阅读说明：本技术 用于监视车辆驾驶员的活动的设备和方法以及存储介质 (Apparatus and method for monitoring activity of vehicle driver and storage medium ) 是由 F·伍尔夫 于 2019-06-27 设计创作，主要内容包括：本发明涉及一种用于监视车辆(14)的驾驶员的活动的设备和方法,所述设备具有用于监视多个驾驶员活动(16)的装置,借助所述装置感测在用于影响车辆运动的促动器(2,201,202)上的不同驾驶员活动,并且设置有驾驶员活动强度程度(4)的评价装置,借助所述评价装置对于对应的驾驶员活动(6)在对应的车辆反应的迫切性方面的强度进行评价并且将该强度作为和驾驶员干预(8,801,802)的强度输出,其中,根据所述驾驶员干预(8,801,802)的强度从多个不同的系统反应(7,12,121,122)中选择一个系统反应,并且执行所选择的系统反应。本发明还涉及一种计算机程序产品和一种机器可读的存储介质。(The invention relates to a device and a method for monitoring the activity of a driver of a vehicle (14), having a device for monitoring a plurality of driver activities (16), by means of which different driver activities on actuators (2,201,202) for influencing the movement of the vehicle are sensed, and having an evaluation device for the intensity level (4) of the driver activities, by means of which the intensity of the respective driver activity (6) in respect of the urgency of the respective vehicle reaction is evaluated and output as an intensity with a driver intervention (8,801,802), wherein one system reaction is selected from a plurality of different system reactions (7,12,121,122) as a function of the intensity of the driver intervention (8,801,802), and the selected system reaction is executed. The invention also relates to a computer program product and a machine-readable storage medium.)

1. An arrangement for monitoring the activities of a driver of a vehicle (14), having a device for monitoring a plurality of driver activities (16), by means of which different driver activities on actuators (2,201,202) for influencing the vehicle movement are sensed, and having an evaluation device for the intensity of the driver activities (4), by means of which the intensity of the corresponding driver activities (6) in terms of the urgency of the corresponding vehicle reaction is evaluated and output as the intensity of a driver intervention (8,801,802), characterized in that one system reaction is selected from a plurality of different system reactions (7,12,121,122) depending on the intensity of the driver intervention (8,801,802) and the selected system reaction is executed.

2. An arrangement according to claim 1, characterized in that the means for monitoring the activity of the driver (15) are:

-a steering wheel angle sensor,

-a brake pedal force sensor for detecting the force of the brake pedal,

-a brake pedal travel sensor for detecting the travel of the brake pedal,

-an accelerator pedal force sensor for detecting the force of the accelerator pedal,

-an accelerator pedal travel sensor for detecting the position of the accelerator pedal,

-an occupant activity camera,

-an on/off element for switching the switching element,

-a capacitive steering wheel sensor,

-a steering wheel torque sensor for detecting a steering wheel torque,

-or a combination of the above.

3. The apparatus according to claim 1 or 2, wherein the system reaction (7,12,121,122) is:

-immediate shut-down of the power supply,

-a driver interaction between the driver and the vehicle,

-a standard shut-down of the power supply,

or combinations of the above system reactions.

4. An arrangement according to claim 3, characterised in that the immediate switch-off (7) is a non-prolonged switch-off of the current auxiliary system command (1,101,102) and that the control of the individual actuators (11) is handed over to the control of the driver (15).

5. The arrangement according to claim 3 or 4, characterized in that the immediate switch-off (7) triggers a standard switch-off (S21) or an immediate switch-off (S20) on the other actuators (11) not involved in the immediate switch-off.

6. An arrangement according to claim 3 or 4, characterised in that the standard shut-off is a delayed shut-off of all auxiliary system commands (1,101,102) and that the control of all actuators (11) is handed over to the control of the driver (15).

7. An arrangement according to claim 3 or 4, characterised in that the current assistance system instructions (1,101,102) are made in accordance with the driver's control in the case of driver interaction.

8. The apparatus of claim 7, wherein the current assistance system instruction (1,101,102) continues to remain active in the event of the driver interaction.

9. The arrangement according to claim 1, characterized in that the intensity of the driver intervention (8) depends on:

-the amplitude of the driver's manoeuvre,

-the speed of the driver's manoeuvre,

-a driver-manipulated torque,

-the driver-manipulated acceleration,

-the manipulation of a driver-operated element,

-or a combination of the above.

10. A method for monitoring (S3) the activity of a driver of a vehicle, in which monitoring driver activity (2) is sensed and an analytical assessment (5, S4, S5, S6) is made of the intensity of the driver activity (2) in terms of the urgency of a vehicle reaction, characterized in that a system reaction is selected from a plurality of different system reactions (S8, S9, S10) as a function of the intensity of the driver intervention (8) and the selected system reaction is executed (S8, S9, S10).

11. The method according to claim 10, characterized in that the signal for monitoring the activity of the driver (15) is:

-a signal of an occupant activity camera,

-an on/off signal to be switched on,

-a steering wheel angle signal,

-a brake pedal force signal for a brake pedal,

-a brake pedal travel signal for the brake pedal,

-an accelerator pedal force signal for the accelerator pedal,

-an accelerator pedal travel signal, and-a control signal,

-a signal of a capacitive steering wheel sensor,

-a signal of a steering wheel torque sensor,

-or a combination of the above signals.

12. The method according to claim 10 or 11, characterized in that the system reaction (7,12,121,122) is

-immediate shut-down of the power supply,

-a standard shut-down of the power supply,

driver interaction

-or a combination of the above reactions.

13. The method according to any one of claims 10 to 12, characterized in that the corresponding system reaction is triggered by comparing the intensity of the driver intervention with a saved threshold (S8, S9, S10).

14. The method according to any one of claims 10 to 13, characterized by triggering (S8) a driver interaction if the intensity of the driver intervention (8) is within a minimum range, wherein a motion regulator of the corresponding actuator is adapted (S11) to the driver intervention, and the driver intervention is input (S12) to the corresponding actuator (11) and performed (S13) by the corresponding actuator (11).

15. The method according to any one of claims 10 to 14, characterized in that if the intensity (8) of the driver intervention is within a middle range (S5), a respective standard shut-off is triggered (S9, S14) for all actuators, and the driver intervention is input (S15) to the respective actuator (11) and carried out (S16) by the respective actuator (11).

16. The method according to any one of claims 10 to 15, characterized in that if the intensity of the driver intervention (8) is within a maximum range (S6), an immediate switch-off is triggered (S10), and the driver intervention is input (S17) to the corresponding actuator (11) and is performed (S18) immediately by the corresponding actuator (11), and the other actuators are switched off by means of a corresponding standard switch-off (S21) or by means of a corresponding immediate switch-off (S20).

17. The method according to any one of claims 10 to 16, characterized in that if the intensity (8) of the driver intervention exceeds the highest range (S6) or is below the lowest range (S4), the method proceeds again from scratch (S19) without triggering a system reaction.

18. A computer program product set up for carrying out, implementing and/or handling the method according to any one of claims 10 to 17.

19. A machine-readable storage medium having stored thereon the computer program product of claim 10.

Technical Field

The invention relates to a device and a method for monitoring the activity of a vehicle driver, having a device for monitoring a plurality of driver activities, by means of which different driver activities on actuators for influencing the movement of the vehicle are sensed, and having an evaluation device for the intensity of the driver activities, by means of which the intensity of the respective driver activities in terms of the urgency of the respective vehicle reaction is evaluated and output as the intensity of the driver intervention, wherein one system reaction is selected from the plurality of different system reactions as a function of the intensity of the driver intervention, and the selected system reaction is carried out.

Background

DE 102016007187 discloses a method for deactivating an automated driving function, in particular a highly automated or autonomous driving function, of a vehicle, wherein the driving function is deactivated when a driver of the vehicle performs a steering intervention or a pedal intervention with an intensity that exceeds a predeterminable deactivation threshold value.

Disclosure of Invention

The core of the invention is: the driver of the vehicle is monitored, activities of the driver are identified and at least one of a plurality of system reactions is performed in accordance with the urgency of these activities. This is solved by the method and the device of the present invention.

According to one aspect of the invention, an apparatus for monitoring the activity of a driver of a vehicle is proposed, having a device for monitoring a plurality of driver activities, by means of which different driver activities on actuators for influencing the movement of the vehicle are sensed, and having an evaluation device for the intensity of the driver activities, by means of which the intensity of the respective driver activities in terms of the urgency of the respective vehicle reaction is evaluated and output as the intensity of the driver intervention, wherein one system reaction is selected from a plurality of different system reactions depending on the intensity of the driver intervention and the selected system reaction is executed.

According to a further aspect of the invention, a method is proposed for monitoring the activity of a driver of a vehicle, in which monitoring the driver activity is sensed and the intensity of the driver activity is evaluated analytically with respect to the urgency of vehicle reaction, wherein one system reaction is selected from a plurality of different system reactions depending on the intensity of the driver intervention and the selected system reaction is executed.

According to a further aspect of the invention, a computer program product is proposed, which is designed to carry out, implement and/or handle the method according to the invention.

According to another aspect of the invention, a machine-readable storage medium is provided, on which the computer program product of the invention is stored.

Advantageous embodiments and configurations of the invention result from the preferred embodiments.

It is advantageously provided that, for monitoring the activities of the driver of the vehicle, one or more steering wheel angle sensors are used in order to measure the steering angle of the steering wheel. Alternatively or in combination therewith, it may be provided that one or more capacitive steering wheel sensors or one or more steering wheel torque sensors are also used for the steering wheel angle sensor. The steering wheel angle sensor senses driver activity on the steering wheel, which in non-automated vehicles results in a determination of the direction of vehicle movement. In an automated vehicle, this maneuver is replaced by a driver assistance system.

The terms "driver assistance system" and "automated vehicle" are to be understood within the scope of the present invention as the term "system" is described and used in the standards (SAE classes 1 to 4 of standard SAE J3016). The driving assistance system may include, for example, the following components: "trajectory planning", "motion conditioning" and "actuator management" and "driving maneuver functions".

The term "trajectory planning" is to be understood within the scope of the present invention as referring to a method and a device for planning a vehicle trajectory in advance.

The term "movement control" is to be understood within the scope of the present invention as referring to a method and a device for controlling a planned trajectory of a vehicle.

The term "actuator management" is to be understood in the context of the present invention to mean a method and a device for controlling a corresponding actuator.

The term "driving operation function" is to be understood within the scope of the present invention as referring to a method and a device for selecting the most suitable driving operation among the corresponding driving situations.

It is advantageously provided that the driver's activity of the vehicle is monitored by means of one or more pedal-based devices, by means of which the driver's activity can be sensed. This is done in particular by means of an accelerator pedal and a brake pedal in the vehicle if the driver wants to change the vehicle speed or the vehicle acceleration. For example, a brake pedal force sensor and/or an accelerator pedal force sensor and/or a brake pedal travel sensor and/or an accelerator pedal travel sensor may be used.

It is advantageously provided that, for monitoring the driver's activity, one or more on/off elements are used which can be actuated by the driver. Driver activity may also be sensed by the driver turning one or more driver assistance systems on or off.

Advantageously, it can be provided that the driver's activities are monitored by means of one or more interior cameras. The interior camera images the vehicle occupants in the vehicle interior, in particular the driver himself, and can recognize the activity pattern. These captured driver activities can be compared to the saved movement patterns and evaluated. Depending on the comparison, a driver command for the driver assistance system can be sensed and implemented. The driver instructions for the driver assistance systems can be used, for example, to determine or change the vehicle movement direction and/or the vehicle acceleration and/or to switch one or more driver assistance systems on/off.

It is also advantageous if the device provided for monitoring the driver activity provides one or more signals which are further processed in a subsequent evaluation device and which reflect the driver's handling activity on the corresponding sensor in a suitable size. For example, when the accelerator pedal travel sensor is actuated, a signal is output which indicates how strongly the pedal is deflected between 0% and 100%.

It is particularly advantageous here if the urgency of the driver's activity specifies a degree of force and/or speed and/or deflection of the monitoring device caused by the driver's activity. The actuation speed of the accelerator pedal (% per second) is mentioned as an example, and this speed indicates the urgency for a change in the acceleration of the vehicle.

It is advantageously provided that the size of the urgency is compared with a stored threshold value. It is particularly advantageous here for the range between the two thresholds to be defined as the urgency range and to be referred to as "range" within the scope of the invention.

It is advantageously provided that different saved thresholds are selected depending on the currently active driver assistance system. In this case, each stored threshold value is to be understood as a value matrix, for which a free combination of different driver assistance systems results in one threshold value. It is particularly advantageous if different system reactions occur for different active driver assistance systems in order to configure the handover of the vehicle guidance more reliably and comfortably under the control of the driver.

It is advantageously provided that the sensed urgency is associated with one of preferably three ranges, namely a first lowest range, a middle range or a highest range.

The term "lowest range" is to be understood within the scope of the present invention in that the lowest range is selected if the degree of urgency lies between zero and the first threshold and thus below the middle range and the highest range.

Furthermore, the term "intermediate range" is to be understood within the scope of the present invention in such a way that the degree of urgency lies between a first threshold and a second, greater threshold. It follows that the "intermediate range" lies between the "low range" and the "high range".

Furthermore, the term "highest range" is to be understood within the scope of the present invention in such a way that the degree of urgency lies between the second threshold and a third, greater, threshold, so that the "highest threshold" represents a greater degree of urgency than in the "low range" or the "intermediate range".

It is particularly advantageous here if the degree of urgency is within a range, in order to trigger a system reaction.

It is advantageously provided that one or more system responses are assigned to each range, which are activated when the degree of urgency has a value within the assigned range.

It is advantageously provided that the system response presented is an immediate shutdown and/or a driver interaction and/or a standard shutdown.

In this context, the term "immediate shutdown" is to be understood within the scope of the present invention to mean that the entire system for vehicle guidance exhibits a system reaction in which the control of one or more actuators for vehicle guidance is given back to the driver immediately and as quickly as possible and the auxiliary system is deactivated as quickly as possible or the auxiliary system for different guidance tasks is deactivated.

The term "standard shut-off" is to be understood within the scope of the present invention to mean a system reaction which can, in the event of driver activity, give the driver control of one or more actuators back with a delay. This delay acts as a gentle and comfortable switch-off, in which case the corresponding driver assistance system returns control to the driver by means of a switch-off process, for example, a switch-off ramp (abschalrampe). Illustratively, this may occur according to an intervening ramp having a defined slope.

The "driver-interactive" system response is to be understood within the scope of the present invention in that, instead of switching off the respective assistance system, the driver and the assistance system both have an influence on the movement of the vehicle at the same time, in the case of only a small degree of urgency for driver intervention. The influence interacts with the respective actuator. Such driver interactions are present, for example, in SAE level 2 lane guidance assistance systems, in which the driver can adapt the position of the vehicle in the lane by slightly actuating the steering wheel without deactivating the system. The driver can thus intervene in the actuator control in a regulated manner with a low degree of urgency.

Of particular significance is the implementation of the method according to the invention in the form of a control element which is provided as a control for a driver assistance system or a highly automated vehicle guidance system of a motor vehicle. In this case, a program is stored on the control element, which program can be run on a computer, in particular on a microprocessor or a signal processor, and is suitable for carrying out the method according to the invention. In this case, the invention is implemented by means of a program stored on a control element, so that the control element provided with the program constitutes the invention in the same way as a method suitable for execution by the program. In particular, an electrical storage medium, for example a read-only memory, can be used as a control element.

Further features, application possibilities and advantages of the invention result from the following description of an exemplary embodiment of the invention which is illustrated in the drawings. All features described or shown here, alone or in any combination, form the subject matter of the invention, independently of their generalization in the claims or their reference, and independently of their representation or illustration in the description or in the drawings.

Drawings

Embodiments of the invention are explained below with reference to the drawings. The figures show:

figure 1 shows an exemplary arrangement of the inventive device for monitoring the activities of a driver of a vehicle,

FIG. 2 is an exemplary flow chart of a method of the present invention for monitoring vehicle driver activity.

Detailed Description

Fig. 1 shows a schematic illustration of an embodiment of a device for monitoring a plurality of driver activities 16. The device 16 monitors a plurality of active channels 2,201,202, for example a lateral control of the vehicle, an acceleration of the vehicle, a deceleration of the vehicle, wherein each channel actuates an actuator for the vehicle control by means of a driver assistance function. The monitoring by the monitoring device 14 perceives the activity performed by the driver of the vehicle 14 in relation to the corresponding vehicle guidance channel 2,201, 202. The control of the driver 15 is evaluated by means for determining the intensity of the driving activity 5 with respect to the urgency of said driver activity and thereby defining the intensity of the corresponding driver activity 6. The intensity of the corresponding driver activity 6 is then compared in the device for determining the intensity of driver activity 4 with the values stored as thresholds H0, H1, H2, H3, H4, wherein the intensity of the corresponding driver activity 6 is assigned to the respectively suitable range.

The range may be defined, for example, by the saved values H0, H1, H2, H3, H4, wherein H0< H1< H2< H3< H4. Here, H0 means that there is no driver activity. The saved values are selected according to the currently active driver assistance system or according to a combination of the currently active driver assistance systems.

If the value is between H1 and H2, the intensity of the corresponding driver activity 6 is assigned to the lowest range.

If the value is between H2 and H3, then the intensity of the corresponding driver activity 6 is assigned to the mid-range.

If the value is between H3 and H4, the intensity of the respective driver activity 6 is assigned to the highest range.

The threshold values are stored in the control unit together with the associated ranges, so that the control unit 13 can decide, depending on the input urgency values, by means of the stored threshold values, whether and which system reaction 7,12,121,122 should be triggered.

If, for example, a highly automated vehicle is considered which is being driven without driver intervention, no activity signal and no urgency value are generated without actuation by the driver. However, if the driver is panic due to a dangerous driving situation and actuates the brake pedal with full force in response to this, a driver activity signal is generated by the pedal sensor, from which the driver activity signal also forms an urgency value. This is recognized by the device for monitoring the activity of the driver of the vehicle 14 and the urgency value is compared to the saved threshold value. Due to the intensive driver maneuver, this intervention is associated with the highest range with a high degree of urgency. In the case of this urgency, which triggers an immediate switch-off 7 in the actuated actuator, which in the example of brake pedal actuation under consideration is a deceleration actuator, an immediate switch-off is triggered. Since the highest urgency range is assigned to the urgency range, immediate shutoff 121,122 is also triggered in the other actuators by the control element 13, respectively, so that the vehicle is immediately controlled by the driver. In the case of an assignment of the urgency value to the intermediate range, only the actuator concerned, i.e. the deceleration actuator, will be subjected to an immediate switch-off, whereas the other actuator channels, e.g. the steering actuator, are switched off only according to the standard switch-off, since no urgency is given for an immediate switch-off of the other actuator channels.

FIG. 2 shows a schematic diagram of an embodiment of a method for monitoring vehicle driver activity. In the beginning, a check is made as to whether the driver assistance system is on S2. If the driver assistance system is not active, the flow returns to start S1. If the driver assistance system 16 has been activated, the method continues by reading the output signal 2 of the at least one driver activity sensing device in step S3. The driver activities of the various channels, for example signal 2 of the steering angle sensor, signal 201 of the brake pedal sensor or signal 202 of the accelerator pedal sensor, are preferably sensed and relayed by means of different sensors. In step S3, an urgency value is sought based on the driver activity value, which indicates how quickly the driver activity must be accomplished by the vehicle system. For this purpose, the ascertained urgency values are compared with the saved thresholds H0 to H3 and are assigned to one of the ranges in which different system responses are provided as a function of the driver activity.

In a subsequent step S4, it is checked whether the intensity of the driver intervention 8, i.e. the urgency value, should be assigned to the lowest range S4. If the lowest range has been selected, the method continues in steps S8, S11, S12 and S13 by triggering a system reaction of driver interaction for the actuator that has received driver intervention. Since the driver activity is only small and the urgency likewise has only a small value, the actuator remains active and the driver activity is transmitted as an actuating signal to the actuator, so that the driver can intervene in the vehicle guidance system with only a small amount of activity, for example, in order to adjust the lateral offset of the vehicle in the traffic lane. In this case, the movement controller of the respective actuator is adapted S11 to the driver intervention, and this driver intervention is entered S12 to the respective actuator and is carried out S13 by the respective actuator. The other actuators of the other channels continue to operate unaffected during the system reaction of the driver interaction.

If it has been recognized in step S4 that the driver activity lies above the low range, the method continues in step S5, in which it is checked whether the intensity of the driver intervention 8 lies within the intermediate range. If the query is answered in the affirmative, the system reaction of the standard shutdown S9 is triggered. The system response of the standard shutdown provides that all actuators 3,301,302 are deactivated by means of the standard shutdown. It is therefore desirable to deactivate all vehicle guidance systems on the basis of the intensity of the driver intervention, but this deactivation does not have to be carried out so quickly that the regulation is ended immediately, but rather the individual actuators are comfortably deactivated by means of a conventional shut-down procedure, such as a ramp function, and safely for this driving process. This is done in steps S9, S14, S15 and S16 by triggering a standard shut-off in step S14 and subsequently inputting the corresponding driver intervention to the corresponding actuator in step S15. In step S16, the actuator is turned off.

If the driver activity value 8 is assigned neither to the low range nor to the middle range, it is checked in step S6 whether the driver activity value 8 should be assigned to the highest range. If it is determined in the check of step S6 that the driver activity value 8 lies within the highest range, then this driver activity value is assigned to the highest range. In the case of a driver activity value 8 between the thresholds H2 and H3, the method is continued in steps S10, S17, S18 and S20 or S21 by triggering an immediate switch-off in step S10 for the actuator that has been intervened. In a further procedure, in step S17, the driver intervention is immediately performed by the actuator. All other actuators are selectively deactivated by means of a "standard shut-off" according to step S21 or by means of an immediate shut-off in step S20.

The selection of whether the further actuator is deactivated by means of an immediate or a standard shut-off according to step S20 or step S21 can be determined by the system architecture in the development phase or can be made dependent on the situation, for example dependent on further environmental parameters sensed by means of the environmental sensor.

If the highest range is also not selected in step S6, the method branches according to transition S19 and returns to the beginning.