JP6680319B2 - Map information generation system, method and program - Google Patents

Description

  The present invention relates to a map information generation system, method and program for generating information on a new road.

  Conventionally, there is known a technique of generating information on a new road that does not exist in the map information based on the traveling history of the vehicle. For example, in Patent Document 1, the position of the vehicle is collated with the geographic database, the division position of the previously collated link is determined from the position when the first collation is not performed, and the division point is used as an end point. A structure for creating a link is disclosed. Further, in Patent Document 2, the start point and the end point of the state where the position on the road cannot be estimated match the point immediately before the state where the position on the road cannot be estimated and the point immediately after the state where the position on the road can be estimated. A configuration is disclosed in which a locus in a state where the position on the road cannot be estimated is translated, rotated, or enlarged.

Japanese Patent No. 4559551 JP, 2009-192480, A

  In the above-mentioned conventional technique, the position of the new road may be incorrect. That is, in the technique disclosed in Patent Document 1, the division position of the previously collated link is determined from the position when the first collation is not performed, but the position when the first collation is not performed is accurate. Not necessarily. Therefore, the position of the new road may be inaccurate if the division position of the link is determined based on the position when the first matching is not performed.

In the technique disclosed in Patent Document 2, the start point and the end point of the state where the position on the road cannot be estimated match with the point immediately before the position on the road cannot be estimated and the point immediately after the position can be estimated. Although the locus is corrected as described above, the point immediately before the position on the road cannot be estimated and the point immediately after the position can be estimated are not always accurate. Therefore, the location of the new road may be inaccurate. In addition, in the map matching process in which the detected position is estimated to be a position on the road, the detected position is forcibly converted into a position on the road, and thus the position on the road is estimated. However, the position may differ from the accurate position of the vehicle.
The present invention has been made in view of the above problems, and an object thereof is to provide a technique for improving the accuracy of the position of a new road.

  In order to achieve the above object, the map information generation system includes a movement locus acquisition unit that obtains a movement locus of a moving body, a movement locus correction unit that corrects the position of the movement locus so that the movement locus approaches an existing road, A new road acquisition unit that acquires a section whose corrected movement locus does not correspond to an existing road as a new road, and a new road addition unit that adds information indicating the new road to the map information are provided.

  In order to achieve the above-mentioned object, the map information generation method includes a movement locus acquisition step of obtaining a movement locus of a moving body, and a movement locus correction step of correcting the position of the movement locus so that the movement locus approaches an existing road. And a new road acquisition step of acquiring a section whose corrected movement locus does not correspond to an existing road as a new road, and a new road addition step of adding information indicating the new road to the map information. .

  Further, in order to achieve the above-mentioned object, the map information generation program has a movement locus acquisition function for obtaining the movement locus of the moving body and a movement locus correction function for correcting the position of the movement locus so that the movement locus approaches the existing road. Then, the computer is made to realize a new road acquisition function of acquiring as a new road a section whose corrected movement locus does not correspond to an existing road, and a new road addition function of adding information indicating the new road to the map information.

  As described above, the map information generation system, method, and program acquire a section that does not correspond to an existing road as a new road after correcting the moving path so that the moving path approaches the existing road. In the current technology (technology using GPS, gyro, etc.) for specifying the position of the moving body, the position may be inaccurate due to various factors such as radio interference and error accumulation. Therefore, when focusing on the position of the moving body specified at a certain moment, the position may be inaccurate, and if the connection position between the new road and the existing road is specified based on the position, the position of the new road is determined. Becomes inaccurate.

  As described above, each of the positions of the moving body forming the moving trajectory of the moving body may be inaccurate, but on the other hand, in the state where the moving trajectory is composed of a plurality of positions of the moving body, Focusing on the shape of the trajectory, the shape rarely differs greatly from the trajectory of the actual position. For example, in the GPS technology, the position may randomly change due to multipath or noise, but if the focus is on the movement trajectory that is a set of a plurality of positions, the error is leveled and the shape of the movement trajectory is the trajectory of the actual position. It is not much different from. Therefore, in the map information generation system, method, and program, rather than specifying the connection position between the new road and the existing road on the basis of the specific position of the moving body, the movement locus is corrected so as to approach the existing road. Later, a section whose movement locus does not correspond to the existing road is specified as a new road. Therefore, the accuracy of the position of the new road can be improved.

It is a block diagram which shows a map information generation system. It is a flow chart which shows map information generation processing. It is a figure which shows the example of a road and a movement locus. (4A) is a diagram showing movement by a movement vector, and (4B) to (4E) are diagrams showing an example of acquiring the position of a new road.

Here, embodiments of the present invention will be described in the following order.
(1) Configuration of map information generation system:
(2) Map information generation process:
(3) Other embodiments:

(1) Configuration of map information generation system:
FIG. 1 is a block diagram showing the configuration of a map information generation system 10 according to the present invention. The map information generation 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 or the ROM. In this embodiment, the navigation program and the map information generation program 21 can be executed as this program. The navigation program has a function of performing map matching processing based on self-contained navigation information to identify the position of a vehicle (moving body) on the road and displaying the current location of the vehicle on a map.

  The map information 30a is recorded in advance on the recording medium 30. The map information 30a is information used to identify the current location of the vehicle, and includes node data indicating the position of nodes set on the road on which the vehicle travels, and a shape for identifying the shape of the road between the nodes. It includes interpolation point data, link data indicating the connection between nodes, feature data indicating the position and type of features existing on the road and its surroundings, and the like.

  The vehicle on which the map information generation system 10 according to the present embodiment is installed includes a user I / F unit 40, a vehicle speed sensor 41, a gyro sensor 42, and a GPS receiving unit 43. The user I / F unit 40 is an interface unit for inputting a user's instruction and providing various kinds of information to the user, and includes a display unit also including an input unit including a touch panel display (not shown), a speaker, and the like. It is equipped with an output unit for output sound. The GPS receiver 43 receives radio waves from GPS satellites and outputs a signal for calculating the current position of the vehicle to the controller 20 via an interface (not shown). The vehicle speed sensor 41 outputs a signal corresponding to the rotation speed of the wheels of the vehicle to the control unit 20. The gyro sensor 42 outputs a signal corresponding to the angular acceleration acting on the vehicle to the control unit 20.

  The control unit 20 determines the current position of the vehicle based on the self-contained navigation locus, which is the locus of the position estimated based on the signals output from the vehicle speed sensor 41 and the gyro sensor 42, and the map information 30a by the processing of the navigation program. A plurality of possible comparison target roads are set, and the comparison target roads are narrowed down based on the error circle of the GPS signal acquired by the GPS receiving unit 43. Then, the control unit 20 refers to the map information 30a, and performs map matching to estimate a road having the shape that best matches the self-contained navigation locus among the narrowed-down comparison roads as a traveling road that is a road on which the vehicle is traveling. A process is performed and the present location of the vehicle is estimated on the traveling road estimated by the map matching process.

  Normally, the current position of the vehicle is estimated in such a map matching state, but when the vehicle travels on a new road that is a road that is not defined in the map information 30a, the vehicle is not in map matching state. . The control unit 20 can recognize a state where map matching is not performed and a state where map matching is performed. In the state where map matching is not performed, the control unit 20 determines the current location without performing map matching. presume. In the present embodiment, the control unit 20 estimates the position estimated based on the GPS signal as the current position in the state where map matching is not performed. Of course, here, the control unit 20 may estimate the position estimated based on the signals output from the vehicle speed sensor 41 and the gyro sensor 42 as the current position.

  The control unit 20 acquires a movement locus indicating the transition of the present position that can be specified without depending on the success or failure of the map matching in both the state where the map matching is performed and the state where the map matching is not performed. In the present embodiment, the control unit 20 regards the current position estimated based on the GPS signal as the identifiable current position without depending on the success or failure of the map matching. Then, in the state where the map matching is being performed, the control unit 20 associates the information indicating that the current position is estimated based on the GPS signal with the map matching, with the recording medium as the movement track information 30b. Record at 30. Further, in the state where the map matching is not performed, the control unit 20 associates information indicating that the current location estimated based on the GPS signal is the state where the map matching is not performed, and the movement history information 30b is stored in the recording medium 30. Record.

  The map information generation program 21 is a program module that causes the control unit 20 to realize a function of adding information indicating a new road to the map information 30a based on a movement trajectory in a state where map matching is not performed. In order to realize this function, the map information generation program 21 includes a movement locus acquisition unit 21a, a movement locus correction unit 21b, and a new road acquisition unit 21c.

  The movement track acquisition unit 21a is a program module that causes the control unit 20 to realize the function of acquiring the movement track of the moving body. That is, the control unit 20 acquires the movement locus as a target to be compared with the existing road in order to acquire the new road. The control unit 20 acquires the movement locus so as to include the movement locus on the new road, and in order to obtain the movement locus, the point where the map matching is changed to the map non-matching state and the map is changed from the non-map matching state. A movement locus in a section between the point changed to the matching state and a section of a predetermined distance before and after the section is acquired.

  Specifically, the control unit 20 acquires a moving locus when the vehicle has moved to an existing road, a new road, or an existing road. That is, the control unit 20 changes the state of the moving body in the case where the map-matching first state is changed to the map-unmatched second state and the map-matching third state is changed after the second state. Get the movement track. In the present embodiment, the first distance, which is the length of the first state, and the third distance, which is the length of the third state, are determined in advance, and the control unit 20 refers to the movement trajectory information 30b and maps the map. A first state and a third state in which information indicating a state in which map matching is performed is associated before and after a movement locus in the second state in which information indicating a state in which matching is not performed is associated. When the movement locus of the first state is the first distance and the movement locus of the third state is the third distance, the movement locus of the first state to the third state is changed. get. In addition, in the present embodiment, the length of the third distance that defines the movement trajectory in the third state is predetermined to be shorter than the first distance that defines the movement trajectory in the first state.

  The movement locus correction unit 21b is a program module that causes the control unit 20 to realize a function of correcting the position of the movement locus so that the movement locus approaches the existing road. In the present embodiment, the control unit 20 controls the movement locus acquired by the processing of the movement locus acquisition unit 21a (a movement locus in which the movement locus in the first state, the movement locus in the second state, and the movement locus in the third state are continuous. The movement locus is corrected on the basis of the movement locus in the map matching state in (). At this time, the control unit 20 corrects not only the specific position on the movement locus in the map matching state but also the entire movement locus in the map matching state so as to approach the existing road.

  In the present embodiment, the control unit 20 moves along the movement locus while maintaining the shape of the movement locus. Therefore, in the present embodiment, the control unit 20 linearly moves the movement locus within a two-dimensional plane formed by an orthogonal two-dimensional coordinate system that defines the movement locus (for example, a coordinate system having latitude and longitude as axes). A moving vector is adopted, and a moving vector that defines a moving amount and a moving direction for the moving is specified. At this time, the control unit 20 identifies a movement vector that indicates a movement that allows the movement locus to be associated with the existing road for the longest time, and performs a correction to move the position of the movement locus with the movement vector.

  The new road acquisition unit 21c is a program module that causes the control unit 20 to realize a function of acquiring, as a new road, a section in which the corrected movement locus does not correspond to the existing road. That is, the control unit 20 considers that the moving body is moving on the existing road in the section in which the corrected moving path and the existing road correspond, and the moving body in the section in which the corrected moving path and the existing road do not correspond. Is considered to be moving on a new road. Then, the control unit 20 regards the movement locus and the new road as substantially coincident with each other in the section where the corrected movement locus and the existing road do not correspond to each other, and specifies the position of the new road based on the information indicating the section. . Details of the process of acquiring a new road will be described later. The new road adding unit 21d is a program module that causes the control unit 20 to realize a function of adding information indicating a new road to the map information 30a. That is, the control unit 20 generates the node data indicating the end points of the new road and the link data indicating the new road acquired by the processing of the new road acquisition unit 21c, and adds the generated data to the map information 30a. When the end point of the new road coincides with the existing intersection, the control unit 20 defines the link data so that the new road extends from the existing intersection. Further, when the intersection, which is the end point of the new road, exists on the existing road, the control unit 20 corrects the node data and the link data so that the existing road is divided at the intersection. As a result, by referring to the map information 30a to which the information indicating the new road is added, it becomes possible to execute a process using the road network including the new road, for example, a route search process or a route guidance process. .

  In the present embodiment, the output signal of the GPS receiver 43 and the output signals of the vehicle speed sensor 41 and the gyro sensor 42 are used to identify the current position of the vehicle. The position may be inaccurate due to various factors such as accumulated error. Therefore, when focusing on the current location of the vehicle identified at a certain moment, the current location of the vehicle may be inaccurate, and if the connection position between the new road and the existing road is identified based on the current location of the vehicle, the new road is The position of will be incorrect.

  As described above, the current position of the vehicle at a certain moment, which constitutes the movement locus, may be inaccurate. On the other hand, in the state where the movement locus is formed by the transition of the current position of the vehicle, the shape of the movement locus is Focusing on, the shape rarely differs greatly from the actual position trajectory. For example, in the GPS technology, the position may randomly change due to multipath or noise, but if the focus is on the movement trajectory that is a set of a plurality of positions, the error is leveled and the shape of the movement trajectory is the trajectory of the actual position. It is not much different from. Then, in the present embodiment, the control unit 20 does not specify the connection position between the new road and the existing road based on the current position of the vehicle at a certain moment, but the movement locus in the map matching state approaches the existing road. The new road is specified after the correction. Therefore, the accuracy of the position of the new road can be improved.

  Further, in the present embodiment, the control unit 20 performs the processing of the movement locus acquisition unit 21a to determine that the movement locus before the map matching state is changed to the non-map matching state is not the map matching state. The movement locus can be acquired and the analysis can be started so as to be longer than the movement locus after changing to the state of map matching. Therefore, compare with the case where the movement trajectory before changing from the map matching state to the map matching state is less than the movement trajectory after changing from the non-map matching state to the map matching state. Then, it becomes possible to start the analysis of the movement trajectory at an early stage.

  Further, as in Patent Document 1, the position of the vehicle is collated with the geographic database, the division position of the previously collated link is determined from the position when the first collation is not performed, and the divided point is used as the end point. In the configuration for creating a new link, there is a parallel road close to the existing road, and if the collation is wrong, the new road may be connected to the wrong road. However, as in the present embodiment, a movement locus including a locus before and after a point where the state where map matching is changed and the state where map matching is not performed is acquired, and the shape of the movement locus is partially approximate to the shape of the existing road. According to the configuration in which the movement locus is corrected to a position where the two coincide with each other, the front and rear portions of the movement locus, which may have traveled on the existing road, are associated with the existing road having a similar shape. A new road can be specified. Therefore, the position of the new road can be accurately specified.

(2) Map information generation process:
Next, the map information generation processing by the map information generation program 21 will be described. When the navigation program is executed, the control unit 20 executes map information generation processing by the map information generation program 21. In the map information generation process, the control unit 20 acquires the current location by the process of the navigation program (step S100). That is, the control unit 20 acquires the current position of the vehicle based on the output signals of the vehicle speed sensor 41 and the gyro sensor 42. Next, the control unit 20 determines whether or not the current location matches the existing road (step S105). That is, the control unit 20 determines the self-contained navigation locus and the map information 30a based on the self-contained navigation locus that is the locus of the current location acquired in step S100, the error circle indicated by the output signal of the GPS reception unit 43, and the map information 30a. It is determined whether or not the map matching with the indicated road is being performed.

  When it is determined in step S105 that the current location matches the existing road, the control unit 20 records the movement track information 30b indicating that map matching is being performed (step S110). That is, the control unit 20 associates information indicating that map matching is in progress with the current location indicated by the output signal of the GPS receiving unit 43, and records the movement locus information 30b on the recording medium. When it is not determined in step S105 that the current location matches the new road, the control unit 20 records the movement track information 30b indicating that the map matching is not performed (step S115). That is, the control unit 20 associates the current location indicated by the output signal of the GPS receiving unit 43 with the information indicating that the map matching is not performed, and records the movement locus information 30b on the recording medium.

  Next, the control unit 20 determines whether or not the analysis start condition is satisfied by the processing of the movement locus acquisition unit 21a (step S120). That is, the control unit 20 refers to the movement trajectory information 30b, and the movement route before the current location acquired in step S100 becomes the second state in which the map matching is not performed after the first state in which the map matching is performed. After the state, the movement trajectory is in the case of the map matching third state, the length of the movement trajectory of the first state is the first distance, and the length of the movement trajectory of the third state is the first distance. When the distance is three, it is considered that the analysis condition is satisfied.

  When it is not determined in step S120 that the analysis start condition is satisfied, the control unit 20 repeats the processing from step S100. On the other hand, when it is determined in step S120 that the analysis start condition is satisfied, the control unit 20 acquires the analysis target movement trajectory by the processing of the movement trajectory acquisition unit 21a (step S125). That is, the control unit 20 refers to the movement locus information 30b, obtains the movement locus in the state of map matching before the current location, going back to the past from the current location for the third distance, and further tracing the map back to the past. A movement locus in a state in which the map matching is not performed is acquired, and a movement locus in a state in which map matching is performed retroactively is acquired for the first distance.

FIG. 3 is a diagram showing the existing road by a thin solid line, and a part of the movement trajectory of the vehicle existing at the position Pc is shown by a thick line. In this example, the locus of movement includes a locus in the state of map matching and a locus in the state of non-map matching. That is, the point indicated by the dashed arrow I is the point that has changed from the map matching state to the non-map matching state, and the point indicated by the dashed arrow O is the map matching state from the non-map matching state. It is the point that changed to the state. Therefore, the movement trajectories O ₁ and O ₃ indicate movement trajectories in the state of map matching, and the movement locus O ₂ indicates movement trajectories in the state of not performing map matching. In the figure 3, the length first distance movement trajectory O _1, that the length of the moving locus O ₃ is the third distance is assumed. Therefore, the movement loci O ₁ , O ₂ , and O ₃ shown in FIG. 3 are examples of the movement loci acquired in step S125.

  Next, the control unit 20 identifies the movement vector indicating the movement that allows the movement locus to be associated with the existing road for the longest time by the processing of the movement locus correction unit 21b (step S130). The movement vector can be specified by various methods. For example, the control unit 20 allows a plurality of points (points at constant distances, etc.) set on the movement track to reach a plurality of points set on the existing road (intersections with perpendicular lines extended from the movement track, etc.). Identify multiple vectors to move. Further, the control unit 20 specifies one of the plurality of vectors or a statistically determined vector as the trial vector, moves the movement trajectory by the trial vector, and then determines the movement trajectory after the movement and the existing movement trajectory. Calculate the distance that the road matches. For the distance, for example, a section that is close enough to be considered to correspond to the movement trajectory and the existing road is extracted from the movement trajectory, and the total distance of the extracted sections is the movement trajectory after the movement and the existing road. May be considered to be a matching distance.

  When specifying a trial vector, it may be specified by defining a composite vector of a plurality of vectors, or may be specified by a median value or an average value of the components of the plurality of vectors. Of course, various weights (such as a vector with a shorter distance having a larger weighting coefficient) may be applied when specifying the composite vector. Further, a vector having an excessively large size may not be regarded as a trial vector.

  The above processing is executed for a plurality of trial vectors, and the trial vector is repeatedly identified and moved until the distance at which the movement trajectory after movement and the existing road match is maximized. For example, it is possible to generate a state in which the movement path and the existing road are associated with each other for the longest time. Therefore, if the control unit 20 compares the positions of the movement locus after the movement and the movement locus before the movement after the distance at which the movement locus after the movement and the existing road match is maximized, the movement locus on the existing road is obtained. It is possible to specify the movement vector indicating the movement that can be associated with the longest.

  As described above, when the movement vector indicating the movement that allows the movement locus to be associated with the existing road for the longest time is specified, the control unit 20 causes the movement locus correction unit 21b to perform the movement using the movement vector. The position of the locus is moved (step S135). That is, the control unit 20 corrects the position of the movement locus by moving the respective positions of the movement locus acquired in step S125 in parallel according to the movement vector. As a result, the position of the movement locus is moved while maintaining the shape of the movement locus acquired in step S125. FIG. 4A is a diagram showing an example in which the movement locus is moved according to the movement vector in the example shown in FIG. 3.

  In this state, the control unit 20 disconnects the section whose corrected movement trajectory does not correspond to the existing road from the corrected movement trajectory, moves the disconnected section to connect to the existing road, and moves the section. A process is performed in which the subsequent position is regarded as the position of the new road. Specifically, the control unit 20 sets the trajectory sample points and the road sample points by the processing of the new road acquisition unit 21c (step S140). That is, the control unit 20 sets locus sample points that are virtual points at predetermined intervals on the movement locus corrected in step S135, and sets road sample points that are virtual points at predetermined intervals on the existing road. Set. The predetermined interval, which is the interval between the trajectory sample points and the interval between the road sample points, may be determined in advance and depends on the accuracy required as the accuracy of identifying the position of the new road, the analysis resource, and the like. It has only to be decided.

  4B and 4C are enlarged views of region A in the example shown in FIG. 4A, and FIGS. 4D and 4E are enlarged views of region B in the example shown in FIG. 4A. In these FIGS. 4B to 4D, the existing road is shown by a solid line and the movement locus is shown by a broken line. New roads are not shown. The locus sample points are shown as white circles, and the road sample points are shown as white rectangles.

  Next, the control unit 20 generates a pair in which the locus sample points and the road sample points are associated with each other by the processing of the new road acquisition unit 21c (step S145). That is, the control unit 20 associates the locus sample points with the shortest distance with the road sample points, and pairs one locus sample point with one road sample point. Then, the control unit 20 records the information in which the pair identifiers are associated with each pair and the identifiers are associated with the trajectory sample points and the road sample points in the RAM. If the closest road sample point seen from the locus sample points and the closest locus sample point seen from the road sample points are different, these sample points do not form a pair. As a result, the road sample points on the existing road on which the vehicle travels form a pair with the surrounding track sample points, but the track sample points set for the movement track on the new road are not associated with the road sample points. It becomes a state.

  FIG. 4B and FIG. 4D are enlarged views before cutting and moving the moving locus, which will be described later. In these drawings, the paired locus sample points and road sample points are connected by a thick solid line. It shows with. Thick solid lines are not connected to the trajectory sample points to which the road sample points are not associated. In this way, when there is no road sample point corresponding to the trajectory sample point, the section on the movement trajectory constituted by the trajectory sample point is estimated to be a new road.

  Therefore, in the present embodiment, the control unit 20 performs a process for acquiring a new road based on a movement locus composed of locus sample points to which road sample points are not associated, but before acquiring the new road. In addition, correction is performed to accurately identify the new road. Specifically, the control unit 20 determines by the process of the new road acquisition unit 21c whether or not there is a section whose distance is equal to or less than the threshold value in which a pair is not generated (step S150). That is, the control unit 20 specifies a locus sample point for which a pair is not generated on the movement locus, and specifies a section when a locus sample point for which a pair is not generated continuously exists. Then, the control unit 20 determines the distance of the section and compares it with the threshold value to determine whether or not there is a section having a distance equal to or less than the threshold value in which a pair is not generated.

  When it is determined in step S150 that there is a section with a distance equal to or less than the threshold value in which a pair is not generated, the control unit 20 causes the new road acquisition unit 21c to process the corresponding section into a section in which a pair is generated. They are integrated (step S155). That is, a section with a distance equal to or less than the threshold value, in which a pair is not generated, occurs at an intersection or the like in which the movement trajectory of the vehicle is a curve and the existing road is a straight line. However, since such a section is a section on the existing road, the control unit 20 concludes that the section is a new road by integrating the section into a section in which a pair is generated in step S155. Correct it so that it is not done. In addition, in step S150, when it is not determined that a pair is not generated and a section having a distance equal to or less than the threshold value is present, the control unit 20 skips step S155.

  Further, the control unit 20 determines by the process of the new road acquisition unit 21c whether or not there is a section in which a pair is generated and the distance is equal to or less than the threshold value (step S160). That is, the control unit 20 specifies the locus sample points for which pairs are generated on the movement locus, and if the locus sample points for which pairs have been generated continuously exist, specifies that section. Then, the control unit 20 determines whether or not there is a section with a distance equal to or less than the threshold value in which a pair is generated, by specifying the distance in the section and comparing the distance with the threshold value.

  When it is determined in step S160 that there is a section in which a pair is generated and the distance is less than or equal to the threshold value, the control unit 20 performs the processing of the new road acquisition unit 21c, and the corresponding section is a section in which no pair is generated. (Step S165). That is, the section having a distance equal to or less than the threshold value in which the pair is generated occurs when a new road extending in a direction similar to the existing road is newly installed near the existing road. However, since such a section is not a section on the existing road, the control unit 20 integrates the section into a section in which a pair is not generated in step S165, thereby determining that the section is an existing road. Correct so that it is not estimated. In addition, in step S160, when it is not determined that there is a section in which a pair is generated and the distance is equal to or less than the threshold value, the control unit 20 skips step S165.

  Next, the control unit 20 acquires a section for which a pair has not been generated as a new road section by the processing of the new road acquisition section 21c (step S170). For example, the control unit 20 acquires the movement locus of the section Zn shown in FIG. 4B and the section Zn shown in FIG. 4D as a new road section. As described above, in the present embodiment, it is possible to easily acquire a new road section based on the correspondence between the locus sample points and the road sample points.

  Further, in the state where the new road section is acquired as described above, the new road and the existing road may be discontinuous, so the control unit 20 generates a pair by the processing of the new road acquisition unit 21c. The new road section is connected to the end point of the section and the connected new road is recorded in the map information 30a by the process of the new road adding unit 21d (step S175). In the present embodiment, the control unit 20 moves so as to connect the section on the movement locus including the locus sample points to which the road sample points are not associated with the closest road sample point.

For example, in the example shown in FIGS. 4B and 4D, the section on the movement locus in which the locus sample points to which the road sample points are not associated exists is the newest road side in the pair of locus sample points and road sample points. It is a section Zn on the moving locus existing on the new road side from the locus sample points S _O in the pair located at. Then, the control unit 20 cuts out the section Zn from the movement locus and moves it so as to connect to the nearest road sample point S _R. Incidentally, because this direction of movement of the ends of the sections Zn in a mobile (S _O shown in S _O and 4C shown in FIG. 4B) is generally different, the control unit 20 may correct the shape of the movement trajectory. The correction can be realized by, for example, isotropic affine transformation. 4C is a diagram showing a state after moving the section Zn shown in FIG. 4B, and FIG. 4E is a diagram showing a state after moving the section Zn shown in FIG. 4D. As described above, when a section on a movement locus in which a locus sample point to which a road sample point is not associated exists is moved so as to be connected to the closest road sample point, the position after movement is changed to a new road. Can be regarded as the position of. Then, the control unit 20 can accurately define the position of the new road by recording the position after the movement as the position of the new road in the map information 30a.

(3) Other embodiments:
The above embodiment is an example for carrying out the present invention, and as long as the section corresponding to the corrected movement trajectory is acquired as a new road after the position of the movement trajectory is corrected so that the movement trajectory approaches the existing road. In addition, various other embodiments can be adopted. For example, the map information generation system may be fixedly mounted in the vehicle, or a portable terminal may be brought into the vehicle for use. Further, the map information generation system may be configured by a server or the like that generates map information based on probe information acquired from a vehicle or the like. Of course, in this case, the information indicating the new road added to the map information by the server or the like is distributed to the navigation terminal used in the vehicle, and the map information on the recording medium of the terminal also indicates the new road. May be added. Furthermore, at least a part of the movement locus acquisition unit 21a, the movement locus correction unit 21b, and the new road acquisition unit 21c may be realized by a control entity different from the above-described embodiment. For example, the movement trajectory acquisition unit 21a may be realized by a control ECU or the like for identifying the current location. Furthermore, the moving body is not limited to a vehicle, and may be a pedestrian or the like.

  The movement locus acquisition unit may be able to acquire the movement locus of the moving body. Further, the movement locus may be a locus when the moving body moves from a certain point to another point, and may be the whole locus during traveling, or a part of the locus. The movement trajectory may be a set of a plurality of positions estimated as the position of the moving body, but the movement trajectory on the existing road needs to be included for comparison with the existing road. In order to be acquired, it is preferable that the movement locus on the new road is included. Further, in the above-described embodiment, the movement locus is the locus of the current position acquired based on the output signal of the GPS receiving unit 43, but it may be any locus of the moving body after the map matching, and of course, the self-contained navigation locus. May be

  The movement locus correction means only needs to be able to correct the position of the movement locus so that the movement locus approaches the existing road. That is, it suffices to focus on the entire movement locus acquired by the movement locus acquisition means and perform correction so that not only a specific position on the movement locus but also the entire movement locus approaches the existing road. To this end, for example, the movement locus is moved while maintaining the shape of the movement locus (rotational movement may be included) so that the difference between the movement locus after movement and the existing road is minimized. It is also possible to adopt a configuration in which it is moved to.

  It should be noted that there may be a plurality of movement methods capable of correcting the movement locus so as to approach the existing road, but various methods can be adopted as a method for limiting the movement method from a plurality to one. For example, as described above, the movement locus may be moved so that the difference between the movement locus after movement and the existing road is minimized, or the movement locus may be moved in consideration of various evaluation conditions. . Various conditions can be assumed as the evaluation condition. For example, a configuration is adopted in which the movement method is evaluated so that the movement method is more easily adopted as the movement amount and the rotation angle in the rotational movement in the plural movement methods are smaller. It is possible.

  The new road acquisition means only needs to be able to acquire, as a new road, a section whose corrected movement locus does not correspond to the existing road. That is, it is considered that the moving body is moving on the existing road in the section where the corrected moving path and the existing road correspond, and the moving body is moving on the new road in the section where the corrected moving path and the existing road do not correspond. Considered to have moved. Then, in a section in which the corrected movement locus and the existing road do not correspond to each other, the movement locus may be regarded as indicating the shape of the new road, and the section may be set as the new road.

  Whether or not the corrected movement locus corresponds to the existing road may be determined at least so that it can be considered that the movement locus cannot be a locus on the existing road. It is not considered that only the state where the coordinates of the corrected moving locus and the coordinates of the existing road completely match is considered to correspond. Therefore, for example, it is considered that the existing road that can be the corrected moving locus (which does not cause a contradiction) exists near the corrected moving locus, and the existing road that can be the corrected moving locus is It is possible to adopt a configuration or the like in which it is considered not to correspond when it does not exist near the corrected movement locus.

  In any case, as a result of associating the existing road with the corrected travel path, if there is a section that cannot be associated with the existing road in the corrected travel path, the section is acquired as a new road. I wish I could. As a configuration example for this, for example, the new road acquisition means sets trajectory sample points which are virtual points on the corrected movement trajectory at predetermined intervals, and sets virtual points on the existing road at predetermined intervals. When a road sample point is set, and the locus sample point with the shortest distance is associated with the road sample point, based on the section on the moving locus where there is a locus sample point that is not associated with the road sample point. It is possible to adopt a configuration in which a new road is acquired by using

  That is, in order to associate the existing road with the corrected movement locus, the new road acquisition means sets a locus sample point on the corrected movement locus and a road sample point on the existing road. . In this way, when the trajectory sample point and the road sample point are set, it is possible to easily define the correspondence relationship by pairing the sample points having the closest distances from each other. When the corresponding relationship is defined, the road sample points cannot be associated with the locus sample points existing on the moving locus when traveling on a new road. Therefore, it is possible to acquire a new road based on the section on the movement locus in which the locus sample points to which the road sample points are not associated exist. With this configuration, it is possible to easily acquire a new road.

  The locus sampling points and the road sampling points may be set at a predetermined interval. That is, by matching the number of locus sample points per unit distance with the number of road sample points per road unit point per unit distance, the number of sample points in the section where the movement locus and the existing road match It suffices that the locus and the existing road are set to be the same. According to this configuration, only the correspondence between the trajectory sample points and the road sample points is defined, and the sections in which the corrected trajectory and the existing road correspond and the sections that do not correspond are clarified. You can

  Further, the new road acquisition means moves the section on the movement locus including the locus sample points to which the road sample points are not associated so as to connect to the closest road sample point, and The position may be regarded as the position of the new road. In other words, there may be a slight positional deviation between the corrected movement trajectory and the existing road, but the end points of the existing road and the new road in the actual road network must be different. There should be no. Therefore, by moving so that the section on the movement locus in which the locus sample points to which the road sample points are not associated exist is connected to the closest road sample point, the position after movement becomes the position of the new road. I can see it. As a result, the position of the new road can be accurately defined.

  Furthermore, as a configuration example for moving the movement locus so that the difference between the movement locus after movement and the existing road is minimized, the movement locus correction means can associate the movement locus with the existing road for the longest time. The correction may be performed to move the position of the movement locus with a movement vector indicating movement. That is, assuming that correction is performed to move the movement locus according to the movement vector defined by the combination of the movement amount and the movement direction, the degree to which the movement locus after movement corresponds to the existing road is evaluated for each movement vector. be able to. Therefore, if a movement vector that can associate the movement trajectory after movement with the existing road for the longest time is selected, it is possible to move the movement trajectory so that the difference between the movement trajectory after movement and the existing road is minimized. The movement vector can be easily specified.

  Further, the section between the point where the movement locus acquisition means has changed from the map matching state to the non-map matching state and the point changing from the non-map matching state to the map matching state. , And a movement locus in a section of a predetermined distance before and after the section may be acquired. That is, in order to perform the correction for moving the movement locus, when the movement locus in the state of map matching, the movement locus in the state of non-map matching, and the movement locus in the state of map matching are continuous. The configuration is such that a movement locus including a locus of each state is acquired. According to this configuration, the movement trajectory when the existing road is changed to the new road, the movement trajectory when the new road is changed to the existing road, or the movement trajectory when the existing road, the new road, and the existing road are changed is analyzed. Can be

  Furthermore, the movement in the case where the movement locus acquisition means is in the second state in which the map matching is not performed after the first state in which the map matching is performed, and is changed to the third state in which the map matching is performed after the second state. The locus of the body may be acquired as the movement locus, and the movement locus of the third state may be set to be shorter than the movement locus of the first state. In such a situation, for example, in the case where the movement locus acquisition unit acquires the movement locus when transitioning to an existing road, a new road, or an existing road as an analysis target, on the existing road before the movement from the existing road to the new road. May be configured to be longer than the trajectory on the existing road after the transition from the new road to the existing road. According to this configuration, compared to the case where the movement trajectory on the existing road before the transition from the existing road to the new road is less than or equal to the movement trajectory on the existing road after the transition from the new road to the existing road. , It becomes possible to start the analysis early.

  Further, a configuration may be adopted in which the movement locus correction means estimates the lane in which the moving body has traveled on the existing road and corrects the position of the movement locus so that the movement locus approaches the lane. According to this configuration, it is possible to prevent the determination accuracy of whether or not the movement locus and the existing road correspond to each other due to the moving body moving in different lanes. It should be noted that various configurations can be adopted as the configuration for estimating the lane in which the mobile body travels on the existing road. For example, in the configuration shown in FIG. 1, the link data of the map information 30a is configured to include information for identifying a lane (for example, information indicating the number of lanes, the width of the lane, the lane boundary pattern, etc.). Further, if the control unit 20 collates the information indicating the paint on the road surface acquired by the sensor such as the camera mounted on the vehicle with the information for identifying the lane indicated by the map information 30a, the vehicle is traveling. The position of the lane can be specified. Therefore, if the control unit 20 considers that the position of the existing road is not the center of the road but the position of the lane concerned and corrects the movement locus so that the movement locus approaches the position of the lane in which the vehicle has traveled, the movement locus It becomes possible to accurately correct the position of.

  When the position of the new road is specified, the position of the new road may be adjusted according to the distance between the lane and the center position of the road. For example, since the corrected trajectory is moved so as to correspond to the lane position, if the center position of the road is defined as the road position in the map information, the position of the trajectory and the center position of the road are defined. There is a gap between and. Therefore, the position of the movement locus may be corrected so as to eliminate the deviation and set as the position of the new road.

  Further, as in the present invention, a method of correcting a position of a movement trajectory so that the movement trajectory approaches an existing road and then acquiring a section that does not correspond to the corrected movement trajectory as a new road is a program or a method. Is also applicable. Further, the system, program, and method as described above may be realized as a single device or may be realized by using components shared with each unit provided in the vehicle, and include various modes. It is a waste. For example, it is possible to provide a map information management system, a navigation system, a method, and a program including the above system. Further, it is possible to change as appropriate, such as a part being software and a part being hardware. Further, the invention can be realized as a recording medium of a program for controlling the device. Of course, the recording medium of the software may be a magnetic recording medium or a magneto-optical recording medium, and any recording medium developed in the future can be considered in exactly the same manner.

  10 ... Map information generation system, 20 ... Control part, 21 ... Map information generation program, 21a ... Movement locus acquisition part, 21b ... Movement locus correction part, 21c ... New road acquisition part, 30 ... Recording medium, 30a ... Map information, 30b ... movement locus information, 40 ... user I / F section, 41 ... vehicle speed sensor, 42 ... gyro sensor, 43 ... GPS receiving section

Claims (7)

The section between the point where the map matching changed to the state where the map matching did not occur and the point where the state changed to the state where the map matching did not match the map and the section before and after the section. trajectory of the moving body, a movement locus acquisition means for acquiring a moving track of the movable body in the front and rear of the the new road new road in,
Movement locus correction means for correcting the entire position of the movement locus so that the whole movement locus in the state of map matching approaches an existing road,
A new road acquisition means corrected the moving track to obtain a section that does not correspond to the existing road as the new road,
New road adding means for adding information indicating the new road to map information ,
The map information generating system comprising: a.   The movement trajectory acquisition means,
    The locus of the moving body when the map matching first state is followed by the map matching second state, and after the second state is the map matching third state is taken as the movement trajectory. Along with getting
    The movement locus in the third state is shorter than the movement locus in the first state,
The map information generation system according to claim 1.   The new road acquisition means,
    The section where the corrected movement locus does not correspond to the existing road is cut from the corrected movement locus, the cut section is moved so as to connect to the existing road, and the position after movement of the section is the Considered to be the location of a new road,
The map information generation system according to claim 1 or 2.   The new road acquisition means,
    Set trajectory sample points that are virtual points at predetermined intervals on the corrected trajectory, and set road sample points that are virtual points at the predetermined intervals on the existing road,
    When the locus sample points having the shortest distance are associated with the road sample points, the new road is based on the section on the movement locus where the locus sample points to which the road sample points are not associated exist. To get the
The map information generation system according to any one of claims 1 to 3.   The new road acquisition means,
    The end point of the section on the movement locus in which the locus sample point to which the road sample point is not associated exists is moved so as to be connected to the nearest road sample point, and the position after movement of the section is Consider the position of the new road,
The map information generation system according to claim 4.   A section between the point where the movement locus acquisition means changes from a state where map matching is performed to a state where map matching is not performed, and a point where a state where map movement is changed to a state where map matching is performed, and A movement locus acquisition step of acquiring a locus of the moving body in a section before and after the section as a movement locus of the moving body in a new road and before and after the new road;
  A movement locus correction step, in which the movement locus correction means corrects the entire position of the movement locus so that the whole movement locus in the map matching state approaches the existing road;
  A new road acquisition step in which the new road acquisition means acquires a section in which the corrected movement locus does not correspond to the existing road as the new road;
  A new road adding means, a new road adding step of adding information indicating the new road to the map information;
A method for generating map information, including:   Computer,
  The section between the point where the map matching changed to the state where the map matching did not occur and the point where the state changed to the state where the map matching did not match the map and the section before and after the section. A moving locus acquisition unit that acquires the moving body locus as a moving locus of the moving body on a new road and before and after the new road,
  A movement locus correction unit that corrects the entire position of the movement locus so that the whole movement locus in the state of map matching approaches an existing road,
  A new road acquisition unit that acquires a section in which the corrected movement locus does not correspond to the existing road as the new road,
  A new road adding unit that adds information indicating the new road to map information,
A map information generation program characterized by causing it to function as.

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