WO2021190931A1

WO2021190931A1 - Device for interaction with a user device

Info

Publication number: WO2021190931A1
Application number: PCT/EP2021/056047
Authority: WO
Inventors: Philipp Kleinlein; Philip Koene; Frank Schaefer; Christoph SÖLLNER
Original assignee: BSH Hausgeräte GmbH
Priority date: 2020-03-26
Filing date: 2021-03-10
Publication date: 2021-09-30
Also published as: DE102020203917A1

Abstract

The invention relates to a device (110) for interaction with a user device (120). The device (110) comprises a holder (116) for a user device (120). The device (110) further comprises a sensor unit (112) which is designed to generate a light curtain (113), and to detect sensor data in relation to whether the light curtain (113) is penetrated by an object (130). The device (110) also comprises a control unit (111) which is configured to produce, on the basis of the sensor data, an operator input on the user device (120) inserted in the holder (116).

Description

Device for interaction with a user device

The invention relates to a device which enables a user to interact comfortably and reliably with a mobile user device, in particular in the kitchen environment.

Mobile user devices, in particular smartphones and / or tablet PCs, are also increasingly used in the kitchen environment, e.g. to access recipes from a recipe database, to play videos with cooking tips and / or to communicate via social networks. Interaction with a mobile user device is often difficult because a user has damp or dirty fingers during a cooking process. The use of a mobile user device in the kitchen environment is therefore often not very convenient and / or not reliable.

This document deals with the technical task of increasing the convenience and reliability when using a mobile user device in a kitchen environment.

The object is achieved by the subject matter of the independent claim. Advantageous embodiments are defined in particular in the dependent claims, described in the following description or shown in the accompanying drawing.

According to one aspect of the invention, a device for interacting with a user device, in particular with a smartphone and / or a tablet PC, is described. The user device can have a (possibly touch-sensitive) screen. The device can comprise a base with which the device can be placed on a storage surface, for example on the worktop of a kitchen.

The device comprises a holder for a user device. The holder can, for example, comprise a recess in the base into which a user device can be placed. The holder can be designed in such a way that the user device is held at an angle between 20 ° and 80 ° relative to the storage surface (so that the screen of the user device can be seen well for a user who is arranged in front of the storage area).

The device can comprise a communication unit which is designed to communicate with the user device inserted in the holder via a wireless and / or wired communication connection, in particular via Bluetooth and / or WLAN (Wireless Area Network). If necessary, data for controlling the user device can be sent from the device to the user device. Furthermore, data, in particular device data for calibration, can be sent from the user device to the device.

The device can comprise a power supply unit which is designed to supply the electronic components of the device (in particular a sensor unit and / or a control unit) with power from an electrical supply network. Furthermore, the device can comprise a charging device for charging the user device inserted into the holder. A particularly convenient interaction with the user device can thus be made possible for a user.

The device comprises a sensor unit which is designed to generate a (two-dimensional) light curtain. The sensor unit can be designed to generate a light curtain that primarily or exclusively comprises light in the infrared range.

Furthermore, the sensor unit is set up to record sensor data with regard to whether the light curtain is pierced by an object (for example by a finger of a user). This can in particular be recognized based on light from the light curtain that is reflected on the object back to the sensor unit. The sensor unit can in particular be set up to acquire sensor data in relation to a curtain position at which the light curtain is pierced by an object. The curtain position can indicate the penetration position within the two-dimensional light curtain (for example the x coordinate and the y coordinate within the surface of the light curtain). The curtain position can in particular be determined on the basis of the intensity of the light reflected on the object. The device further comprises a control unit which is set up to effect an operator input on the user device inserted in the holder on the basis of the sensor data. In particular, the control unit can be set up to effect an operator input that is dependent on the curtain position on the user device inserted in the holder. For this purpose, data relating to the curtain position can be sent from the control unit to the user device via the communication link.

The device thus enables a user to operate a user device in that a light curtain produced by the device is pierced at different curtain positions (without touching the user device in the process). In this way, comfortable and reliable interaction with a user device can also be achieved in the kitchen area.

The sensor unit can be set up to generate the light curtain at a certain distance (e.g. between 1 cm and 6 cm, approximately 5 cm) in front of the screen of the user device inserted in the holder. The light curtain can be generated in such a way that the light curtain is arranged in a plane which runs parallel to the screen plane of the screen. The light curtain preferably completely covers the screen of the user device.

Such an arrangement of the light curtain enables virtual touch operation of the user device. In particular, it can be made possible for a user of the device to pierce the light curtain at different curtain positions in order to effect corresponding touch inputs on the screen of the user device which is arranged behind the light curtain. In this way, the convenience and the reliability of the interaction with the user device can be further increased.

The device can comprise a protective surface (for example a protective glass) which is arranged between the light process and the screen of the user device inserted in the holder. The protective surface can be designed to prevent an object penetrating the light curtain from the screen of the inserted into the holder User device touched. In this way, the comfort and reliability of the interaction with the user device can be further increased.

The control unit can be set up to associate a detected curtain position (at which an object has penetrated the light curtain) with a corresponding touch position on the screen of the user device inserted in the holder. This can be done, for example, on the basis of an assignment between curtain positions and contact positions, which was determined in the course of a calibration phase of the device.

Furthermore, the control unit can be set up to effect an operator input on the user device inserted in the holder, which corresponds to a direct touch of the screen of the user device at the touch position. As an alternative or in addition, the control unit can be set up to cause the user device to be operated as if the screen had been touched directly at the touch position. A particularly convenient and reliable (virtual touch) interaction with the user device can be made possible through an assignment or association between curtain positions and corresponding touch positions (without the screen of the user device being touched in the process).

In order to calibrate the device and / or in a calibration phase of the device, the control unit can be set up to request a user to touch at least one specific point on the screen of the user device inserted in the holder with a finger. A curtain position can then be determined on the basis of the sensor data from the sensor unit when the point on the screen is touched at which the user's finger has pierced the light curtain. The determined curtain position can then be associated with the touch position of the screen corresponding to the specific point on the screen. In this way, an association between curtain positions and corresponding touch positions can be determined in a particularly efficient manner in order to enable precise and reliable interaction with the user device.

Furthermore, the control unit can be set up to provide device data with regard to the size and / or the dimensions of the screen and / or with regard to the orientation (e.g. landscape or portrait) of the user device inserted in the holder. The device data can in particular be received by the user device via the communication link.

On the basis of the device data (and on the basis of the calibration phase described above with the involvement of the user), a precise assignment between different curtain positions at which an object can penetrate the light curtain and corresponding contact positions at which the screen of the user device can be made can be touched. Based on the assignment, a particularly precise and reliable interaction with the user device can then be made possible.

As an alternative or in addition, the sensor unit can be set up to generate a light curtain that runs parallel to the shelf on which the device stands. Such a light curtain can be used for efficient and precise cursor or mouse operation of the user device.

The control unit can be set up to determine, on the basis of the sensor data from the sensor unit, a curtain position and / or a change in the forehand position at which the object penetrates the light curtain. It can then be effected that the position of a cursor displayed on the screen of the user device is set and / or changed as a function of the curtain position. Furthermore, if necessary, on the basis of the sensor data of the sensor unit, a double penetration of the light curtain can be detected. This can be interpreted as a double click (as with mouse operation) and implemented as an operator input from the user device. In this way, a comfortable and reliable interaction with the user device can be made possible (in particular without a calibration being necessary for this).

The sensor unit can be arranged on the device so that it can pivot about a pivot axis, so that in a first position of the sensor unit a light curtain is generated which extends essentially parallel to the screen surface of the user device inserted in the holder, and so in a second position of the sensor unit a light curtain is generated which extends essentially parallel to the shelf on which the device is placed. The control unit can be set up to determine whether the sensor unit is in the first position or in the second position. This can be recognized, for example, by means of a sensor arranged on the pivot axis. Furthermore, the control unit can be set up to effect virtual touch operation of the user device inserted in the holder on the basis of the sensor data of the sensor unit when it is determined that the sensor unit is in the first position. Alternatively or additionally, the control unit can be set up to effect cursor and / or mouse operation of the user device inserted in the holder on the basis of the sensor data from the sensor unit when it is determined that the sensor unit is in the second position. The automatic detection of the alignment of the light curtain can further improve the convenience and reliability of the interaction with the user device.

It should be noted that all aspects of the device described in this document can be combined with one another in diverse ways. In particular, the features of the claims can be combined with one another in many ways.

The invention is described in more detail below with reference to the exemplary embodiments shown in the accompanying drawing. Show it

FIGS. 1a and 1b show an exemplary device for interacting with a mobile user device; and

FIG. 2 shows the screen of an exemplary mobile user device.

As stated at the outset, the present document deals with increasing the convenience and reliability of the interaction with a mobile user device in a kitchen environment. In this context, FIGS. 1a and 1b show an exemplary mobile user device 120 (for example a smartphone or a tablet PC) which has a (typically touch-sensitive) screen on which a pictorial representation is shown. The pictorial representation can include, for example, one or more symbols for applications that can be touched by a user in order to execute the respective application. Furthermore, the pictorial representation can include a search field into which text for a search query can be entered. The mobile user device 120 can thus comprise a touch-sensitive screen via which a user interface of the user device 120 is provided. The mobile user device 120 can be used in the kitchen environment, for example to play a video with cooking tips and / or to search for a recipe from a recipe database. Since the user often has dirty and / or wet fingers when cooking, the interaction with the mobile user device 120 can turn out to be uncomfortable and / or unreliable.

1a shows a (holding) device 110 for a user device 120, the holding device 110 having a base 118 with which the holding device 110 can be placed on a storage surface 140, for example on the worktop of a kitchen. The holding device 110 shown in FIG. 1 a comprises a holder 116 which is designed to hold the user device 120, in particular in such a way that the screen of the user device 120 can be conveniently viewed by a user. For example, the holder 116 can be designed to hold the user device 120 at an angle between 20 ° and 80 ° relative to the base 118 and / or relative to the shelf 140, so that the user device 120 is arranged at an angle to the shelf 140. In the example shown, the holder 116 comprises a recess within the base 118 in which the user device 120 can be placed.

The holding device 110 comprises a sensor unit 112 which is set up to generate a two-dimensional light curtain 113. The light curtain 113 may comprise light in the infrared (IR) range or consist of light in the IR range. The light curtain 113 can be designed such that the light curtain 113 has the size of the (touch-sensitive) screen of the user device 120 and / or that the light curtain 113 (completely) covers the screen of the user device 120.

The sensor unit 112 can be designed (as shown in FIG. 1 a) to generate a light curtain 113 which runs essentially parallel to the screen of the user device 120 (for example at a distance of 5 cm or less, or 1 cm or less, from the screen ). Furthermore, the sensor unit 112 can be designed to detect sensor data with regard to whether the light curtain 113 is passing through at least one object 130 is pierced, in particular by one or more fingers of a user.

A control unit 111 of the device 110 can be set up to detect, on the basis of the sensor data of the sensor unit 112, that the light curtain 113 is pierced by an object 130, in particular by a finger of a user. Furthermore, the control unit 111 can be set up to determine, on the basis of the sensor data from the sensor unit 112, the curtain position 131 at which the object 130 penetrates the light curtain 113. The curtain position 131 (at which an object 130 penetrates the light curtain 113) can be associated with a touch position 121 on the screen of the user device 120. This association or this assignment can have been determined in the context of a calibration of the device 110 together with the user device 120.

The control unit 111 can be set up to send the sensor data of the sensor unit 112 and / or data relating to the recognized curtain position 131 and / or data relating to the determined contact position 121 via a communication unit 117 of the device 110 to the user device 120 to send. The data can be sent to the user device 120 in a wired or wireless manner (e.g. via Bluetooth or WLAN).

The data sent to the user device 120 with regard to the detected penetration of the light curtain 113 can be used as an operating input of the user device 120. In particular, the device 110 can cause the user device 120 to be operated by piercing the light curtain 113 at the curtain position 131 as if the user had touched the screen of the user device 120 at the corresponding touch position 121. In this way, comfortable and reliable interaction with a user device 120 can also be made possible in a kitchen environment.

As shown in FIG. 1 a, the device 110 can comprise a protective surface 115 (for example a protective glass) which is arranged between the light curtain 113 and the screen of the user device 120. The protective surface 115 can reliably prevent a user from having a Finger 130 touches the screen of user device 120 (and possibly soils the screen in the process). By providing a protective surface 115, the convenience and reliability of the interaction with a user device 120 can be further improved.

The sensor unit 112 can be arranged on the device 110 in such a way that the alignment of the light curtain 113 can be changed. For example, as shown in FIG. 1 a, the sensor unit 112 can be fastened to the device 110 such that it can pivot about a pivot axis 114, in particular in such a way that the angle of the light curtain 113 can be changed relative to the shelf 114. The pivot axis 114 can run parallel to a side edge of the user device 120. By providing a pivotable sensor unit 112, the alignment of the light curtain 113 can be adapted to the respective alignment of the screens of different types of user devices 120.

Furthermore, the sensor unit 112 can be arranged on the device 110 in such a way that the light curtain 113 generated by the sensor unit 112, as shown in FIG. 1 b, can be aligned parallel to the storage area 140. In this case, the light curtain 113 can form a virtual touchpad on the shelf 140. In particular, it can be made possible for a user to slide his finger 130 over the storage surface 140 and, in doing so, to pierce the light curtain 113 at different curtain positions. The control unit 111 of the device 110 can cause the position of a pointer or a cursor on the screen of the user device 120 to be changed in a manner corresponding to the change in the curtain position. It is also conceivable that the sensor unit 112 is installed multiple times in or on the device 110 such that a first sensor unit 112 is mounted in the front as shown in FIG 112 is mounted as in Fig. 1a.

The device 110 can thus be designed to enable virtual touch operation of a user device 120 and / or a mouse or touchpad operation of the user device 120. The control unit 111 of the device 110 can be designed to determine whether the sensor unit 112 is used to generate a light curtain 113 which is arranged parallel to the screen of the user device 120, or To generate a light curtain 113 which is arranged parallel to the storage area 140. This can be detected, for example, using a sensor (not shown) on the pivot axis 114. If a light curtain 113 is generated parallel to the screen, virtual touch operation of the user device 120 can automatically be enabled. If, on the other hand, a light curtain 113 is generated parallel to the storage area 140, a mouse or cursor operation of the user device 120 can automatically be made possible.

The control unit 111 of the device 110 can be designed to start a calibration when the device 110 is started up (as shown by way of example in FIG. 2). For this purpose, the user can, if necessary, be requested to remove the protective surface 115. Furthermore, the user can be requested to pierce the light curtain 113 at one or more different curtain positions 131 with the finger 130 and thereby also to touch the screen 220 of the user device 120 (at the corresponding one or more different touch positions 121). This makes it possible to associate a curtain position 131 directly with a corresponding touch position 121, and thus to calibrate the device 110 for the respective user device 120 and / or for the current position of the user device 120 in the holder or receptacle 116.

In this document, a docking station 110 (i.e. a holder) for a user device 120 is thus described. The docking station 110 has a sensor unit

112 (e.g. a zForce sensor from Neonode), which enables contactless interaction with the user device 120. The sensor unit 112 is designed to generate a light curtain 113 in a specific plane (which is arranged, for example, parallel to the screen plane of the user device 120). On the basis of the light from the light curtain 113 reflected back to the sensor unit 112, it can be detected that an object 130 has been introduced into the light curtain 113. Furthermore, the curtain position 131 of the object 130 can be within the plane of the light curtain

113 (in particular the x-coordinate and the y-coordinate within the plane of the light curtain 113). If necessary, several objects 130 can also be detected, so that multi-touch operation of a user device 120 is made possible. The light curtain 113 generated by the sensor unit 112 is arranged at a certain distance (eg 5 cm) in front of the screen 220 of the user device 120. The arrangement at a certain distance can ensure that the penetration of the light curtain 113 is detected in a certain time interval before touching the screen 220 of the user device 120 (and thus the user has no reason to actually touch the screen 220 of the user device 120 ).

The docking station 110 can be equipped in such a way that a user device 120 is placed on the holder 116 of the docking station 110 in a portrait mode and / or in a landscape mode. The holder 116 can be designed in such a way that different user devices 120 of different sizes can be placed in the holder 116.

The docking station 110 can comprise a charging device for charging a user device 120 arranged in the holder 116 (e.g. charging via a charging cable and / or inductive or wireless charging). A charging cable can, if necessary, be permanently mounted on the docking station 110 or integrated in an exchangeable manner.

The user device 120 can comprise a position sensor which is designed to determine the position or the orientation of the user device 120 (e.g. portrait or landscape or portrait or landscape format). The control unit 111 of the holding device 110 can be designed to obtain this device data from the user device 120 via the communication connection. The device data can then be used to calibrate the sensor unit 112.

The holding device 110 can be designed to determine the size and / or the position of the screen 220 of the user device 120. For this purpose, if necessary, a database with possible user devices 120 can be accessed, from which the information relating to the size and / or the position of the screen 220 of the user device 120 can be determined. If necessary, the size of the screen 220 of the user device 120 can also be determined via communication directly with the user device 120. As an alternative or in addition, the holding device 110 can comprise one or more sensors (not shown) which are designed to measure the size and / or the position of the screen 220 of the user device 120. So can a precise calibration of the holding device 110 for a specific user device 120 can be effected.

Alternatively or in addition, the user can be involved in the calibration process. For example, the user can be prompted to touch a specific point on the screen 220 of the user device 120. The curtain position 131 recognized when the screen 220 is touched can then be equated with the position of this point. Furthermore, the size of the screen 220 can be determined from device data relating to the user device 120. Calibration can thus be performed efficiently with a single touch.

It is also conceivable that the user only pierces a specific point on the light curtain 113 with an object 130. The control unit 111 transmits the position of the object 130 to the user device 120. The user device 120 can then correlate the transmitted coordinates of the object 130 (which are provided by the control unit 111) with the coordinates at which the operating element was displayed on the screen 220. By correlating the operating element displayed on the screen 220 (which is to be touched by the user) and the recognized curtain position 131 of the light curtain 113, the light curtain 113 can be calibrated with the current position of the user device 120 in the receptacle or holder 116. For example, in order to calibrate the device 110, the user can be requested to confirm a dialog box displayed on the screen 220 of the user device 120 with “OK” (i.e. by touching the dialog box) when starting a user application on the user device 120.

If more than one point is used for calibration in the manner described, the size of the screen 220 can also be calibrated without having to access a database of housing sizes of user devices. In other words, a (virtual) touch at several positions on the screen 220 of a user device 120 can thus be used for calibration, in particular to also determine or calibrate the size of the screen 220 of the user device 120. The measures described in this document enable a user of a user device 120 to interact with the user device 120 in a comfortable and reliable manner even in a kitchen environment.

The present invention is not restricted to the exemplary embodiments shown. In particular, it should be noted that the description and the figures are only intended to illustrate the principle of the proposed device.

Claims

PATENT CLAIMS

1. Apparatus (110) for interacting with a user device (120); wherein the device (110) comprises,

- A holder (116) for a user device (120);

- A sensor unit (112) which is designed,

- to generate a light curtain (113); and

- to detect sensor data in relation to whether the light curtain (113) is pierced by an object (130); and

- A control unit (111) which is set up to effect an operator input on the user device (120) inserted in the holder (116) on the basis of the sensor data.

2. Device (110) according to claim 1, wherein

- the sensor unit (112) is set up to acquire sensor data in relation to a curtain position (131) at which the light curtain (113) is pierced by an object (130); and

- The control unit (111) is set up to effect an operator input, which is dependent on the curtain position (131), on the user device (120) inserted in the holder (116).

3. Device (110) according to one of the preceding claims, wherein

- The user device (120) has a screen (220); and

- The sensor unit (112) is set up to generate the light curtain (113) at a certain distance in front of the screen (220) of the user device (120) inserted in the holder (116), in particular such that the light curtain (113) is in a Plane is arranged which runs parallel to a screen plane of the screen (220).

4. Device (110) according to claim 3, wherein - The device (110) comprises a protective surface (115) which is arranged between the light process (113) and the screen (220) of the user device (120) inserted in the holder (116); and

- The protective surface (115) is designed to prevent an object (130) penetrating the light curtain (113) from touching the screen (220) of the user device (120) inserted in the holder (116).

5. Device (110) according to one of claims 3 to 4, wherein the control unit (111) is set up

- on the basis of the sensor data of the sensor unit (112) to determine a curtain position (131) at which the object (130) penetrates the light curtain (113);

- Associate the curtain position (131) with a corresponding touch position (121) on the screen (220) of the user device (120) inserted in the holder (116); and

to effect an operating input on the user device (120) inserted in the holder (116), which corresponds to a direct touch of the screen (220) of the user device (120) at the touch position (121); and or

- To cause the user device (120) to be operated as if the screen (220) were directly touched at the touch position (121).

6. Device (110) according to one of claims 3 to 5, wherein the control unit (111) is set up to calibrate the device (110),

- requesting a user to touch at least one specific point on the screen (220) of the user device (120) inserted in the holder (116) with a finger (130);

- on the basis of the sensor data of the sensor unit (113) to determine a curtain position (131) when touching the point on the screen (220) at which the finger (130) of the user has pierced the light curtain (113); and

- to associate the determined curtain position (131) with a touch position (121) of the screen (220) corresponding to the specific point on the screen (220).

7. Device (110) according to one of claims 3 to 6, wherein the control unit (111) is set up

- to determine device data in relation to a size of the screen (220) and / or in relation to an orientation of the user device (120) inserted in the holder (116), in particular to receive it from the user device (120); and

- an association between different curtain positions (131) at which an object (130) can penetrate the light curtain (113) and corresponding touch positions (121) at which the screen (220) of the user device (120) are touched can be determined on the basis of the device data.

8. Device (110) according to one of the preceding claims, wherein

- The device (110) comprises a base (118) with which the device (110) can be placed on a storage surface (140); and

- The sensor unit (112) is set up to generate a light curtain (113) which runs parallel to the storage area (140).

9. The device (110) according to claim 8, wherein the control unit (111) is set up

- on the basis of the sensor data of the sensor unit (112) to determine a curtain position (131) and / or a change in the forehand position (131) at which the object (130) penetrates the light curtain (113); and

to cause a position of a cursor displayed on a screen (220) of the user device (120) to be set and / or changed as a function of the curtain position (131).

10. Device (110) according to one of the preceding claims, wherein the sensor unit (112) is arranged pivotably about a pivot axis (114) on the device (110), so that

- In a first position of the sensor unit (112), a light curtain (113) is generated which extends essentially parallel to a screen surface of the user device (120) inserted in the holder (116); and - In a second position of the sensor unit (112), a light curtain (113) is generated which extends essentially parallel to a support surface (140) on which the device (110) is placed.

11. The device (110) according to claim 10, wherein the control unit (111) is set up

- to determine whether the sensor unit (112) is in the first position or in the second position; and

- on the basis of the sensor data of the sensor unit (112) to effect a virtual touch operation of the user device (120) inserted in the holder (116) when it is determined that the sensor unit (112) is in the first position; and or

to effect a cursor operation of the user device (120) inserted in the holder (116) on the basis of the sensor data of the sensor unit (112) when it is determined that the sensor unit (112) is in the second position.

12. Device (110) according to one of the preceding claims, wherein the sensor unit (112) is designed to generate a light curtain (113) which primarily or exclusively comprises light in the infrared range.

13. Device (110) according to one of the preceding claims, wherein

- The holder (116) comprises a recess in the base (118) in which a user device (112) can be placed, in particular such that the user device (112) is at an angle between 20 ° and 80 ° relative to the storage surface ( 140) is held.

14. The device (110) according to any one of the preceding claims, wherein the device (110) comprises a communication unit (117) which is designed to be connected to the in the user device (120) inserted into the holder (116).

15. Device (110) according to one of the preceding claims, wherein

- The device (110) comprises a power supply unit which is designed to supply the sensor unit (112) and / or the control unit (111) with power from an electrical supply network; and or

- The device (110) comprises a charging device for charging the user device (120) inserted into the holder (116).