EP4341882A1 - Determining a vehicle configuration which is adapted to the driving behavior of a person - Google Patents

Abstract

The invention relates to a method for determining a vehicle configuration (24) which is adapted to the driving behavior of a person, having the steps of: determining a driving profile (20) of the person, said driving profile (20) comprising a speed profile and/or acceleration profile of a vehicle (10) being controlled by the person; ascertaining category values (28) for the driving profile (20) for a plurality of vehicle configurations (24), wherein the category values (28) comprise at least one of the values selected from the energy requirement and the C02 emission for each vehicle configuration (24), and the energy requirement or the CO2 emission is calculated from the speed profile and/or acceleration profile; and determining an optimal vehicle configuration (24) by ascertaining vehicle configuration values (30) for each vehicle configuration (24) by weighting the category values (28) for each vehicle configuration (24) and selecting the optimal vehicle configuration value (30).

Description

Determining an adapted to the driving behavior of a person

vehicle configuration

The invention relates to a method, a computer program, a computer-readable medium and a system for determining a vehicle configuration that is adapted to the driving behavior of a person.

People who want to buy a new vehicle are often overwhelmed with the decision of choosing the right powertrain configuration. Sellers are often not able to provide individual advice and may not be objective/independent. Furthermore, the energy consumption, fuel consumption and CO2 emissions of a vehicle depend on the driving behavior of the driver. By optimizing the vehicle configuration and, in particular, the vehicle drive train with regard to the driver's driving behavior, more economical and environmentally friendly vehicles can be provided.

It is the object of the invention to provide a vehicle with low energy consumption, low fuel consumption and/or low CO 2 emissions for a driver.

This object is solved by the subject matter of the independent claims. Further embodiments of the invention result from the dependent claims and from the following description.

One aspect of the invention relates to a method for determining a vehicle configuration that is adapted to the driving behavior of a person or a driver. The computer-implemented method can be executed automatically by a computer system. In particular, the method can be used to recommend a suitable drive train for the vehicle as a function of the driving profile. The vehicle may be a road vehicle such as a car, truck, or motorcycle.

According to one embodiment of the invention, the method comprises: determining a driving profile of the person, the driving profile being a speed profile and/or comprises an acceleration profile of a vehicle controlled by the person. In particular, the driving profile is determined using a vehicle other than the vehicle whose configuration is to be adapted or optimized. The driving profile includes data of a vehicle that is controlled by the person or the driver and that can be recorded and/or determined while driving. This data can include speed values and/or acceleration values. It is also possible that further information, such as a speed of the engine of the vehicle, a gear position, an accelerator pedal position, etc., is included in the driving profile. The data can be determined via sensors in the vehicle and/or calculated from measured values of these sensors. All this data is recorded for the driving profile over time.

According to one embodiment of the invention, the method further comprises: determining category values for the driving profile for a plurality of vehicle configurations, the category values comprising at least one of an energy consumption and a CO2 emission of the respective vehicle configuration and wherein the energy consumption or the CO2 -ejection can be calculated from the velocity profile and/or acceleration profile. For example, a simulation, a machine learning algorithm, or a combination thereof can be used to calculate the category scores. A category value evaluates a vehicle configuration in relation to the driving profile in terms of a specific category, such as fuel consumption, energy consumption, C02 emissions, etc.

The driving profile is used to determine one or more category values for a plurality of vehicle configurations. A corresponding algorithm is used for this purpose, in which a vehicle configuration and the driving profile are entered and which outputs one or more category values.

A vehicle configuration determines the structure of the vehicle to be configured, ie which drive is to be used, how is the transmission structured, etc. Wind resistance and/or a body shape can also be contained in the vehicle configuration. It is possible that person is the plural of vehicle configurations, for example via a configurator application operated by the person.

According to an embodiment of the invention, the method further comprises: determining an optimal vehicle configuration by determining vehicle configuration values for each vehicle configuration by weighting the category values for each vehicle configuration and choosing an optimal vehicle configuration value.

An optimal vehicle configuration is determined from the one or more category values. To do this, the category values are weighted to determine a vehicle configuration value. The vehicle configuration value can be used to evaluate a vehicle configuration in relation to the driving profile. It is possible that the person set the weight using the configurator application mentioned above.

The optimal vehicle configuration is determined from the vehicle configuration values. This can be the vehicle configuration with the highest or lowest vehicle configuration value.

According to one embodiment of the invention, the driving profile is determined using a person's mobile device, which records movement data with internal sensors and the driving profile is generated from the movement data. The mobile device can be a smartphone or tablet. An internal sensor can be a GPS sensor and/or an acceleration sensor. The data determined by the internal sensors of the mobile device can be stored in the mobile device and/or can be transmitted to a server via a data communication network for mobile devices, which evaluates the data and carries out further steps of the method.

According to an embodiment of the invention, the mobile device is carried in a vehicle controlled by the person. With this vehicle, the movement profile or at least a part of routes of the driving profile is determined. In particular, the speed values and/or acceleration values of the driving profile can be recorded with a mobile device in this vehicle.

According to one embodiment of the invention, the mobile device recognizes whether it is based on the movement data in a controlled vehicle and whether the driving profile is generated solely from the movement data recorded in the vehicle. From acceleration values and/or speed values it can be determined whether the person is walking or is in a vehicle. This means that it can be automatically recognized whether values for the driving profile are to be recorded.

According to one embodiment of the invention, the driving profile includes a plurality of routes. A route can be a specific route taken by the person from a starting point to a destination. A route can be traversed several times and/or regularly. For example, the person can use the mobile device to select which of the routes to use to determine the category values. Only certain routes, such as the way to the person's place of work, can be included in the driving profile.

A new route can be started each time the vehicle is stationary for a longer period of time and/or the mobile device detects that it is leaving the vehicle or being brought into the vehicle. The mobile device can be designed to record data communication with the vehicle and in this way recognize that it should start recording data for the driving profile and/or a route.

According to an embodiment of the invention, the vehicle configuration includes at least one of the following information: a vehicle string, an average fuel consumption, a mass of a selected vehicle, and/or a drag coefficient of a selected vehicle. A vehicle configuration can have a powertrain type (such as electric, petrol, diesel, gas, etc.), an engine type (e.g. wise with different maximum powers), a transmission type (automatic/manual), etc. Furthermore, the vehicle configuration can include a body type from which the drag coefficient can be derived. In general, the vehicle configuration can include information that indicates a fuel or energy consumption of the vehicle to be configured depending on the driving profile.

According to one embodiment of the invention, the weights for the category values are at least partly chosen by the person. For example, the person can use the mobile device to choose which category is more important to them than another category, such as C02 emissions, energy consumption, wear and tear, etc. With this choice, the weight for the important category can then be increased.

According to one embodiment of the invention, the driving profile includes positions of a route traveled by the person. Not only the speed and/or the acceleration, but also the location of the vehicle can be stored in the driving profile. It can thus be determined from map data whether certain regularly traveled routes are advantageous for a vehicle configuration or not. The driving profile can indicate, for example, that the person usually drives in a built-up area or drives in a mountainous area. In addition, gas stations and/or charging stations can also be determined along routes.

According to one embodiment of the invention, a category value is determined that takes into account charging stations for electrically operated vehicles or gas stations along the route. For example, the category value for a vehicle configuration with an electric drive can depend on how many charging stations for the drive are available along the routes of the driving profile.

According to one embodiment of the invention, the category values for the driving profile are determined by simulating a vehicle driving along the driving profile with the vehicle configuration. Depending on the vehicle configuration, an energy Energy consumption and/or C02 emissions of the respective vehicle configuration can be calculated. The driving profile can be broken down into sections and/or routes. Energy consumption and/or CO2 emissions can then be calculated for each section and/or route of the driving profile. Energy consumption and/or CO2 emissions can also be determined for individual routes.

The category values can thus be determined by a simulation with which the route that the person has traveled with the vehicle is virtually driven with a vehicle that has the desired vehicle configuration. The driving behavior of the person who is stored in the driving profile can be included.

In accordance with an embodiment of the invention, each category value is determined by a machine learning algorithm into which the driving profile is input. It may be that the entire calculation of a category value from the driving profile is performed by a machine learning algorithm. The output of the machine learning algorithm, such as an artificial neural network, is one or more category values.

According to one embodiment of the invention, the energy consumption or the CO 2 emission is determined as a function of a speed and/or an acceleration using a machine learning algorithm. It may be that the machine learning algorithm only determines an energy consumption and/or a CO2 emission for the respective vehicle configuration for a section and/or a route of the simulated route that the vehicle covers with a vehicle configuration in the simulation.

It is also possible that the vehicle configuration values are also determined by the machine learning algorithm, ie the vehicle configuration values are output values of the machine learning algorithm and/or that a category value is already the vehicle configuration value of the vehicle configuration entered into the machine learning algorithm. According to an embodiment of the invention, the machine learning algorithm has been trained with a variety of driving profiles, speeds and/or accelerations and a variety of vehicle configurations for which the category values, energy consumption and/or CO 2 emissions are known. Driving profiles that have already been provided with category values can be stored in a database, for example on the server. The machine learning algorithm, something like an artificial neural network, is trained with data from this database in order to then calculate suitable category values, energy consumption and/or CO2 emissions from an unknown driving profile and vehicle configuration.

According to one embodiment of the invention, an associated machine learning algorithm is trained for each vehicle configuration. This means that each vehicle configuration can have its own machine learning algorithm. Alternatively, the vehicle configuration can also be entered into the machine learning algorithm. In this way, category values, energy consumption and/or CO2 emissions can also be generated for vehicle configurations for which no training data was available. Overall, it is also possible for the machine learning algorithm to evaluate the vehicle configurations in relation to the driving profile, i.e. a value is output for each vehicle configuration that evaluates the vehicle configuration as a whole.

According to an embodiment of the invention, the method further comprises: determining a vehicle based on the vehicle configuration. The determined vehicle configuration can be inserted into an order for a vehicle, based on which a vehicle is then manufactured that has the vehicle configuration and in particular the corresponding drive train.

Further aspects of the invention relate to a computer program which, when executed on a computer system, directs the computer system to carry out the method as described herein, and a computer-readable medium in which such a computer program is stored. A computer-readable medium can be a hard disk, a USB storage device, a RAM, a ROM, an EPROM or a FLASH memory. A computer-readable medium can also be a data communication network, such as the Internet, that enables downloading of program code.

For example, the computer system may include the mobile device and optionally a server to which the mobile device is connected.

A further aspect of the invention relates to a system for determining a vehicle configuration adapted to the driving behavior of a person, which is set up to carry out the method as described herein. It is to be understood that features of the system can also be features of the method or the computer program and the computer-readable medium and vice versa. The system can be the computer system described above. It is also possible that the vehicle with which the driving profile is recorded is part of the system.

Exemplary embodiments of the invention are described in detail below with reference to the accompanying figures.

1 schematically shows a system according to an embodiment of the invention.

2 shows a flow chart for a method according to an embodiment of the invention.

The reference symbols used in the figures and their meaning are summarized in the list of reference symbols. In principle, identical or similar parts are provided with the same reference symbols.

1 shows a vehicle 10 together with a system 12 comprising a mobile device 14 and a server 16 for determining a vehicle configuration which is adapted to a person's driving behavior. The mobile device 14, such as a mobile phone or tablet computer, is carried in the vehicle 10, which is controlled by the person. ed. While driving, the mobile device 14 records movement data of the vehicle with internal sensors 18, such as a GPS sensor or an acceleration sensor, and sends this data to a server 16, which compiles this data into a driving profile for the person. The mobile device 14 and the server 16 are connected via a mobile data communication network for data exchange.

With an application that is executed by the mobile device 14, the person can also create multiple vehicle configurations that are sent to the server 16. The server 16 then uses the driving profile to determine which vehicle configuration is optimal for the person's driving profile and thus for their driving behavior with regard to one or more categories, such as energy consumption or CO2 emissions.

It is to be understood that the mobile device 14 can also partially carry out the method steps which are described above and below in connection with the server 16 .

FIG. 2 shows a diagram with which a method for determining a vehicle configuration adapted to the driving behavior of the person is illustrated. The method can be performed by a software application on the mobile device 14 in interaction with other software components on the server 16. The software application on the mobile device can be obtained from the person using a digital distribution platform for application software from the operating system manufacturer of the mobile device 14 . The person can also create a user account and use it to register in the software application.

In step S10 a driving profile 20 of the person is determined with the mobile device 14 .

The driving profile 20 includes a speed profile and/or an acceleration profile of the vehicle 10 controlled by the person, which is recorded with the mobile device 14 carried in the vehicle 10 controlled by the person. The driving profile 20 is determined with the person's mobile device 14, which records movement data with internal sensors 18 and wherein the driving profile 20 consists of the Movement data is generated. The movement data can include speeds, accelerations and/or positions.

For example, the software application on the mobile device can record position data during a journey and then transmit this to the server 16 for evaluation. A data history can be stored and pre-processed there. The driving profile 20 can include a history of the movement data of trips made by the person. The trips can be recorded using the software application that is installed on the mobile device 14 via the integrated GNSS (Global Navigation Satellite System) receiver of the mobile device 14 . A direct connection to the vehicle 10 is therefore not necessary. However, vehicle data can also be integrated to improve the estimates. For this purpose, the mobile device can receive this data via an interface to the vehicle 10 .

It is possible for the mobile device 14 to automatically recognize whether it is located in the controlled vehicle 10 based on the movement data. The driving profile 20 can then only be generated from the movement data recorded in the vehicle 10 . So that the person does not have to start and stop recording the journey themselves every time they drive, the software application can automatically detect when a journey begins and ends and start and stop the recording process. To do this, it is detected whether movement is possible without a vehicle or not in order to start recording, and after a certain period of time without movement, recording is stopped and the journey is completed. This allows the software application to run in the background and requires little attention from the person.

The individual trips can also be stored as routes 22 in the driving profile 20 . The person can use the mobile device 14 to select which of the routes 22 will be used for the further process or stored in a database on the server 16 . The recorded position data, for example of an individual trip determined as above, can then be combined into a route 22 . These automatically recorded routes 22 can then be presented to the person on the mobile device 14 in an overview. It's possible that the Person must release the routes 22 for further analysis. Routes 22 can also be deleted.

In step S12 several possible vehicle configurations 24 are determined. This can be done, for example, by the person configuring one or more vehicles with the software application and the server 16 determining possible vehicle configurations 24 for this purpose. However, it is also possible for the following steps to be carried out for all possible vehicle configurations 24 that are stored in the server 16 .

The vehicle configuration 24 is a data structure that can contain information about the following characteristics of a configured vehicle: a drive type, a vehicle train, an average fuel consumption, a mass of the selected vehicle, a Cd value of the vehicle, etc. In particular, information about at what speed and/or what acceleration the vehicle consumes how much energy or fuel can be contained in the vehicle configuration 24 .

Overall, the method should enable the person to find the optimal drive train concept for his driving profile 20 . The properties of a (hybrid) drive train, for example ICE (Internal Combustion Engine), FIEV (Hybrid Electric Vehicle), PFIEV (Plug-in Hybrid Electric Vehicle), BEV (Battery Electric Vehicle), hydrogen drive, natural gas drive , can be configured individually, although concepts that currently do not exist can also be configured, such as a hypothetical hybrid drive made of natural gas and hydrogen. In addition to the parameters for the drive, vehicle parameters can also be taken into account and/or stored in the vehicle configuration 24 .

In the following steps of the method, vehicle configurations 24 are weighted with regard to certain categories. These weights 26 can be at least partially selected for the categories or the associated category values 28 by the person using the software application. For example, the person can whether an electric drive is very important to her and/or whether she also wants to drive in areas that are poorly accessible for electric vehicles. The weights 26 can then be determined from this information.

It is to be understood that steps S10 and S12 can also be carried out in reverse order.

In step S14, the server 16 determines category values 28 for the driving profile 20 for a plurality of vehicle configurations 24. Category values 28 are determined at least for energy consumption and/or CO2 emissions for the respective vehicle configuration 24, which were determined in step S12. The energy consumption or the CO2 emissions are calculated from the speed profile and/or acceleration profile that were determined in step S10.

The parameters from the respective vehicle configuration 24 are used for the calculation. Category values 28 can also be determined for other categories, such as cost savings, CO2 savings, charging/refueling comfort, range, etc. A category value 28 evaluates the respective category, for example from 0 to 1, with 0 being “low” or can mean "minimal" and 1 "high" or "maximum".

In particular, the category value 28 for a category relating to the driving profile 20 is determined by simulating driving along the driving profile 20 by a vehicle with the vehicle configuration 24 . The respective energy and/or fuel consumption of the vehicle can be calculated from the parameters for the vehicle configuration 24 and the speed and/or acceleration along the trips and/or routes 22 stored in the driving profile 20 . The parameters can be entered into a model of the vehicle, which calculates the respective energy and/or fuel consumption. The energy and/or fuel consumption for a trip and/or route 22 or for the entire driving profile 20 is calculated by adding up these values. With the simulation, the fuel/energy consumption and/or the C02 emissions can be estimated based on the speed and/or acceleration profile during the journey. Data-driven models (such as machine learning) based on historical vehicle data can be used for the assessment. The model can also take into account vehicle parameters such as the specified WLTP (World harmonized Light-duty Vehicles Test Procedure) consumption or the mass and the drag coefficient. The consumption values can also be used to calculate potential cost savings. Furthermore, additional costs/savings through tax benefits, costs for vehicle maintenance (e.g. electric vehicles do not require engine oil and have significantly lower brake wear due to the possible recuperation) and also the depreciation can be taken into account. The environmental compatibility can be evaluated via the C02 emissions.

The person's individual usage profile, which results from the driving profile 20, is not compared with predefined usage profiles; instead, the person's driving behavior is calculated using simulation with the individual framework conditions and possible drive train configurations.

A category value 28 can be determined by a machine learning algorithm into which the driving profile 20 is input. It is also possible for the energy consumption or the CO2 emission to be determined as a function of a speed and/or an acceleration using a machine learning algorithm. The model used to determine the energy consumption or CO2 emissions during the simulation can be a machine learning algorithm. It is possible that an associated machine learning algorithm is trained for each vehicle configuration 24 or that the vehicle configuration 24 is additionally entered into the machine learning algorithm.

The position data and the cumulative consumption data can also be used to assess the comfort when recharging or refueling. Depending on the energy source, these times differ considerably. Generally can be rated how often the person has to recharge the energy storage device(s) (petrol, diesel, battery, natural gas, hydrogen) in a given period of time. The corresponding category value 28 can be used as a secondary evaluation criterion or weighted less. First-rate or higher weighting can be used to evaluate how high the proportion of journeys or routes 22 is that cannot be driven with a single tank filling/loading and thus cause additional waiting time for the person for refilling. These evaluation criteria can also be weighted with regard to the existing charging infrastructure by comparing the position data from the driving profile 20 with existing map material.

If the driving profile 20 includes positions of a route 22 traveled by the person, a category value 28 can be determined which takes into account charging stations for electrically operated vehicles or filling stations along the route 22 . When determining the best possible powertrain configuration, the availability of charging options can be taken into account. This means that if there are no charging stations in the vicinity of Route 22, then an electric vehicle is less recommended than if the charging infrastructure is better developed. In this way, regional differences can also be included in the calculation.

In step S16 an optimal vehicle configuration 24 is determined from the category values 28 . For each vehicle configuration 24 determined in step S12, a vehicle configuration value 30 is determined by weighting the category values 28 from step S14. An optimal vehicle configuration value 30, for example the largest vehicle configuration value 30, is selected from the vehicle configuration values 30, which evaluate the vehicle configuration 24 overall.

A vehicle configuration value 30 may be calculated by multiplying the category values 28 by the associated weights 26 and then summing. The ratings of the categories, ie the category values 28, can then be user-defined weighted and combined into a unitless total value, ie the vehicle configuration value 30, which can be used for decision-making. The goal may be to recommend the powertrain or vehicle that maximizes the person's utility.

The software application can then retrieve the results, such as the category values 28 and/or the vehicle configuration value 30, from the server 16 and visualize them on the mobile device 14 for the person.

In summary, the person can use their mobile device 14 to record their journeys manually or automatically using the GPS function of the mobile device 14 . After the person has confirmed that the recorded route is relevant for the analysis, the data is uploaded to a central database in the server 16 and analyzed there. If a representative database can be assumed, a powertrain configuration is determined from the analyzes carried out. Certain criteria (e.g. profitability, environmental impact) can be weighted differently in the determination. The recommendation is then transmitted again to the mobile device 14 and displayed to the person.

The software application on the mobile device 14 or the system 12 can also be used for other options. For example, the person's driving profile 20 can be compared to the average of driving profiles of other people. The created driving profile 20 is compared with other driving profiles 20 in the database. In this way, the person can be given specific feedback on their driving behavior. Anomalies can be shown and suggestions for improving defined criteria can be displayed.

The system 12 can still be used sensibly even after a vehicle has been purchased. It can serve as proof for car insurance. This means that the person receives a rate reduction from the insurance company if they record a defined portion of their journeys with the software application. The system 12 can then also provide feedback and recommendations on driving behavior. The software application can also determine the current mileage or the kilometers driven (ie the mileage) of the vehicle without being connected to the vehicle. All you have to do is enter an initial mileage at the beginning or read it out through an interface to the vehicle.

This can also be used to coordinate regular service in a workshop. In order to plan these usage losses as well as possible, a current mileage of the vehicle can be determined. However, there is often no data connection to the vehicle and the users do not communicate this information regularly either. The software application can determine the mileage by continuously recording the distances driven.

It should also be noted that "comprising" does not exclude other elements or steps, and "a" or "an" does not exclude a plurality. Furthermore, it should be pointed out that features or steps that have been described with reference to one of the above exemplary embodiments can also be used in combination with other features or steps of other exemplary embodiments described above. Any reference sign in the claims shall not be construed as a limitation.

Reference Vehicle System Mobile Server Motion Sensor Driving Profile Route Vehicle Configuration Weight Category Value Vehicle Configuration Value

Claims

patent claims

1 . Method for determining a vehicle configuration (24) adapted to the driving behavior of a person, the method comprising:

determining a driving profile (20) of the person, the driving profile (20) comprising a speed profile and/or an acceleration profile of a vehicle (10) controlled by the person;

Determination of category values (28) for the driving profile (20) for a plurality of vehicle configurations (24), wherein the category values (28) include at least one of energy consumption and CO2 emissions for the respective vehicle configuration (24) and wherein the Energy consumption or CO2 emissions are calculated from the speed profile and/or acceleration profile;

determining an optimal vehicle configuration (24) by determining vehicle configuration values (30) for each vehicle configuration (24) by weighting the category values (28) for each vehicle configuration (24) and choosing an optimal vehicle configuration value (30).

2. The method of claim 1, wherein the driving profile (20) with a mobile device (14) of the person is determined, which records movement data with internal sensors (18) and wherein the driving profile (20) is generated from the movement data; wherein the mobile device (14) is carried in the vehicle (10) controlled by the person.

3. The method according to claim 2, wherein the mobile device (14) recognizes whether it is based on the movement data in the controlled vehicle (10) and the driving profile (20) only from the movement data recorded in the vehicle (10). is produced.

4. The method according to any one of the preceding claims, wherein the driving profile (20) comprises a plurality of routes (22), wherein the person with a mobile device (14) can select which of the routes (22) are used to determine the category values (28).

5. The method according to any one of the preceding claims, wherein the vehicle configuration (24) includes: a vehicle train, an average fuel consumption, a mass of a selected vehicle, and/or a drag coefficient of a selected vehicle.

6. The method according to any one of the preceding claims, wherein the weights (26) for the category values (28) were at least partially chosen by the person.

7. The method according to any one of the preceding claims, wherein the driving profile (20) comprises positions of a route (22) traveled by the person; wherein a category value (28) is determined, which takes into account charging stations for electrically operated vehicles or gas stations along the route (22).

8. The method according to any one of the preceding claims, wherein the category values (28) for the driving profile (20) are determined by simulating a driving along the driving profile (20) by a vehicle with the vehicle configuration (24).

9. The method according to any one of the preceding claims, wherein each category value (28) is determined by a machine learning algorithm into which the driving profile (20) is input; and/or wherein the energy consumption or the CO2 emission is determined as a function of a speed and/or an acceleration using a machine learning algorithm.

10. The method according to claim 9, wherein for each vehicle configuration (24) an associated machine learning algorithm is trained; or wherein the vehicle configuration (24) is additionally entered into the machine learning algorithm.

11. A computer program which, when run on a computer system (12), directs the computer system (12) to carry out the method according to any one of the preceding claims.

12. Computer-readable medium in which a computer program according to claim 11 is stored.

13. System (12) for determining a vehicle configuration (24) adapted to the driving behavior of a person, which is set up to carry out the method according to one of claims 1 to 10.