EP1747113A1

EP1747113A1 - Method and device for adapting a function in a vehicle

Info

Publication number: EP1747113A1
Application number: EP05731758A
Authority: EP
Inventors: Andreas Engelsberg; Dietrich Manstetten; Holger Kussmann; Lars Placke; Marc Stoerzel; Ulrich Schweiger
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2004-05-13
Filing date: 2005-04-01
Publication date: 2007-01-31
Also published as: WO2005110800A1; DE102004023544A1

Abstract

The invention relates to a method and a device for adapting a function in a vehicle, wherein the function comprises at least one configurable parameter. The user can activate a training or configuration mode of the function while at the same time setting a desired behavior in said function, wherein an interface (2) having an input (3) and output (4) is provided for said purpose. User-specific data for the driver assistance system (1) is stored in a configuration block (5).

Description

Method and device for adapting a function in a vehicle

State of the art

The invention relates to a method and a device for adapting a function in a vehicle.

Many functions in motor vehicle technology are designed in such a way that they assume different behavior depending on the driver type or driver request and / or driving situation. An example of this is an adaptive transmission control, in which the shift strategy is set as a function of the driver type (for example sporty, normal, etc.), which is determined either by the driver or adaptively by measuring the driver behavior. Procedures in connection with the control of an engine in the dynamic range (cf. DE 196 15 806 AI) or in connection with a vehicle speed controller (DE 196 11 502 AI) are also known. In general, the functions are changed by changing at least one parameter of the

Function, for example a filter function, adapted. Adaptive systems are also known in which the parameters are influenced depending on other factors, for example the environmental conditions, the reaching of certain locations, etc. An example of this is DE 19943 611 AI, which describes an adaptive vehicle speed controller in which the target time gap between one's own vehicle and a vehicle in front is automatically increased when it is wet and / or when visibility is low.

Due to the increase in such functions in the motor vehicle, the behavior of the vehicle is becoming increasingly opaque for the driver and possibly even Surprisingly, because the driver may also unintentionally change the behavior of the vehicle by changing his driver behavior.

Advantages of the invention

A special training or configuration mode for such adaptive functionalities or systems, which the driver must consciously activate and during which the driver can consciously teach the functionality or the system a certain behavior that he desires, that is, the extent of the influence at least of a parameter of the functionality or the system can improve the transparency of such adaptive functionalities or systems in a motor vehicle and increase their acceptance.

It is particularly advantageous that the driver has control over the type and extent of the adaptation, which goes beyond the mere setting of different operating modes (such as the settings “normal”, “sporty”, “winter” in the case of an adaptive transmission position) When the training mode is activated, the driver is able to "teach" the vehicle something and influence the future system behavior. In a particularly advantageous manner, the adaptation properties of the system are transparent to the driver and the system is adapted directly to his individual requirements.

The configuration of the training or configuration mode as an interactive process is particularly advantageous, which significantly simplifies handling and operation for the driver and also opens this possibility of training or configuration to inexperienced users.

Further advantages result from the following description of exemplary embodiments or from the dependent patent claims.

drawing

The invention is explained below with reference to the embodiments shown in the drawing. FIG. 1 shows an overview of a driver assistance system with an interface for a training or configuration mode, while FIG. 2 shows an exemplary embodiment for the functioning of this user interface using a flowchart.

Description of exemplary embodiments

A driver assistance system is shown at 1 in FIG. An example of such a driver assistance system is an adaptive distance control (ACC). However, in the following, driver assistance system is not only understood to mean such a distance control, but also other driver assistance systems such as, for example, assistance systems for keeping lane, changing lanes, etc., or also assistance systems which trigger actions depending on specific events, for example on reaching a certain location (e.g. Opening the garage door when approaching, etc.). Driver assistance systems of this type, the functionalities of which are largely implemented by means of programs, have parameters with the aid of which the system can be configured and adapted to specific driving situations and / or drivers. Such parameters are, for example, in the case of a distance control, the change in the target time gap specified by the driver when it is wet and / or if the driver does so through additional secondary activities, such as, for example

Conducting a phone call that has impaired attention. The target time gap defines the distance to a vehicle in front. Another parameter in such a system describes the way in which the driver's vehicle approaches a slower vehicle in front. Depending on the selection of the parameter, the driver's vehicle quickly drives onto the vehicle in front with a subsequent strong deceleration or, with another setting, slowly with a subsequent comparatively weak deceleration. More correct in this context is the distinction between a brake intervention that occurs earlier, ie at a greater distance, or later, ie at a smaller distance from the vehicle in front. In this sense, fast and slow opening is also to be understood below. Furthermore, parameters can be present which represent recurring functional sequences, for example trigger a specific action when a specific location is reached. Such parameters exist not only in connection with driver assistance systems, but also in other control systems in connection with a motor vehicle, for example in engine control or transmission control which is selected depending on the driver's driving style, a configuration corresponding to the driver type. Here, too, changeable parameters are provided, which are changed in accordance with the determined driving style, for example operating point-dependent shift points or filter constants describing the dynamics of the engine torque change during acceleration.

FIG. 1 shows a configuration block 5 which, for example, comprises a configuration table or a configuration memory for these parameters, which interacts with the programs of the driver assistance system 1 and is accessed by the driver assistance system. By accessing this

Configuration block 5 configures the driver assistance system according to the current configuration values available there.

The problem often arises with such adaptive systems that it is not transparent to the user under which conditions the behavior of the systems changes.

If they adapt to a driving situation, this behavior can sometimes be incomprehensible to the driver, even confusing him because the system has also reacted differently in the past. The information about the driver type or the driving style of the driver is also collected in a manner that is not recognizable to the driver

Drivers are given the opportunity to influence the configuration of the system themselves as part of a training or configuration mode and to change the parameters according to their wishes, possibly within predefined limits and / or in predefined steps. The driver is given access to configuration parameters, which goes far beyond simply setting different operating modes. For this purpose, an interface 2 is provided, which is shown, for example, as a user interface on a screen in the vehicle and which is shown by the driver when the training or configuration mode is activated. This user interface interacts with the driver assistance system 1 and comprises the areas input 3, in which the activation and setting of certain

Configurations can be controlled and the area output 4, in which feedback and / or acknowledgments about the setting made by the driver assistance system are displayed to the user. When the training or configuration mode is activated, the driver assistance system is trained by the user, in particular the driver, by making settings via the user interface 2, there the input interface 3, or starting a training or configuration process, confirming the setting made, and via the output interface Receives 4 responses from the system. The result of

The training process is stored by the driver assistance system in the configuration file 5 in the form of parameter values which represent the desired behavior of the functionality or the system.

For the execution of the interaction between user and system within this

Training or configuration mode uses key elements, complex graphical representations with input and output options and or voice input and output systems.

The driver activates the training or configuration mode via a corresponding one

The user interface 2 is made available to him by input of an operating element or by means of a corresponding voice command. Depending on the design of the system, he can influence the configuration of the system within predefined limits or adapt it to his needs using the input options there.

In the simplest design of the interaction, the user is given various menus in which the configurable functionalities or parameters are shown, for example “approaching a slower vehicle in front”, “increasing the distance when it rains”, “actions which are to be carried out when a garage entrance is reached "_,," Dynamics of the motor ", etc. If the user activates one of these menu items, the simplest embodiment provides him with various setting variants of the functionality, for example" slow approach "and" fast approach ". The user can then select and confirm a setting variant, receiving appropriate feedback and / or acknowledgments from the system when selected and confirmed. The system then adapts the configuration parameters according to the selected variants. The adaptation takes place on the basis of pre-stored parameter values. In another embodiment, the driver is enabled by the user interface to present certain driving maneuvers to the system. In one embodiment, this is done on the basis of a simulation of typical traffic events carried out in the vehicle. In order to adapt the selected functionality, in this exemplary embodiment, as part of the training mode, one or more traffic events are shown on a screen in the vehicle, to which the driver must react by actuating the pedals. The driver's reaction is measured (eg change in distance, etc.). If the driver wants to set the funcionality according to his simulated behavior, he confirms the acceptance of the setting by pressing a corresponding button or by entering a corresponding one

Command. The system then acknowledges the change in configuration.

Another version realizes the training mode during real driving. The driver is then able to set the system and learn under real conditions. This is illustrated by the example of setting a distance controller for the behavior

Approaching a slower vehicle ahead is shown. When the training or configuration mode is active, the assistance system records the driver's driving style, above all by measuring the distance to the vehicle in front, the change in distance, the approach speed, the time of deceleration, the course of the deceleration and / or the size of the deceleration. The driver has an appropriate one

Copes with the traffic situation according to his ideal ideas and if he wants to set the functionality according to the behavior shown there, he confirms the acceptance of the setting by pressing a corresponding button or by entering a corresponding command. The assistance system then sets the configuration parameters influencing the functionality accordingly, so that the desired behavior is achieved in automatic control mode.

A corresponding procedure is also provided for other functionalities. This also applies to recurring functional sequences, such as a location-dependent recurrence of functional sequences. When the training mode is active, these are configured by the user carrying out the corresponding functional sequences at a specific location. FIG. 2 shows an advantageous exemplary embodiment for the user interface. The flowchart shown outlines the process in the context of the training or configuration mode.

The training or configuration mode is activated by the driver, for example by actuating an operating element or by entering a corresponding voice command. This starts the flowchart outlined in FIG. 2 (step 20). In the subsequent step 22, the user is offered various configurable functionalities, in one exemplary embodiment, for example, the functionalities "approaching a slower vehicle driving ahead with an active distance controller", "reaction of the distance controller with poor visibility", "specifying recurring functional sequences", etc. by selecting the The driver is able to configure the functionality in the desired functionality in step 24. If there is no selection after a certain time, a query is made as to whether the driver wishes to cancel the training mode (step 26). when the driver presses an "off button" or issues a corresponding voice command. In this case, the program outlined is left.

If the driver has selected a functionality, the driver is given the option of configuration in step 28. In one embodiment, this is done

Providing a list of setting options from which the driver e.g. can select by "clicking", for example "slow approach", "normal approach", "fast approach" or "larger distance when it rains", "same distance when it rains", etc., by entering different sizes by the driver himself ( e.g. increasing the distance of 10% when it rains, etc.) and / or by selecting certain events when reaching a given location (e.g. "when entering the gate, please send out radio code for the garage door opening, close the sunroof and window of the vehicle and the radio in Bring basic setting ").

In another embodiment, this is carried out in step 28 while the vehicle is driving

Driver behavior, for example the speed of approaching a vehicle in front, recorded or determined in the context of a simulation.

In the following step 30, it is checked whether the driver has selected a specific setting or has confirmed a specific driving behavior. If this is the case, then in step 32 the setting of the system was carried out (for example by storing corresponding configuration parameters in the configuration file) and confirmed to the driver by issuing an acknowledgment signal. If there is no selection after a certain time, the driver is asked to exit training mode, make a selection or go back to the start menu.

It is then checked in step 26 whether the driver wants to end the training mode or whether another parameter should be configured. In the latter case, step 22 starts again, while in the former case the program is ended.

The embodiment shown above is illustrated using driver assistance systems. It is also used analogously in connection with other systems, for example engine control systems and or transmission control systems. The training mode, for example in engine control systems, is structured accordingly, the driver e.g. can adjust the acceleration ability of the engine.

Depending on the version, the options for interaction between driver and system shown above are used individually or in combination, i.e. realized for different functionalities in one form, for other functionalities in the other form.

In one embodiment, the user can also bring the configuration of the functionality into a grand setting by actuating an operating element or by means of a corresponding voice command.

In one exemplary embodiment, acknowledgment is understood to mean that the configuration that has been carried out is displayed to the user and that the data displayed are stored as a log in a manner that cannot be deleted.

Claims

claims

1. A method for adapting a function in a vehicle, the function comprising at least one configurable parameter, characterized in that the user of the function can impress a desired behavior in a training or configuration mode that can be activated by the user.

2. The method according to claim 1, characterized in that the at least one parameter is configurable by the user.

3. The method according to any one of the preceding claims, characterized in that the training or configuration mode is activated by operating the control element and / or entering voice commands.

4. The method according to any one of the preceding claims, characterized in that when the training or configuration mode is activated, the user has an interface with input and output interface, via which he exerts influence on the configuration of the function.

5. The method according to any one of the preceding claims, characterized in that the function is an adaptive vehicle speed controller and the at least one parameter is the speed with which the vehicle approaches an earlier, slower vehicle when the vehicle speed controller is active and or which distance change is made in unfavorable environmental conditions , represents.

6. The method according to any one of the preceding claims, characterized in that for the configuration of the at least one parameter the user presents a driving maneuver, the essential variables of this driving maneuver are recorded and, when confirmed by the driver, the measured variables as the basis for the configuration of the at least one parameter serve.

7. The method according to any one of the preceding claims, characterized in that the user is offered various configuration options, among which he selects one by means of confirmation.

8. The method according to any one of the preceding claims, characterized in that the configuration is confirmed and / or acknowledged to the user.

9. The method according to any one of the preceding claims, characterized in that the function comprises a group of recurring functional sequences, in particular a location-dependent recurrence of functional sequences, which the driver impresses on the system by selection or presentation and confirmation with active training or configuration mode.

10. The method according to any one of the preceding claims, characterized in that the training or configuration mode can be switched off by the driver and / or the system can be brought into a basic setting by the driver.

11. Device for adapting a function in a vehicle, the function comprising at least one configurable parameter, characterized in that means are provided by means of which a user activates a training or configuration mode during which the user of the function chooses a desired one Can impress behavior.