EP2245427A1 - Method for operating a navigation system - Google Patents

Abstract

The invention relates to a method for operating a navigation device, comprising an input device, on which operator commands and/or position inputs such as starting points and/or destinations can be inputted, a path network databank, wherein the route leads from starting point to destination, a signal reception unit for receiving positioning signals in particular satellite signals, a position determining unit, which determines the current position from the position signals, a display device (1), on which the planned route (3) can be graphically displayed, wherein a) on calculating the route, route data is selected from the path network databank and buffered, the route data describing the route path between the starting point and the destination, b) calculation of the graphical data of a schematic route representation (7, 9) for graphical display of the route (3) on the display device (1), the graphical data being calculated from the buffered route data and c) graphical display of the schematised graphical route representation (7, 9) on the display device (1).

Description

 January 21, 2009

Method for operating a navigation system

The invention relates to a method for operating a navigation system according to the preamble of claim 1.

Generic navigation systems are used, for example, as mobile or permanently installed navigation devices, in particular in motor vehicles, in order to guide the driver along a route from a starting point to a destination point. Via an input device, the user can enter operator commands and location information and thereby enter into communication with the navigation system. By receiving position signals, which are emitted in particular by positioning satellites, a signal receiving unit of the navigation system in cooperation with a position determining unit can determine the position of the navigation system.

Based on the data of a road network database, the planned route can also be determined by means of a route calculation unit and used as a basis for the route guidance process. The planned route can be displayed graphically to the user on a display device. The graphical route display should give the user a visual impression of the route through the geographical area.

BESTATIGUNGSKOPIE Also known generic systems send to a wirelessly reachable server a request for calculating a route from a start to a destination, preferably with the current position as a starting point and get not only the calculated route but also information to display the calculated route in the display unit of the system in different zoom levels. These systems are known as offboard routing.

In the case of known navigation systems, it is customary for the calculation of the graphical route representation to extract the geometric data of all road segments via which the route leads from the road network database and to store it preferably in a volatile main memory. This approach is very problematic, especially in the display of very long routes that lead, for example, across Europe, since the route in these cases includes a very large number of road segments and therefore a large number of geometric data from the road network database must be queried. In addition, this large number of geometry data must then be kept in the main memory, so that a correspondingly large main memory is necessary. The data processing of this large number of geometry data also slows down the calculation of the graphic data for the graphical route representation, so that correspondingly long waiting times can occur before the display. For off-board routing systems, the transmission of the appropriate amount of geometry data is disadvantageous for both cost and time reasons.

Based on this prior art, it is therefore an object of the present invention to propose a new method for operating a navigation system, with which the illustrated problems in the graphical representation of the route can be avoided.

The inventive method is based on the fundamental idea that, especially in the graphic representation of very long routes, the exact calculation of the geometric course of the route for a good understandable graphical route representation is not required. For very long routes, such a large number of road segments must be displayed simultaneously on the display device, so that it does not depend on the exact geometric course of a single road segment for the clear indication of the route. In order to avoid, however, that the graphically displayed route course deviates too much from the actual course of the route, it is proposed according to the invention to resort to the route data which are already stored in the volatile main memory in the calculation of the graphic data of a schematized graphical route representation. In the context of this invention, the route data preferably stored in the volatile main memory are selected as route data which were selected from the road network database during the route calculation and describe the route course between the starting point and the destination point.

If only these route data already selected during the route calculation process are used to calculate the graphic data of the schematized graphical route representation, then the amount of data which is to be buffered in the main memory is not substantially increased since the route data is already included in the route calculation in the

Memory has been cached. In addition, the computation time required for the calculation of the graphics data is considerably shortened because it is no longer necessary to access the data in the road network database, but only the route data stored in the main memory must be evaluated.

The method according to the invention offers particularly great advantages if the road map stored electronically in the road network database is divided into a plurality of subregions which are to be referred to below as tiles. The totality of all tiles complement each other without gaps to the corresponding geographical area. Each tile is separated in the database by a separate set of records. which contains all the necessary data for the description of the road network in the corresponding subarea. If such a tile-based road map is used in the navigation system, during the route calculation process, such data are also selected as route data from the road network database relating to the tiles over which the route travels. Such route data relating to the tiles may be identifiers that associate the associated tile with each route element. Preferably, this identifier is already part of the identifier of the route element itself. In a further advantageous embodiment, the identifier can already be mathematically deduced from the identifier by means of known methods such as quad code, at which geographical position the tile is located.

These tiles, which are touched or cut by the route, will hereafter be referred to as route tiles. From the tile data contained in the route data, support points can then be derived in a simple manner, which serve as the basis for the graphical representation of the schematized route representation. In the schematic graphic route representation, namely, the selected interpolation points are connected to one another by line segments, so that the graphically represented route is thus represented as a sequence of line segments between the various interpolation points.

With the method according to the invention, different types of schematized graphical route representations, each with a different degree of abstraction, can be calculated. For a first type of the schematized graphical route representation, which roughly maps the route representation, a support point is determined in each route tile by selecting a point in a specific, predetermined position of the route tile independently of the route. For example, the point in the middle of the route tile or the point located in a certain corner of the route tile, for example, the lower left corner of the route tile, can always be the base of the route tile Route tile are selected. In the graphical route representation, the route shown then consists of a sequence of line sections, each extending between the individual bases. Thus, the course of the graphical route representation is roughly schematized. On the one hand, it is ensured that the graphical route representation runs along all the tiles of the geographical area over which the calculated route passes. On the other hand, the graphical route representation of the actual route of the route through the individual tiles is completely independent, since the support points are selected regardless of the route in a specific, predetermined position of the route tile.

In order to ensure a display of the route representation which is characteristic for the course of the route, even at a lower resolution, at least two interpolation points are determined in each route tile in accordance with a second type of the schematized graphical route position. These vertices are the intersection points where the route intersects the tile boundaries. These intersections between route and tile boundaries must be calculated anyway during the route calculation process, so that the corresponding data are already present in the volatile main memory and can be easily selected. By selecting these intersection points, the course of the graphical route representation is further approximated to the actual course of the route, since the individual line segments of the graphical route representation each extend between two points, namely between the two intersections that actually lie on the route. The geometric course of the route between the intersection points is again disregarded in this type of schematized graphical route representation.

Since the schematized graphic route representation calculated according to the invention represents a considerable coarsening of the route course, the display of this coarsened route course does not always make sense. If, for example, a geographical area whose size corresponds to the size of one or a few tiles is displayed on the display device, a coarsening of the route profile is indicated by displaying straight line sections which run between the individual interpolation points in the middle or at the intersections of the tiles, certainly not useful. It is therefore particularly advantageous if the type of the schematized graphical route representation is changed depending on the predetermined graphical resolution of the route to be displayed. In particular, however, for displaying the route in the overview mode, the schematized graphical route representation can be used advantageously because in overview mode, the entire route is displayed contiguous and therefore regularly a correspondingly high resolution is necessary.

The type of the schematic graphical route representation can be determined in a particularly simple and rapid manner by determining the number of tiles to be displayed simultaneously on the display device or the number of route tiles to be displayed simultaneously on the display device. For the number of tiles or the number of route tiles for simultaneous display on the display device is characteristic of which coarsening in the graphical route representation can be used meaningful way. If, for example, a very large number of tiles or route tiles are displayed simultaneously on the display device, then it does not depend on the exact geometry of the road segments contained in the route, since this exact geometry is not due to the large number of tiles or route tiles to be displayed at the same time can be resolved.

Since the route data calculated during the route calculation process contain the starting point, the destination point and possibly also intermediate destination points in any case, these points should also be selected as interpolation points of the schematized graphical route representation become. Because these points are readily available and characterize the route exactly.

By the method according to the invention a coarsening of the graphical representation of the route is achieved, which, however, involves the danger that the coarsening is too great in the individual case. In order to be able to prevent too rough a route representation in an individual case, the distance between two adjacent pixels to be connected for the display of the route representation can be determined when displaying the route on a pixel-based pixel matrix. If the distance between two pixels to be connected for the route display exceeds a predetermined maximum, for example because there are five pixel spacing between two pixels to be connected for the route display, this can be defined as exceeding the maximum size of coarsening and thereby triggering the calculation of further auxiliary bases. The additional support points can be selected, for example, by selecting further geometry data from the road network database in the corresponding region of the map. The additional support points ensure that the coarsening of the graphical route representation does not exceed a certain maximum.

In order to limit the necessary effort in the calculation of additional support points, it is particularly advantageous that the addition of additional support points is aborted when the predetermined minimum distance between two adjacent additional support points falls below a predetermined minimum distance. For example, is the distance between two additional support points or the distance between a

Additional support point and an already existing support point smaller than a pixel, so the further addition of additional support points in this area no longer makes sense, since there is no way for the graphical route representation, the then additionally calculated additional support points graphically resolve. The method according to the invention can be carried out on any type of mobile or permanently installed navigation devices. The method according to the invention offers particularly great advantages when applied to navigation systems which comprise a stationarily installed server and a user terminal and are often referred to as "offboard navigation systems". The user terminal may in particular be a portable minicomputer or a mobile telephone. In these off-board navigation systems, the server and the user terminal are connected to one another via a data communication connection, for example an internet connection or a mobile radio connection, and can exchange data via the data communication connection. It is of great importance to minimize the amount of data to be transmitted via the data communication connection as much as possible. This is achieved by using the method according to the invention in that the route calculation and / or the calculation of the graphic data of the schematized graphical route representation is performed on the server and only the results are transmitted to the user terminal via the data communication connection.

Various aspects of the invention are illustrated in the drawings and are explained by way of example below.

Show it:

1 shows the display of a route on a display device, on which a geographical area is displayed based on tiles;

FIG. 2 shows the display device according to FIG. 1 when displaying the route according to the first type of the schematized graphical route representation; FIG. 3 shows the display device according to FIG. 1 when displaying the route according to a second type of the schematized graphical route representation.

FIG. 1 shows a display device 1 in which a geographical area divided into tiles 2 is displayed together with a route 3. The route 3 in this case runs from a starting point 4 to a destination point 5. The tiles 2, which are stored in a road network database in each case as a separate data set group, each comprise a quadratic subregion of the geographical area. The tile boundaries shown in FIG. 1 serve only for better understanding and are usually not displayed during operation of the navigation system. Also, it is not necessary for the inventive method that square tiles are present.

In the calculation of the route 3, all tiles 2 are selected, which are cut by the route 3 at intersection points 6 at their tile boundaries. These tiles 2, which are passed from Route 3 between starting point 4 and destination point 5, are referred to as route tiles. The data of the route tiles, for example the corresponding identification number and the location of the intersection points 6, are stored in the volatile main memory.

FIG. 2 shows the first type 9 of a roughly schematized graphical route representation of the route 3. The center 8 was calculated in each case for all route tiles stored in the main memory. The first type 9 of the roughly schematized route representation is then obtained as a sequence of line segments, each between the different

Center points 8 of the route tiles extend. The end and the beginning of the first type 9 of the roughly schematized route representation results from line segments of the respective last midpoints 8 to the starting point 4 or to the destination point 5. FIG. 3 illustrates a second type 7 of a middle-level schematized graphical route representation. In the second type 7 of the route representation, the route progression results from the sequence of line sections between the intersections 6 in the individual route tiles. It can be seen that the course of the second type 7 is already very close to the actual course of the route 3 shown in FIG.

Claims

claims

A method of operating a navigation system, comprising

an input device, at which operator commands and / or location information, in particular starting points and / or destination points, can be entered,

a road network database describing the road network of a particular geographic area,

a route calculation unit for calculating a route taking into account the location information and the road network database, the route leading from the starting point to the destination point,

a signal receiving unit for receiving position signals, in particular satellite signals,

a position determination unit which determines the current position from the position signals,

- A display device (1) at which the planned route (3) can be displayed graphically, characterized in that a) in the route calculation from the road network database route data are selected and buffered, the route data describing the route between starting point and destination point, b Calculating the graphic data of a schematized graphical route representation (7, 9) for graphical display of the route (3) on the display device (1), the graphic data being calculated on the basis of the temporarily stored route data, c) graphical display of the schematized graphical route representation (J, 9 ) on the display device (1).

2. Method according to claim 1, characterized in that in the road network database an electronic road map is stored which describes the road and intersection road network of a certain geographical area by data records, the road map being divided into several subregions, namely tiles (2). , which are stored as individual sets of records in the database, and wherein the cached route data includes tile data relating to the tiles (2), namely route tiles, over which the route (3) passes, and from the tile data Support points (6, 8) are derived, which describe the schematized graphical route representation (7, 9) at least partially as a result of line sections, each extending between the support points (6, 8).

3. The method according to claim 2, characterized in that for a first type (9) of the schematized graphical route representation in each route tile a support point (8) is determined by the fact that regardless of the route (3), a point in a certain th, predetermined position of the route tile is selected.

Method according to claim 3, characterized in that the position in the center of the route tile or the position in a certain corner of the route tile is selected as a base (8) for the first type (9) of the schematized graphical route representation.

5. The method according to claim 2, characterized in that for a second type (7) of the schematized graphical route representation in each route tile at least two support points (6) are determined by the intersection points at which the route (3) intersects the tile boundaries, be selected.

6. The method according to any one of claims 1 to 5, characterized in that the type (7, 9) of the schematized graphical route display is changed depending on the predetermined graphical resolution of the route to be displayed, in particular that the schematized graphical route display for graphical display of Route (3) in overview mode, in which the entire route is displayed contiguously.

7. The method according to claim 6, characterized in that the type (7, 9) of the schematized graphical route representation depending on the number of simultaneously displayed on the display device (1) tiles (2) or depending on the number of simultaneously on the display device ( 1) to be displayed route tiles is changed.

8. The method according to any one of claims 1 to 7, characterized in that the starting point (4) and / or the target point (5), and / or intermediate target points as bases of the schematized graphical

Route representation are selected.

9. The method according to any one of claims 1 to 8, characterized in that as the display device (1) a pixel-based pixel matrix is used, each interpolation point (4, 5, 6, 8) of the schematized graphical route representation (7, 9) a pixel of

Pixel matrix is mapped, and wherein before the display of the schematized graphical route representation (7, 9) on the pixel matrix, the distance between each adjacent, for the display of the route representation (7, 9) to be connected pixels is determined.

10. The method according to claim 9, characterized in that when exceeding a predetermined maximum distance between two adjacent pixels to be connected to the display th the calculation of additional additional support points in the corresponding section is triggered, each additional support point is again mapped to a pixel of the pixel matrix.

1 1. A method according to claim 9 to 10, characterized in that the data of the road network database is accessed for determining the additional support points.

12. The method according to any one of claims 9 to 1 1, characterized in that the calculation of additional support points is canceled as soon as the distance between two adjacent additional support points below a predetermined minimum distance.

13. The method according to any one of claims 1 to 12, characterized in that the navigation system comprises a stationary installed server and a user terminal, said server and user terminal via a, in particular wirelessly formed, data communication connection can exchange data, and wherein the route calculation and / or the Calculating the graphic data of the schematized graphical route representation on the server and transmitting the results to the user terminal via the data communication link, and wherein the display of the schematized graphical route representation is made to the display device of the user terminal.