WO2020109387A1 - Operating assembly for a vehicle, vehicle comprising the operating assembly and method for operation using the operating assembly - Google Patents

Abstract

For gesture recognition in motor vehicles, usually cameras are used which can optically detect a gesture of a vehicle occupant, for example. The object of the invention is to create an operating assembly characterised by a simple sensor system. For this purpose, the invention relates to an operating assembly (2) for a vehicle (1) comprising a detection device (6) for detecting a body movement of a vehicle occupant (4), and a control device (9) for controlling a functional unit (3) of the vehicle (1) based on the detected body movement, wherein the detection device (6) has a magnetic field sensor (8), wherein the magnetic field sensor (8) and a magnetic field (M) can be moved relative to one another according to the body movement, such that a detection of the body movement occurs according to the relative movement.

Description

Operating arrangement for a vehicle, vehicle with the operating arrangement and

Procedure for operating with the operating arrangement

The invention relates to an operating arrangement for a vehicle with the features of the preamble of claim 1. Furthermore, the invention relates to a vehicle with the loading operating arrangement and a method for operating a functional unit of the vehicle with the operating arrangement.

Cameras are usually used for gesture recognition in motor vehicles, which can, for example, optically detect a gesture of a vehicle occupant. Thus, individual functions can be selected using certain finger or hand gestures and can be detected or implemented without contact by means of a gesture control.

The publication DE 10 2011 112 275 A1, which probably forms the closest prior art, discloses an operating arrangement for a motor vehicle with a detection device for detecting a gesture from at least one occupant of the motor vehicle, and a control device for controlling a functional unit of the motor vehicle as a function of it from the detected gesture, wherein the detection device is designed to determine a distance from a body part of the at least one occupant, with whom the person performs the gesture, so that the control can be carried out by the control device as a function of the distance.

The invention has for its object to provide an operating arrangement of the type mentioned ge, which is characterized by a simple sensor system.

This object is achieved by an operating arrangement with the features of claim 1, a vehicle with the features of claim 1 1 and a method with the features of claim 12. Advantageous refinements result from the subclaims, the drawings and / or the description. The invention relates to an operating arrangement which is formed and / or suitable for a vehicle. In particular, the operating arrangement serves for the contactless operation of a display and / or operating system of the vehicle.

The vehicle is designed in particular as a motor vehicle, preferably a car, small van (people mover), or truck, with an internal combustion engine, electric drive or hybrid drive.

The operating arrangement has a detection device which is designed and / or suitable for detecting a body movement of at least or exactly one vehicle occupant. In particular, the detection device is used for the contactless detection of the body movement, preferably a finger, hand and / or head movement of the vehicle occupant. The detection device is preferably arranged and / or can be arranged in a passenger compartment of the vehicle. The detection device can be designed as a mobile detection device or alternatively as a stationary detection device, in particular integrated into the vehicle.

The operating arrangement has a control device which is designed and / or suitable for controlling a functional unit of the vehicle on the basis of the detected body movement. The control device is used in particular to evaluate the body movement detected and transmitted by the detection device, the control device preferably controlling the functional unit as a function of the body movement. The detection device can transmit a detected body movement as a sensor signal to the control device. The control device can determine or identify a specific body movement on the basis of the sensor signal and, if necessary, assign it to an associated function. The control device can then transmit a control signal to the functional unit, the functional unit being able to implement a function on the basis of the control signal, in particular as a function of the corresponding body movement. For example, different body movements can be assigned different functions. The functional unit, the control device and the detection device are preferably connected to one another in terms of signal technology. It is proposed within the scope of the invention that the detection device has at least or exactly one magnetic field sensor or is designed as this. In particular, the magnetic field sensor is used to detect a magnetic field, the magnetic field sensor and the magnetic field being movable relative to one another. The magnetic field sensor and the magnetic field can be moved relative to one another depending on the body movement, so that the body movement is detected as a function of the relative movement. In principle, the magnetic field sensor can be moved relative to the magnetic field, the magnetic field in particular remaining stationary. Alternatively, however, it can also be provided that the magnetic field can be moved relative to the magnetic field sensor, the magnetic field sensor remaining stationary. The magnetic field sensor or the magnetic field is preferably coupled to the vehicle occupant so that the relative movement between the magnetic sensor and the magnetic field results directly from the body movement. In particular, the relative movement is a rotational movement and / or a straight movement. Alternatively or optionally in addition, the body movement is a turning, sliding, wiping, pitching and / or tapping movement from which the relative movement results. In particular, the control device serves to determine a movement pattern from the corresponding relative and / or body movement, the functional unit executing a corresponding function on the basis of the determined movement pattern.

The advantage of the invention is in particular that a particularly simple and robust sensor system is proposed by the magnetic field sensor. In addition, there is no need to optically record the body movement, so that the sensors can be produced much more cost-effectively. Another advantage is in particular that the magnetic field sensor requires little space, so that a particularly space-saving arrangement can be realized.

In a possible implementation it is provided that the magnetic field is designed as an earth magnetic field. In particular, a vehicle's own position detection system, for example GPS system, can be used to determine a vehicle position and / or orientation of the vehicle in the earth's magnetic field, during a movement of the vehicle and simultaneous movement of the magnetic field sensor in the Earth's magnetic field is corrected based on the vehicle position and / or orientation. The magnetic field sensor is preferably coupled to the vehicle occupant in motion, the magnetic field sensor being moved relative to the earth's magnetic field during body movement and, if appropriate, a relative movement generated by the moving vehicle being compensated for by the correction.

In an alternative implementation it is provided that the operating arrangement has at least one or exactly one magnet for generating the magnetic field. The magnet can be designed as a permanent magnet or an electromagnet. In particular, the magnet is arranged and / or can be arranged in the passenger compartment, in particular in a detection area of the magnetic field sensor. In particular, the magnet is arranged stationary in the passenger compartment, the magnetic field sensor being motion-coupled to the vehicle occupant. Alternatively, however, the magnet can also be motion-coupled to the vehicle occupant, the magnetic field sensor being arranged stationary in the passenger compartment.

In a preferred embodiment it is provided that the magnetic field sensor is designed to detect a magnetic field vector. In particular, the magnetic field sensor is used to detect at least or exactly two mutually perpendicular field components of the magnetic field. In particular, however, it can also be provided that the magnetic field sensor is designed and / or suitable for detecting exactly three field components that are perpendicular to one another. In particular, the detection device determines the resulting magnetic field vector on the basis of the detected field components.

The control device is designed to detect the body movement on the basis of a change in the magnetic field vector resulting from the relative movement. In particular, the change can be detected as a change in the amount and / or as a change in the orientation of the magnetic field vector. In particular, the change in the magnetic field vector is clearly assigned and / or assignable to a body movement. Based on the change, the type of body movement and / or the movement pattern can be inferred and counteracted. if necessary, a function associated therewith implemented by the functional unit.

In a specific embodiment it is provided that the magnetic field sensor is designed as a Hall sensor (2D sensor) measuring at least or exactly two-dimensionally. Alternatively, however, it can also be provided that the magnetic field sensor is designed as a three-dimensionally measuring Hall sensor (3D sensor). The detection device is in particular designed to evaluate at least two or three linearly independent field components of the magnetic field.

In a preferred embodiment of the invention it is provided that the magnetic field sensor is formed by a plurality of spin valves which are arranged in two Wheatstone bridges for two-dimensional measurement. In particular, the magnetic field sensor has exactly eight of the spin valves, four of the spin valves being integrated in a Wheatstone bridge with orthogonal sensitivity axes. Such an arrangement of the spin valves is already known from the prior art. (see G. Santiago et al., "Magnetosensitive e-skins with directional perception for augmented reality", Sei. Adv. 4, eaao2623 (2018), DOI: 10.1126 / sciadv.aao2623)

In a specific embodiment it is provided that the spin valves are applied to a film. In particular, the film has a film thickness of in particular less than 2 pm and / or more than 1.5 pm. The film is preferably designed as a plastic film, in particular based on polyimide. Optionally, at least one further film can be provided, the film and the at least one further film together forming the film. For this purpose, the two foils are placed one above the other in layers and, for example, integrally connected to one another. In particular, the spin valves are arranged in a sensor layer or designed as this, the sensor layer being applied to the film. The sensor layer can have a layer thickness of in particular less than 30 nm and / or more than 25 nm. A protective layer can optionally be additionally applied to the film and / or the sensor layer. In particular, the spin valves are covered and / or embedded by the protective layer. The protective layer can be formed from polydimethylsiloxane (PDMS). The protective layer can have a layer thickness of less than 7 mhi and / or more than 3 gm. The magnetic field sensor, in particular the film, the sensor layer and / or the protective layer, particularly preferably has a total thickness of less than 10 gm, preferably less than 8 gm, in particular less than 6 gm. The magnetic field sensor is thus preferably designed as a flexible sensor film. Such an embodiment is already known from the prior art (cf. G. Santiago et al., "Magnetosensitive e-skins with directional perception for augmented reality", Sci. Adv. 4, eaao2623 (2018), DOI:

10.1126 / sciadv.aao2623)

In a further embodiment it is provided that the magnetic field sensor or the magnet can be arranged on a body part of the occupant with which the occupant performs the body movement, so that when the body part moves, the magnetic field sensor and the magnetic field can be moved and / or moved relative to one another. In principle, the magnet or the magnetic field sensor can be self-adhesive and / or can be arranged directly on the body part. In particular, the magnetic field sensor is designed as a self-adhesive sensor film. Alternatively, the magnet or the magnetic field sensor can be arranged or integrated on an object that can be worn on the body part. The magnetic field sensor or the magnet can preferably be arranged on an arm, in particular a wrist, palm and / or finger, or on the head of the vehicle occupant.

In a further specification, it is provided that the operating arrangement has an accessory that can be worn on the body part, the magnetic field sensor or the magnet being arranged and / or arrangeable on the accessory. In particular, the accessory can be designed as a wearable, such as, in particular, a bracelet, a wristwatch, in particular a special smart watch, in particular smart glasses, glasses, or a glove. The magnetic field sensor or the magnet can be integrated into the accessory, for example by the manufacturer. Alternatively, the magnetic field sensor or the magnet can be retrofitted to the accessory. For this purpose, for example, the magnetic field sensor or the magnet can be fixed to the accessory with a material fit and / or a force fit and / or a form fit. In particular, the sensor film can be self-adhesive, whereby the sensor film can be glued to the accessory. Another object of the invention relates to a vehicle with the Betriebsanord voltage according to one of the preceding claims or as this has been previously described be. The vehicle has the control device and the functional unit. In particular, the functional unit can be designed and / or suitable for operating and / or for displaying a function of the vehicle. The functional unit is preferably designed as an infotainment system, an on-board computer or a control device. The detection device is connected in terms of signal technology to the control device in order to determine the body movement. In particular, the detection device can be connected and / or connected to the control device via a radio link, in particular via Bluetooth. Alternatively, the detection device and the control device can, however, also be arranged together on a printed circuit board via at least one conductor track.

Depending on the configuration, either the magnetic field sensor or the magnet can be designed as a separate component of the operating arrangement that can be moved by the body movement. In addition to this, the magnetic field, in particular the magnet, or the magnetic field sensor can be designed as a stationary component of the operator control. The stationary component can, for example, in a center console, dashboard, vehicle frame - e.g. in the A-pillar - or a rear-view mirror of the vehicle integrated or arranged on this. Alternatively or optionally in addition, the stationary component or a further stationary component in a rear of the vehicle, for example driver and / or passenger seat, or vehicle frame - e.g. in the B-pillar - integrated into the vehicle or arranged on it.

Another object of the invention relates to a method for operating the functional unit of the vehicle with the operating arrangement as described above.

The magnetic field sensor and the magnetic field are moved relative to one another by at least one occupant of the vehicle during a body movement. This can the magnetic field sensor can be moved depending on the body movement in the magnetic field, the magnetic field remaining stationary. Alternatively, however, the magnetic field can also be moved as a function of the body movement relative to the magnetic field sensor, the magnetic field sensor remaining stationary.

The body movement is detected as a function of the relative movement by the detection device. In particular, the detection device detects the movement in a defined detection area. For example, this detection area can be defined by an area selected in the passenger compartment, in particular in the vicinity of the functional unit.

The functional unit is then controlled by the control device as a function of the detected body movement. In particular, the control device can compare the detected body movement with a selection of stored movement patterns, the functional unit being activated if there is a match with a corresponding movement pattern. A function can be linked to a predefined movement pattern. For example, a wiping hand movement as the body movement may be linked to a menu selection as the function.

In a preferred implementation it is provided that the detection device detects a magnetic field vector of the magnetic field, a change in the magnetic field vector being detected by the magnetic field sensor during the relative movement. Here, a rotational movement can be detected, for example, as a change in the orientation of the magnetic field vector by the magnetic field sensor. Alternatively or optionally additionally, a straight movement, in particular a tipping or wiping movement, can be detected by the magnetic field sensor as a change in the orientation of the magnetic field vector and / or as a change in the amount of the magnetic field vector.

The control device then determines the body movement on the basis of the changed magnetic field vector, so that the functional unit is activated as a function of the determined body movement. For example, the tax device determine the body movement using an arctan function. In particular, a certain body movement, especially one

According to the stored movement pattern, a predetermined function is carried out by the functional unit.

Further features, advantages and effects of the invention result from the following description of a preferred embodiment of the invention as well as the attached figures. These show:

Figure 1 is a highly schematic representation of a vehicle with a control arrangement as an embodiment of the invention.

Figures 1a, b each show a highly schematic representation of a driving tool 1 with an operating arrangement 2, which is used for contactless operation, also known as gesture recognition, a functional unit 3 of vehicle 1 by a vehicle occupant 4. For example, the vehicle 1 is a motor vehicle or alternatively a rail, land, water and / or aircraft. The functional unit 3 is designed as a display and / or operating system and arranged on a dashboard 5 of the vehicle 1. For example, the functional unit 3 can be designed as an infotainment system of the vehicle 3.

The operating arrangement 2 has at least one detection device 6 for detecting a body movement of the vehicle occupant 4. Furthermore, the operating arrangement 2 comprises at least one magnet 7 for generating a magnetic field M, here exemplarily represented by a few field lines. The magnet 7 is formed, for example, as a permanent magnet, the magnetic field M generated being at least 5 mT in size, for example. The detection device 6 has a magnetic field sensor 8, which detects a magnetic field vector V, here only exemplified by an arrow, of the magnetic field M. For example, the magnetic field sensor 8 can be designed as a two- or three-dimensional Hall sensor. In the case of a relative movement between the magnetic field sensor 8 and the magnetic field M, depending on the type of body movement, a change in the magnetic field vector V can be caused, for example, by a change in the orientation and / or by a change of the amount of the magnetic field vector V can be detected. For example, the magnetic field sensor 8 is formed by a plurality of spin valves attached to a film, which are arranged in two Wheatstone bridges for two-dimensional measurement. For example, the magnetic field sensor 8 thus formed has a total thickness of approximately 6 pm and can be configured flexibly. As a result, the magnetic field sensor 8 has a significantly reduced installation space.

The operating arrangement 2 has a control device 9, wherein the detection device 6 is signal-technically connected to the control device 9, indicated by dashed lines. The control device 9 uses the detected change in the magnetic field vector V to determine a body movement of the vehicle occupant 4. The body movement is detected exclusively in a defined measuring range in which the detection device 6, for example, still detects a sufficiently high field strength of the magnetic field M. The control device 9 can evaluate the change in the magnetic field vector V detected by the magnetic field sensor 8 and determine an associated body movement. The functional unit 3 is then activated by the control device 9, the functional unit 3 outputting a function as a function of the determined body movement. For example, the body movement is turning a virtual rotary controller e.g. for setting the volume as a function of the information system or pressing a virtual button e.g. to answer a phone call as another function of the infotainment system. Alternatively or optionally in addition, the functional unit 3 can, however, also provide further facilities, such as a start button, a sunroof, a hazard lights, a vehicle window, a vehicle door, etc. can be controlled.

In FIG. 1a, the detection device 6 is arranged on a body part 4a, b of the vehicle occupant 4 which guides the body movement, the detection device 6 being moved relative to the magnet 7 in the magnetic field M when the body part 4a, b is moved. The detection device 6 is designed as a mobile detection device and can, for example, also be worn on the body of a person outside the vehicle 1. For example, the Detection device 6 can be connected to the control device 9 via Bluetooth.

In a first possible embodiment variant, the detection device 6 can be arranged on an arm 4a of the vehicle occupant 4. The movement of the body is controlled by a hand or finger movement, e.g. Wiping, tapping, rotating movement, generated and detected within the magnetic field M by the detection device 6. For example, the detection device 6 is in an accessory that can be carried on the arm 4a, e.g. Wristwatch, smartwatch, bangle, glove etc. integrated. In this first arrangement variant, the magnet 7 is arranged in or on the dashboard 5 or alternatively a center console of the vehicle 3, the detection area being defined in particular as a front area of the dashboard 5 and / or the functional unit 3.

In a second possible embodiment variant, the detection device 6 can be arranged on a head 4b of the vehicle occupant 4. The body movement is determined by a head movement, e.g. Pitch or rotational movement, generated and detected within the magnetic field M by the detection device 6. For example, the detection device 6 is in an accessory soire, e.g. Glasses, integrated. In this second arrangement variant, the magnet 7 can be in or on the vehicle body 10, e.g. Vehicle headlining, A-pillar, etc., or alternatively the rear view mirror, the detection area is in particular defined as a roof area of the passenger compartment.

In FIG. 1b, the magnet 7 is arranged and / or can be arranged on the body part 4a of the vehicle occupant 4 which executes the body movement, the magnet 7 being moved with its magnetic field M relative to the detection device 6 when the body part 4a is moved. The detection device 6 is designed as a stationary detection device and permanently installed in the vehicle 1, in particular the dashboard 5 or the center console etc. For example, the detection device 6 and the control device 9 can be arranged together on a circuit board and connected to one another in terms of signal technology. In the exemplary embodiment shown, the magnet 7 can also be arranged on the arm 4a or alternatively on the head 4b of the vehicle occupant 4. The body movement is generated by a hand or finger movement, for example wiping, tapping, rotating movement, and detected within a detection area of the detection device 6. For example, the magnet 7 is integrated in the accessory 4, such as a wristwatch, smartwatch, bangle, glove, etc., on the arm 4a.

Bezuaszeichen

1 vehicle

2 operating arrangement

3 functional unit

4 vehicle occupants

4a, b body parts

5 dashboard

6 detection device

7 magnet

8 magnetic field sensor

9 control device

10 vehicle body

M magnetic field

V magnetic field vector

Claims

Claims

1. Operating arrangement (2) for a vehicle (1)

with a detection device (6) for detecting a body movement of a vehicle occupant (4),

with a control device (9) for controlling a functional unit (3) of the vehicle (1) on the basis of the detected body movement,

characterized in that

the detection device (6) has a magnetic field sensor (8), the magnetic field sensor (8) and a magnetic field (M) being movable relative to one another as a function of the body movement, so that the body movement is detected as a function of the relative movement.

2. Control arrangement (2) according to claim 1, characterized in that the magnetic field (M) is designed as an earth's magnetic field.

3. Control arrangement (2) according to claim 1, characterized by a magnet (7) for generating the magnetic field (M).

4. Control arrangement (2) according to one of the preceding claims, characterized in that the magnetic field sensor (8) is designed to detect a magnetic field vector (V) of the magnetic field (M), the control device (9) for determining the body movement on the basis one resulting from the relative movement is the change in the magnetic field vector (V).

5. Operating arrangement (2) according to one of the preceding claims, characterized in that the magnetic field sensor (8) is designed as an at least two-dimensionally measuring Hall sensor.

6. Operating arrangement (2) according to one of the preceding claims, characterized in that the magnetic field sensor (8) is formed by a plurality of spin valves which are arranged for two-dimensional measurement in two Wheatstone bridges.

7. Operating arrangement (2) according to claim 6, characterized in that the several ren spin valves are applied to a film.

8. Control arrangement (2) according to one of the preceding claims, characterized in that the magnetic field sensor (8) or the magnet (7) on a body part (4a, b) of the vehicle occupant (4) with which the body movement can be arranged , so that when the body part (4a, b) moves, the magnetic field sensor (8) can be moved in the magnetic field (M).

9. Operating arrangement (2) according to claim 8, characterized in that the detection device (6) is designed as an accessory that can be worn on the body part (4a, b), the magnetic field sensor (8) being arranged on the accessory.

10. Control arrangement (2) according to claim 8, characterized in that the control arrangement (2) has an accessory that can be worn on the body part (4a, b), the magnet (7) being arranged on the accessory.

11. Vehicle (1) with the control arrangement (2) according to one of the preceding claims, characterized in that the vehicle (1) has at least the control device (9) and the functional unit (3), and wherein the detection device (6 ) is connected to the control device (9) for determining the body movement.

12. A method for operating a functional unit (3) of the vehicle (1) according to claim 10 with the operating arrangement (2) according to one of claims 1 to 9 in which:

- With a body movement of at least one vehicle occupant (4) of the vehicle (1), the magnetic field sensor (8) and the magnetic field (M) are moved relative to one another;

- The body movement depending on the relative movement is detected by the magnetic field sensor (8);

- The functional unit (3) is controlled as a function of the detected body movement by the control device (9).

13. The method according to claim 12, characterized in that the magnetic field sensor (8) detects a magnetic field vector (V) of the magnetic field (M), a change in the magnetic field vector (V) being detected during the relative movement and the control device (9) on the basis the change determines the body movement, and control of the functional unit (3) by the control device (9) takes place as a function of the determined body movement.