WO2011029562A1

WO2011029562A1 - Range calculation for a plurality of roads

Info

Publication number: WO2011029562A1
Application number: PCT/EP2010/005446
Authority: WO
Inventors: Andreas Lamprecht; Jochen Ungermann
Original assignee: Audi Ag; Audi Electronics Venture Gmbh
Priority date: 2009-09-11
Filing date: 2010-09-04
Publication date: 2011-03-17
Also published as: DE102009040966A1

Abstract

The invention relates to range calculation for a plurality of roads, said roads being divisible into multiple classes. Ranges are calculated for roads belonging to a first class, while roads for paths belonging to a second class are determined by estimation.

Description

Range calculation in a variety of ways

The invention relates to the range calculation in a variety of ways.

For motor vehicles, the remaining range is usually output as a numerical value in a display in the instrument cluster. The calculation of the remaining kilometers is based purely on the measured amount of fuel in the tank and historical customer consumption.

DE 103 02 504 A1 discloses a method for determining the range of an electric vehicle, in which vehicle, route and / or environment-related information about the vehicle and a planned or a current driving route are detected and processed by a vehicle computer by means of suitable information acquisition devices. For this purpose, this information is linked to each other before starting and / or driving on a route and evaluated with respect to a predetermined or variably changing vehicle operating mode. Subsequently, the remaining range of the electric vehicle is calculated from this information and / or the evaluation result and displayed in a display device.

DE 10 2008 037 262 A1 discloses a method for outputting a determined remaining range of a tank filling of a vehicle in an optical output unit of a navigation system of a vehicle. In this case, the determined remaining range of the tank filling is alphanumerically as a distance from a current position of the vehicle a display in the optical output unit. According to the invention, the distance is output as a polygonal line closed at the current position, wherein an inner area enclosed by the polygonal line is output differently in relation to an outer area lying outside the traverse.

DE 43 44 369 A1 discloses a method for consumption-oriented driving power limitation of a vehicle drive as a function of a travel destination and the energy supply of the energy storage providing the drive power. In this case, at the beginning of the journey, the driver prescribes, via an input unit to a travel computer, travel information from which at least the total distance to the destination can be determined. The travel computer repeatedly determines the allowable target route consumption during the journey on the basis of the measured current energy supply to overcome the distance ahead.

Finally, from the target route consumption, a default value is derived, which serves as a default for a device for driving power limitation in such a way that the driving performance is limited the more, the smaller the determined target route consumption is.

From US 5,487,002 A1 an energy management system for vehicles with limited energy storage is known.

DE 692 04 811 T2 discloses a remaining range indicating device for a vehicle powered by a storage battery. In this case, the type of road that is traveled by the electric vehicle, identified as well as the distance that can drive the electric vehicle, calculated depending on the nature of the road and displayed on a display device.

The object of the invention is to simplify the operation of a motor vehicle with a limited power supply. This object is solved by the inventions given in the independent claims. Advantageous embodiments emerge from the dependent claims.

Accordingly, in a device for range calculation in a plurality of paths, which are passable by a motor vehicle, the paths in a plurality of classes einteilbar, ranges of the motor vehicle on a first class routes calculable and ranges on paths of a second class can be determined by estimation. An estimate is understood to mean a determination with a lesser (computation) effort than is carried out for a calculation of first-class paths.

In particular, the ranges on second-class routes are estimated to be less than the calculated ranges on first-class routes.

Preferably, the ranges are estimated on second-class routes such that a straight line connecting a maximum-range point (range limit) on one of the second-class paths to the starting point of the range calculation is shorter than a straight line that has a maximum-range point connects a neighboring path of the first class with the starting point of the range calculation.

For the widest possible coverage of all possible paths, a plurality, in particular a plurality, of paths of the first class are not parallel to one another. In particular, a spider is spanned by the paths of the first class.

The paths are preferred roads. The first class routes are, for example, highways and / or federal roads, while the roads In the second class preference is given to paths on which normally smaller distances are covered, such as country roads or residential streets.

More preferably, the paths of the first class are paths or, for example compared to other motorways or federal highways contained in the map material, are determined as those paths which intersect a geometric object representing a range around the starting point of the range calculation. This serves, for example, to preselect the routes of the first class. The geometric object is in particular a circle with the radius of easy reach. But even more complicated geometric objects than circles can be useful, especially in asymmetric height profiles.

The range calculation is preferably feasible taking into account a height profile.

The height profile is preferably transmitted to the motor vehicle online.

The starting point of the range calculation is, for example, the starting point of a journey.

Alternatively, the starting point of the range calculation is the current location of the motor vehicle, ie the location at which the motor vehicle is approximately at the time of presentation.

In a method of calculating a range in a plurality of roads drivable by a motor vehicle, the roads are divided into a plurality of classes, ranges are calculated on first class routes, and ranges are estimated by second-class routes. Further features and advantages of the invention will become apparent from the description of an embodiment with reference to the drawing. It shows

Figure 1 Calculation of a representation of ranges

Figure 2 a - c representation of ranges

Reach calculations often have no link reference and are therefore inaccurate. A simple example is the ride on an inclined plane. A classical range calculation would not take into account the energy needed to reach the potential energy level E _po t = m · g · Ah.

The expected driving speed is also not taken into account for the calculation. As an example, again a simple comparison is listed: A 50 km long route on a motorway would lead to the same result as a 50 km long route through a city.

Therefore, a route reference is preferably used to calculate the range. The idea is to use a simulation model of the motor vehicle, which takes into account the energy expenditure for overcoming a defined height and speed profile in order to calculate the remaining residual range.

The height and speed profile is provided by means of an interface for navigation. It does not matter if the driver has entered a destination or is driving without active route guidance.

For visualization on a map a "Spiegeleidarstellung" is used which represents 3 different areas:

^■ Area 1 of the Line of Safe Return ^■ Area 2 of the maximum range

^■ Area 3 of the Efficient Zone

This results in a high-precision calculation and visualization of the remaining range, for example for an electric vehicle.

FIG. 1 shows the calculation of the distance-related range, in particular a remaining range. The initial value of the calculation process is today's range specification, represented in the sketch as a geometric object in the form of a circle. Next, the intersections K, of this circle are determined by the class "highway" routes, which are the maximum range points on first-class routes.

Now, from a starting point, here the ego position of the motor vehicle represented as a triangle in the middle, the route to the K 's is determined, in the example this is the distance E ^ to the intersection Ki.

From this route, the elevation profile is now read from the navigation database. If the height profile in the motor vehicle is not available, this profile could be downloaded via an online query from the Internet. The now available altitude profile, together with the expected speeds, which result from the classes and the current traffic situation, is transferred to a vehicle model. This is now able to calculate the point Ri, which indicates how far the motor vehicle can travel on exactly this route with the remaining energy content.

Repeating this process now for all K, along the radius' can be generated at the end of a kind of spider representation. This kind of presentation is shown in Figure 2a. The corners are rounded off for aesthetic reasons.

To increase the precision, further K's can be generated by cutting the geometric object in the form of a circle with lower (street) class paths such as federal highways.

The final presentation has several areas:

^■ Area 1: "Line of Safe Return" - If you move within this range you can return to your starting point without refueling.

^■ Range 2: "Maximum Range" - This is the range 2 that can be achieved "simply". Within area 2, a petrol or electricity filling station must be available.

^■ Area 3: "Efficient Zone" - This is area 3, which can be achieved by a particularly efficient driving style.

A planned in a navigation device route is represented by a line 4, wherein the already driven part of the route is shown thicker than the still moving part.

The calculation of the range works, however, even without entering a navigation destination. The comfort and planning reliability for the driver are significantly increased, as not a navigation destination must be entered time consuming with each trip.

FIGS. 2b and 2c show how the ranges 1-3 are dynamically tracked according to the calculated ranges during a drive of the motor vehicle. The starting point is always the current one Location of the motor vehicle. During the drive of the motor vehicle, the ranges and thus the ranges 1 to 3 shrink and their center shifts approximately with the motor vehicle.

In the case of an active route guidance, the displayed route is colored in the same way as the areas already mentioned. The representation of the remaining range extends in this case to the 2-dimensional distance. Optionally, the area representation of the areas can then be deactivated and only the route is colored.

Claims

claims

1. A device for calculating range in a plurality of ways, characterized

that the paths are divisible into a plurality of classes,

that ranges are calculable on ways of a first class, and ranges can be determined by estimation on ways of a second class.

2. Apparatus according to claim 1,

characterized in that the ranges on paths of the second class are so estimable that they are less than the calculated ranges on paths of the first class.

3. Device according to one of the preceding claims,

characterized in that the ranges on second-class routes are estimable such that a straight line connecting a maximum-range point on one of the second-class paths to the starting point of the range calculation is shorter than a straight line that has a maximum-range point connects a neighboring path of the first class with the starting point of the range calculation.

4. Device according to one of the preceding claims,

characterized in that a spider can be spanned by the paths of the first class.

5. Device according to one of the preceding claims, characterized in that the paths of the first class are highways and / or federal roads.

6. Device according to one of the preceding claims,

characterized in that the paths of the first class are paths intersecting a geometric object representing a range around the origin of the range calculation.

7. Device according to one of the preceding claims,

characterized in that the range calculation is feasible taking into account a height profile.

8. Apparatus according to claim 7,

characterized in that the height profile of the device is transmitted online.

9. Device according to one of the preceding claims,

characterized,

that the starting point of the range calculation is the starting point of a journey.

10. Device according to one of the preceding claims,

characterized,

that the starting point of the range calculation is the current location.

11. A method of calculating range in a plurality of ways, in which the paths are divided into a plurality of classes,

at the ranges are calculated on routes of a first class and

in which ranges are estimated by way of estimates of a second class.