, the control unit 20 recalculates the cost for each candidate position, and the control unit 20 includes the cost according to the position of the tollhouse in the total cost. That is, in step S125, the control unit 20 compares the candidate position where the distance to the tollhouse is determined to be equal to or less than the threshold value with the candidate position where the distance to the tollhouse is determined to be greater than the threshold value. Then, set a cost of a smaller value and add it to the total cost of each candidate position. Then, the control unit 20 considers that the candidate position having the lowest cost is the current location of the vehicle. As a result, for example, in the example shown in FIG. 2C, the candidate positions Pc1 and Pc2 are more likely to be identified as the current location of the vehicle as compared with the candidate positions Pc3.

When the current location of the vehicle is specified as described above, the control unit 20 considers the current location specified by referring to the position of the tollhouse in step S135 as the current location of the vehicle instead of the current location specified in step S110. .. As a result, even if the estimation of the road attribute is incorrect, the estimation can be canceled and the current location of the vehicle can be specified. As a result, the possibility of erroneously detecting the current location of the vehicle is reduced.

(3) Other embodiments:
The above embodiment is an example for carrying out the present invention, and various other embodiments are provided as long as the current location of the vehicle is specified without referring to the road attribute when communication with the roadside unit is performed. The form can be adopted. For example, the navigation system 10 may be a device mounted on a vehicle or the like, a device realized by a portable terminal, or a device realized by a plurality of devices (for example, a client and a server). System may be used. Further, at least a part of the communication control unit 21a, the road attribute estimation unit 21b, the current location identification unit 21c, and the output control unit 21d constituting the current location acquisition system may be divided into a plurality of devices and exist.

Further, some configurations of the above-described embodiments may be omitted, and the order of processing may be changed or omitted. For example, the order of steps S120, S125, and S130 may be changed. Further, in the current location identification process shown in FIG. 3, steps S120, S125, and S130 may be omitted. In this case, regardless of whether the road attribute estimation result is a general road or a toll road, the control unit 20 may be configured to reset the road attribute estimation in step S132. Further, in this case, in step S135, the control unit 20 performs the same processing as in steps S102 to S110 to specify the current location, but at this time, the road attribute is not limited.

Further, in the current location identification process shown in FIG. 3, steps S120, S125, and S130 may be executed after step S133. That is, when communication with the roadside unit is performed, the control unit 20 may reset the road attribute estimation in step S132 regardless of whether the road attribute estimation result is a general road or a toll road. .. After that, the control unit 20 may be configured to determine whether or not it is close to the roadside machine installed at the tollhouse of the toll road by executing at least one of steps S120, S125, and S130.

In this case, in specifying the current location in step S135, the cost is adjusted according to the determination result in at least one of steps S120, S125, and S130. That is, in step S135, the control unit 20 calculates the cost for the candidate position on the road having an arbitrary road attribute, and specifies the current location from the cost of each candidate position. At this time, if at least one of steps S120, S125, and S130 provides evidence that the vehicle exists on the road where the tollhouse exists, the control unit 20 controls the control unit 20 on the road where the tollhouse exists. For the candidate position, set a cost smaller than the other candidate positions and include it in the sum.

Further, the flowchart shown in FIG. 3 is an example of resetting the estimation when the road attribute is estimated to be a general road, but when the road attribute is estimated to be a toll road. It may be configured to reset the estimation.

Further, in the above-described embodiment, the roadside unit for collecting tolls (for example, a radio beacon roadside unit) is focused on, and the estimation result of the road attribute is referred to when communication is performed with the roadside unit for collecting tolls. The configuration is such that the current location of the vehicle is specified without doing so. However, the same processing may be performed for a roadside machine other than the roadside machine for collecting tolls. For example, the roadside unit may include a roadside unit (optical beacon roadside unit) mainly installed on a general road in order to transmit traffic information. Even if these roadside aircraft are included, there is no change in the possibility of false detection if the road attributes are limited when communication with the roadside aircraft is established. Therefore, in a configuration in which the communication unit 44 can communicate with the roadside unit of various communication methods, the current location of the vehicle is specified without referring to the road attribute when the communication with the roadside unit is performed. May be good.

The communication control unit only needs to be able to communicate with the roadside unit. That is, the communication control unit may be configured so as to be able to communicate with the roadside unit existing outside the vehicle while the vehicle is traveling. The roadside unit may be installed on the road or at a position around the road, and may be able to communicate with the current location acquisition system in the vehicle. Of course, the communication method of the roadside unit is not limited, but it is preferable that the roadside unit communicates by the same communication method as the toll collection system installed in connection with the toll road.

Further, the communication purpose of the roadside machine is not limited, and various roadside machines may be used in addition to the roadside machine for collecting usage fees for parking lots and the like. For example, it may be a roadside machine for collecting toll road tolls, or a roadside machine for warning that it is impossible to collect toll road usage fees (warning that a card is not inserted, etc.). There may be other roadside aircraft that are used for any purpose.

The road attribute estimation unit only needs to be able to estimate the road attribute of the road on which the vehicle exists. That is, when the road on which the vehicle is located is limited, the candidate positions that are candidates for the current location of the vehicle can be limited. The estimation of the road attribute may be performed by various methods, and factors other than the operation of the vehicle such as the average vehicle speed of the vehicle can be used. For example, a communication history between a roadside machine for collecting tolls and a roadside machine different from the roadside machine (a roadside machine using an optical beacon existing on a general road, etc.) may be used. Further, for example, the road attribute may be estimated based on the features existing around the vehicle (for example, the type and color of the road sign existing around the road, the presence or absence of a traffic light, etc.). The road attribute is used to limit the candidate position, and the position on the road of the road attribute may be the candidate position.

The current location identification unit acquires the estimated position of the vehicle, acquires the candidate position that is a candidate for the current location of the vehicle on the road indicated by the map information based on the road attribute and the estimated position, and obtains the current location of the vehicle from the candidate position. Identify. That is, the current location identification unit identifies the most probable current location from a plurality of viewpoints. For this purpose, the current location identification unit acquires the estimated position of the vehicle. The estimated position of the vehicle is the current location of the vehicle estimated by the determined method, but the candidate position is obtained by evaluating the estimated position from a different viewpoint from the determined method, and the most candidate position is obtained. It would be good if a certain position could be obtained as the current location.

Therefore, the estimated position is acquired based on the self-contained navigation trajectory, the candidate position is acquired based on the road attribute, the radio wave from the navigation satellite, and the map information, and based on the map information (map matching), the position of the tollhouse, etc. In addition to the configuration in which the current location is specified from the candidate positions, various configurations may be adopted. For example, the estimated position may be acquired based on the locus of the position estimated by the radio wave from the navigation satellite, and the candidate position may be acquired based on at least one of the self-contained navigation locus and the map information.

Further, either or both of the position of the vehicle acquired based on the self-contained navigation trajectory and the position estimated by the radio wave from the navigation satellite may be used for acquiring the estimated position. For example, if the reliability of the position estimated by the radio waves from the navigation satellite is higher than the reliability of the position of the vehicle acquired based on the self-contained navigation trajectory, based on the position estimated by the radio waves from the navigation satellite. It is possible to adopt a configuration in which the estimated position is acquired. Of course, the estimated position may be obtained by the weighted average of both. Further, the method for obtaining the estimated position and the candidate position is not limited to the above-mentioned method, and the information acquired by the sensor such as a camera or LIDAR may be referred to when determining at least one of the estimated position or the candidate position. Good.

The estimated position and the candidate position are defined by different methods, but for example, the positions where both can exist may be different. That is, the estimated position may be determined without the restriction of being on the road, and the candidate position may be determined by imposing the restriction of being on the road indicated by the map information. Specifically, when a certain position other than on the road becomes the estimated position, the position on the road existing around the position becomes the candidate position.

The current location identification unit may change the current location identification method depending on the conditions when identifying the current location of the vehicle based on the candidate position. That is, the method of specifying the current location may be changed depending on whether the communication with the roadside aircraft is performed or not within the predetermined period before the present, and the current location of the vehicle can be changed without referring to the road attribute. You may specify.

Specifically, the road attribute is usually a clue to consider that the candidate for the current location of the vehicle is on the road of the road attribute, but when communication is performed with the roadside aircraft, the roadside aircraft is on the toll road, generally. Considering that it is installed on the road (or near a general road), the limitation of road attributes is not always correct. Therefore, if the road attribute is not referred to when communicating with the roadside unit, it is possible to prevent erroneous determination of the current location due to the limitation of the road attribute.

Further, when communication is performed with the roadside unit and there is a candidate position where the distance to the tollhouse on the toll road is equal to or less than the threshold value, it is highly probable that the candidate position is the current location. Therefore, in this case, a configuration that specifies the current location based on the position of the tollhouse may be adopted.

The threshold for evaluating the distance between the tollhouse and the candidate position on the toll road is that if the candidate position is sufficiently close to the tollhouse and such a candidate position exists, communication with the roadside aircraft is on the toll road. It suffices if it is defined so that it can be considered appropriate to presume that it is communication with the above roadside unit. That is, in a situation where it is highly probable that the current location is near the toll road due to the existence of the communication history with the roadside machine, the candidate position is evaluated based on the position of the tollhouse, which is information other than communication. Will be done.

If the location of the tollhouse is close to the candidate location, it is highly probable that the roadside aircraft used for communication is near the current toll road. In this way, if the current location is likely to be near the tollhouse, it can be used to identify the current location, assuming that the candidate position near the tollhouse is likely to be the current location. The threshold value may be defined so that it is appropriate to presume that the communication with the roadside unit is the communication with the roadside unit on the toll road, for example, in the range of 1 to 20 m. It can be defined by any value included.

Further, the method of identifying the current location of the vehicle without referring to the road attribute when the communication with the roadside machine is performed as in the present invention is also applicable as a program or a method. In addition, the above systems, programs, and methods may be realized as a single device or may be realized by using parts shared with each part provided in the vehicle, including various aspects. It is a program. In addition, some of them are software and some of them are hardware, which can be changed as appropriate. Further, the invention is also established as a recording medium for a program that controls a system. Of course, the recording medium of the program may be a magnetic recording medium or a semiconductor memory, and any recording medium to be developed in the future can be considered in exactly the same way.

10 ... Navigation system, 20 ... Control unit, 21 ... Current location acquisition program, 21a ... Communication control unit, 21b ... Road attribute estimation unit, 21c ... Current location identification unit, 21d ... Output control unit, 30 ... Recording medium, 30a ... Map information , 41 ... GNSS receiver, 42 ... vehicle speed sensor, 43 ... gyro sensor, 44 ... communication unit, 45 ... user I / F unit

Claims (6)

A communication control unit that communicates with the roadside unit,
The road attribute estimation unit that estimates the road attributes of the road on which the vehicle is located,
The estimated position of the vehicle is acquired, the candidate position which is a candidate of the current location of the vehicle on the road indicated by the map information is acquired based on the road attribute and the estimated position, and the current location of the vehicle is obtained from the candidate position. With a current location identification department to identify
The current location identification part is
When communication with the roadside machine is performed, the current location of the vehicle is specified without referring to the road attribute.
Current location acquisition system. The current location is
When the candidate position where the distance to the tollhouse on the toll road is equal to or less than the threshold value exists, it is specified based on the position of the tollhouse.
The current location acquisition system according to claim 1. The identification of the current location based on the location of the tollhouse is
Not implemented if there is no toll road within the defined range from the estimated position,
The current location acquisition system according to claim 2. On the toll road where the tollhouse is located,
Includes access roads for movement between general roads and toll road mains,
The current location acquisition system according to claim 2 or 3. The current location is
It is specified on the road where the traveling direction of the vehicle indicated by the locus of the estimated position and the traveling direction on the road match.
The current location acquisition system according to any one of claims 1 to 4. Computer,
Communication control unit that communicates with the roadside unit,
Road attribute estimation unit that estimates the road attributes of the road on which the vehicle exists,
The estimated position of the vehicle is acquired, the candidate position which is a candidate of the current location of the vehicle on the road indicated by the map information is acquired based on the road attribute and the estimated position, and the current location of the vehicle is obtained from the candidate position. It is a current location acquisition program that functions as a current location identification department that identifies
The current location identification part is
When communication with the roadside machine is performed, the current location of the vehicle is specified without referring to the road attribute.
A current location acquisition program that makes your computer work.

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