WO2024251321A1 - Control of a vehicle - Google Patents

Abstract

The invention relates to a method (200) for controlling a vehicle (105), having the steps of determining (205) that the vehicle (105) is parked; and activating (240) a specified coast-down function (125) of the vehicle (105) for a specified duration. The coast-down function (125) is only activated if at least one person (135) is on board the vehicle (105).

Description

controlling a vehicle

The present invention relates to the control of a vehicle. In particular, the invention relates to the control of a trailing function of the vehicle.

A vehicle has a large number of consumers, including interior or exterior lighting, for example. For reasons of comfort, safety or legal requirements, it may be necessary to continue operating one of the consumers for a predetermined period of time after the vehicle has been parked. For example, a vehicle's interior light is usually only switched off when all doors are closed and a predetermined period of time has elapsed.

Due to the large number of consumers, the total current consumed can be considerable. This can put a strain on an on-board network and in particular on an electrical energy storage device connected to it. In the case of an electrically powered vehicle, the usable range can be reduced.

DE 10 2004 055 836 proposes to control a display device on board a motor vehicle depending on the occupancy of a seat from which the display device is visible.

Known techniques focus on consumers that can be used in the interior of the vehicle and usually while driving. However, these techniques are hardly applicable to a function that continues to run after the vehicle has been turned off, also referred to herein as a run-on function. The present invention is based on the object of providing an improved technology for controlling a run-on function of a vehicle. The invention solves this problem by means of the subject matter of the independent claims. Subclaims give preferred embodiments.

According to a first aspect of the present invention, a method for controlling a vehicle comprises steps of determining that the vehicle is parked; and activating a predetermined follow-up function of the vehicle for a predetermined duration. The follow-up function is only activated when there is at least one person on board the vehicle.

It was recognized that the follow-up function cannot be justified if there is no person on board the vehicle. A device for determining whether a person is on board can be present, for example, in the form of a system for detecting seat occupancy. By suppressing the follow-up function, electrical energy can be saved, which can then be available for other purposes on board the vehicle. In particular, an electrical energy storage device that provides electrical energy while the vehicle is parked can be preserved. Another electrical consumer, such as an alarm system or a locking system, can potentially operate for longer thanks to the electrical energy saved.

The vehicle preferably comprises a land vehicle. It is also preferred that the vehicle comprises a motor vehicle, for example a passenger car, a truck, a bus or a commercial vehicle.

The follow-up function can in particular relate to assisting a person when getting in or out of the vehicle. For example, the follow-up function can comprise an interior light or an exterior light, an automatic door, a control element or a display element. Activation of such devices can be dispensed with if no person is on board the vehicle. In one embodiment, the function comprises a comfort function that serves to improve or make the vehicle more comfortable for a person to handle or use.

The run-on function may also include preparing the vehicle for re-use. For example, a receiver for wireless signals of an unlocking mechanism may be active for a predetermined time after the vehicle has been parked.

In one embodiment, the tracking function relates to a consumer mounted outside the vehicle. The tracking function can in particular comprise scanning the surroundings of the vehicle. The consumer can have a scanning device such as a camera, a radar sensor, a LiDAR Sensor or an ultrasonic sensor. Several such sensors can also be attached to the outside of the vehicle. In total, a follow-up function can have a considerable power consumption, in one example around 70 W or more. In particular, if the predetermined duration for the operation of the follow-up function is long, for example in the range of more than 10 minutes, the energy saving can be considerable.

The follow-up function can include controlling a safety function depending on a scan of the environment. The safety function can be passive, in that it only issues a warning, or active, in that it controls an actuator.

The safety function can be designed to prevent a collision between a person getting out and another road user. For example, a radar sensor can be used to determine that a cyclist is approaching who could collide with a person getting out. The person on board the vehicle can be warned about the cyclist, or the cyclist can be warned about the person getting out. In a further embodiment, a collision can be actively prevented, for example by locking the door of the vehicle until the cyclist has passed.

In yet another embodiment, the safety function is designed to mitigate the consequences of a collision between a person getting out and another road user. The safety function can include, for example, an interior or exterior airbag. Other possible actuators include moving vehicle parts.

It is particularly preferred that an already activated follow-on function remains activated when it is determined that the last person leaves the vehicle. However, after the last person leaves the vehicle, the activation of a follow-on function can be prevented.

A remaining duration of the follow-up function can be shortened to a predetermined amount when it is determined that the last person leaves the vehicle. For example, if the follow-up function is required to allow a person to exit the vehicle up to 15 minutes after the vehicle has been switched off, vehicle and it is determined 10 minutes after parking that the last person has left the vehicle, the remaining time can be set from 5 minutes to, for example, 1 minute. The predetermined time can be absolute or determined with reference to the previously applicable time. If the predetermined time is greater than the remaining time, the follow-up function can be switched off when the original time has elapsed.

Determining whether a person is on board the vehicle can be done by means of a sensor system for determining occupancy of seats in the vehicle. The sensor system can be set up to determine for one or more seats on board the vehicle whether a person is on them. In a refinement, the sensor system can, for example, determine whether an adult, a teenager or a toddler is on a seat, whether there is a piece of luggage or a child seat there, whether a child is in a child seat, whether the seat is occupied by a baby seat with or without an infant, or whether, for example, a pet is on a seat. If it cannot be determined that none of the seats in the vehicle are occupied by a person, it can be determined that there is no person on board the vehicle.

The determination can be made on the basis of scans using a large number of sensors in the interior of the vehicle. Example sensors include a seat contact, a camera, an ultrasonic sensor, a LiDAR sensor, a radar sensor or a door contact. The more sensors are provided, the more accurately the seat occupancy can be determined. Redundant information can contribute to increased determination reliability.

The determination can be made on the basis of a model for occupancy. The model can, for example, provide a probability of a seat being occupied by a person. The model can take into account the quality of sensor signals, a match between signals from different sensors or a logical connection. It can be determined that there is no person on board the vehicle if the associated probabilities that a person is present for all known seats are less than a predetermined threshold. A similar consideration can be determined on the basis of confidence. According to a further aspect of the present invention, a control device on board a vehicle comprises means for detecting that the vehicle is parked; means for determining whether a person is on board the vehicle; and means for controlling a follow-on function for a predetermined period after parking; the means being arranged to activate the follow-on function only when at least one person is on board the vehicle.

The control device can comprise a processing device that is designed to partially or completely carry out a method described herein. For this purpose, the processing device can be implemented electronically and can comprise, for example, an integrated circuit, a programmable logic device or a programmable microcomputer. The method can be implemented in the form of a configuration or as a computer program product with program code means for the processing device. The configuration or the computer program product can be stored on a computer-readable data carrier. Features or advantages of the method can be transferred to the device or vice versa.

A control system on board a vehicle comprises a control device as described herein and a safety system which is configured to run for a predetermined period after the vehicle has been turned off. The safety system can provide or control a run-on function as explained herein over the predetermined period.

According to yet another aspect of the present invention, a vehicle comprises a control device described herein and/or a safety system mentioned herein.

The invention will now be described in more detail with reference to the accompanying drawings, in which:

Figure 1 a system; and

Figure 2 is a flow chart of a process illustrated.

Figure 1 shows a control system 100 on board a vehicle 105. The vehicle 105 preferably comprises a passenger car; in other embodiments, however, it may also comprise, for example, a truck or a bus.

The control system 100 comprises a control device 110 with an energy controller 115, a sensor system 120 and a scanning system 125. The sensor system 120 is designed to determine for one or more seats 130 of the vehicle 105 whether a person 135 is present there or not. In the embodiment shown, the sensor system 120 comprises a door contact 140, an occupancy sensor 145 in the area of a seat 130 and a contactless scanning device 150 in the interior of the vehicle 105. The door contact 140 is designed to detect an opening state of a door of the vehicle 105 and/or a request to open or close the door. An occupancy sensor 145 can determine for an assigned seat 130 whether a person 135 is present there or not. The scanning device 150 is preferably contactless and more preferably imaging. By means of the scanning device 150 it can generally be determined whether and, if so, where a person 135 is located on board the vehicle 105.

The sensor system 120 can create a mathematical model based on sensor signals from the sensors 140 to 150, wherein the model can determine a probability that one or more persons 135 are on board the vehicle 105.

The scanning system 125 preferably comprises at least one electrical consumer that is mounted in the exterior of the vehicle 105 or is designed to scan an exterior area. The scanning system 125 can be designed to control a predetermined safety function, in particular to protect a person in the area of the motor vehicle 105 when getting in or out. In the present case, the scanning system 125 comprises exemplary consumers of this type in the form of two scanning devices 155 that are designed to scan an area to the right and left of the vehicle 105. The scanning devices 155 can each comprise, for example, an ultrasonic sensor, a a radar sensor, a LiDAR sensor or a camera. Other sensors or electrical consumers that relate to the exterior of the vehicle 105 are also possible.

The energy control 115 can control the distribution of electrical energy to different consumers or systems on board the vehicle 105. By means of an interface 160, the energy control 115 can be connected to another device on board the vehicle 105, which can provide a signal as to whether the vehicle 105 is in a ready-to-drive or parked state or that it is being parked, i.e. a transition from the ready-to-drive to the parked state. The vehicle 105 is usually parked with the intention of parking. Many systems of the vehicle 105, for example an electric drive system, a ventilation system or an air conditioning system for an interior, can be switched off when the vehicle is parked. A parked vehicle 105 is always at a standstill; however, a vehicle 105 that is stationary, for example at a red light, cannot yet be considered to be parked.

If the vehicle 105 is parked and it is determined by means of the sensor system 120 that at least one person 135 is still on board the vehicle 105, the activation of an electrical sub-network can be requested from the energy control 115. The sub-network can supply the scanning system 125 and in particular one or more scanning devices 155 with electrical energy. The energy control 115 can fulfill the request and leave the electrical sub-network activated for a predetermined period of time, for example approximately 10 minutes. Once the period has elapsed, the electrical sub-network can be deactivated again.

It is proposed to suppress activation of the subnetwork if there is no person 135 on board the vehicle 105.

Figure 2 shows a flow chart of an exemplary method 200 for controlling a vehicle 105. The method 200 can be carried out in particular by means of a control system 100 on board a vehicle 105. In a step 205, it can be detected that the vehicle 105 is parked. In a step 210, the occupancy of seats 130 of the vehicle 105 can be determined. For this purpose, in a step 215, an interior of the vehicle 105 can be scanned, for example by means of the scanning device 150. In a step 220, one or more doors can be monitored, for example by means of a door contact 140. In a step 225, a mathematical model can be formed which can evaluate sensor signals from one or more sensors 140 to 150, as well as check the plausibility of sensor signals against one another, merge them with one another, or combine them with one another. Logical circumstances or structural conditions of the vehicle 105 can be taken into account for this purpose. Steps 215 to 225 can be carried out continuously while the vehicle 105 is ready for operation, and at least for a predetermined period after the vehicle 105 has been parked.

Upon detection of the parking of the vehicle 105 in step 205, activation of an electrical sub-network, which is required to operate the scanning system 125, can be requested in a step 230. In a step 235, it can be determined on the basis of the model of the sensor system 120 whether at least one person 135 is on board the vehicle 105. If this is the case, the requested electrical sub-network can be activated in a step 240. This allows a follow-up function to be controlled in a step 245, which is connected to the electrical sub-network. In the present example, the follow-up function includes a safety function for protecting a person 135 getting out of the vehicle 105. For this purpose, an area around the vehicle 105 can be scanned using the scanning device 155, and a predetermined measure can be taken if there is a risk that a person 135 getting out will collide with another road user in the area around the vehicle 105. The measure may include a warning, active prevention or mitigation of possible accident damage.

In a step 250, it can be checked whether a predetermined period associated with the activation has expired. If this is not the case, it is possible to return to step 245 in order to continue to control the follow-up function. Otherwise, the electrical sub-network can be deactivated in a step 255. In one embodiment, the electrical sub-network can also be deactivated if it was determined in step 235 that there is no person 135 on board the vehicle 105.

If it is detected in a step 260 on the basis of the model of the sensor system 120 that the last person 135 is getting out of the vehicle 105, the remaining duration for an already running follow-up function can be reduced to a predetermined amount in a step 265. If no follow-up function is active at this time, this step can be ineffective. If a follow-up function is active and the remaining duration is less than the predetermined amount in step 265, an adjustment can be dispensed with.

Overall, it can be ensured that a follow-up function intended to serve a person 135 on board or in the area of the parked vehicle 105 cannot be carried out or can be carried out for a short time if it is determined that there is no person 135 on board the vehicle 105. This can save electrical energy that can be available for other purposes.

reference sign

100 tax system

105 vehicles

110 control device

115 Energy Control

120 sensor system

125 scanning system

130 seats

135 people

140 door contact

145 occupancy sensor

150 scanning device

155 scanning device

160 interface

200 procedures

205 Capture: Vehicle is parked

210 Record seat occupancy

215 Scan the interior

monitor 220 doors

225 Model Form

230 Request activation of electrical subnetwork

235 Determine: at least one person on board?

240 Activate electrical subnetwork

245 Control the run-on function

250 duration expired?

255 Disable subnet

260 Capture: last person gets off

265 adjust remaining duration

Claims

claims 1. Method (200) for controlling a vehicle (105), the method (200) comprising the following steps: Detecting (205) that the vehicle (105) is parked; and activating (240) a predetermined follow-up function (125) of the vehicle (105) for a predetermined duration; wherein the follow-up function (125) is only activated when at least one person (135) is on board the vehicle (105). 2. The method (200) according to claim 1, wherein the follow-up function (125) relates to assisting a person (135) when entering or exiting the vehicle (105). 3. The method (200) according to claim 1 or 2, wherein the follow-up function (125) relates to a consumer (155) mounted in the exterior of the vehicle (105). 4. The method (200) of claim 3, wherein the tracking function (125) comprises scanning an environment of the vehicle (105). 5. The method (200) of claim 4, wherein the tracking function (125) comprises controlling a safety function in response to a scanning of the environment. 6. The method (200) according to claim 5, wherein the safety function is designed to prevent a collision of a person (135) getting out of the vehicle with another road user. 7. The method (200) according to claim 5 or 6, wherein the safety function is designed to mitigate the consequences of a collision between an exiting person (135) and another road user. 8. The method (200) according to any one of the preceding claims, wherein an already activated follow-up function (125) remains activated when it is determined that the last person (135) leaves the vehicle (105). 9. The method (200) of any preceding claim, wherein a remaining duration of the follow-up function (125) is shortened (265) to a predetermined amount when it is determined that the last person (135) is leaving the vehicle (105). 10. Method (200) according to one of the preceding claims, wherein the determination of whether a person (135) is on board the vehicle (105) is carried out by means of a sensor system (120) for determining an occupancy of seats (130) of the vehicle (105). 11. The method (200) according to claim 10, wherein the determining is carried out on the basis of scanning by means of a plurality of sensors (140-150) in the interior of the vehicle (105). 12. The method (200) according to claim 10 or 11, wherein the determining is carried out on the basis of a model for the occupancy. 13. Control device (110) on board a vehicle (105), the control device comprising: a device (160) for detecting that the vehicle (105) is parked; a device (120) for determining whether a person (135) is on board the vehicle (105); and a device (115) for controlling a follow-up function (125) for a predetermined period after parking; the device (115) is configured to activate the follow-up function (125) only when at least one person (135) is on board the vehicle (105). 14. Control system (100) on board a vehicle (105), comprising a control device (110) according to claim 13 and a security system (125) which is designed to run for a predetermined period after the vehicle (105) has been parked. 15. Vehicle (105) comprising a control device (110) according to claim 13.