EP4487197A1 - Input device having an input field which can be actuated by touch and a button for switching the input field from an energy-saving mode to an active operating mode, and associated method - Google Patents

Abstract

The invention relates to an input device (1) having an input field (10) which can be actuated by a touch of an operator (2), a button (11) and control electronics (12), wherein the input field (10) has a touch-sensitive input surface (13) on one side and the button (11) is arranged on a second side of the input field (10) opposite the first side, wherein the button (11) is designed to be actuated by an actuation of the input field (10) and/or by a force acting on the input surface (13) in the direction of the button (11) and/or by the operator (2) approaching the input surface (13), and the control electronics (12) are designed to switch the input field (10) from an energy-saving mode to an active operating mode in the event that the button (11) is activated, in which active operating mode the input field (10) consumes more energy than in the energy-saving mode and are designed to determine a position of the touch on the input surface (13).

Description

Input device with an input field that can be operated by touch and a button for switching the input field from an energy-saving mode to an active operating mode and associated method

Description:

The invention relates to an input device with an input field that can be actuated by touching an operator and in particular by his finger and a button for switching the input field from an energy-saving mode to an active operating mode and an associated method.

A large number of different input fields, which can also be referred to as touchscreen or touchpad, are known from the prior art. However, when operating as intended, i.e. when they determine the position of a touch on their input surfaces and pass on the position, these can achieve a comparatively high level Have energy requirements, which also exist when the input fields are in their active operating mode but are not actuated or touched, therefore not needed.

Accordingly, the energy consumption of such input fields is comparatively high, regardless of operation.

In order to reduce the energy requirement, i.e. the power requirement, it is known in the prior art to switch the input fields into an energy-saving mode when they are not needed and, if necessary, to switch them back to the active operating mode when they are needed again.

For this purpose, additional buttons are partially provided adjacent to the input fields or adjacent, i.e. adjacent to the input areas of the input fields, so that the button must first be pressed in order to then be able to operate or actuate the input field.

As a result, two different or two consecutive movement sequences are required to operate such input fields, which is perceived by the operator as unintuitive and cumbersome.

The invention is therefore based on the object of overcoming the aforementioned disadvantages and of providing an input device with an input field that can be actuated by the touch of an operator, wherein the input device should have low energy consumption and be intuitive and easy to use.

This task is achieved by the combination of features according to claim 1.

According to the invention, an input device with an input field that can be activated by touching an operator, a button and control electronics is therefore proposed. The input field points to a first Page has a touch-sensitive input surface, the button being arranged on a second side of the input field opposite the first page. The first side of the input field can in particular form the visible side of the input device, so that the button is arranged on the back of the input field or behind the input field from the visible side. In addition to the touch-sensitive input surface, the input field can also have evaluation electronics for evaluating the touch of the input surface and in particular the determination of the position of the touch and, if necessary, a power supply device for powering the input field. To detect the touch, the input field can, for example, have a capacitive film which extends over the input area. The button is designed to be actuated by actuating the input field, ie by touching the input surface and/or by a force acting on the input surface in the direction of the button and/or by the operator approaching the input surface. If the input device is part of a mobile unit, it is preferably provided that the button cannot be actuated by the operator simply approaching the input surface, but only by a force acting on the input surface in the direction of the button, since this can prevent the For example, the button is already actuated by approaching when the input device is inserted into a bag or trouser pocket. According to the invention, the control electronics are designed to switch the input field from an energy-saving mode to an active operating mode when the button is pressed, in which the input field consumes more energy than in the energy-saving mode. The input field is designed to determine a position of the touch on the input surface in the active operating mode.

If the input field is not needed or not operated, it is in a low-energy energy-saving mode, which requires less energy, ie electricity, than the active operating mode in which it is Determine the position of the touch and pass it on to operate a device. Such a position determination is not possible in the energy saving mode. In the energy saving mode, the energy consumption of the input field can also be reduced to “0” Wh.

If the input field is activated by the operator, he or she does not have to activate the input field separately beforehand. A single movement sequence is sufficient, through which the input field is operated at the same time and this can be switched from the energy-saving mode to the active operating mode using the button.

In addition to the reduced power consumption and intuitive operation using a single movement sequence, which does not deviate from the conventional movement sequence for operating the input area, another advantage is that unwanted operations on the input field are avoided.

In order to switch the input field from the active operating mode back to the energy-saving mode when it is no longer needed, i.e. is no longer touched, an advantageous development provides that the control electronics or the input field itself is designed to switch the input field when a predetermined waiting time has elapsed, which can also be referred to as dead time, to switch from the operating mode to the energy saving mode after pressing the input field. In particular, the waiting time is reset when the input field is actuated again within the waiting time, so that the input field is preferably only put back into energy-saving mode when the operator no longer presses it (again) within the waiting time.

In order to switch the input field into its energy-saving mode, it can be provided that the control electronics is designed to separate the input field from a power supply device of the input field when switching to the energy-saving mode, so that the input field is no longer is supplied with electricity or energy and consumption is reduced accordingly. In particular, if a separate power supply device is provided for the input field, it can alternatively also be provided that the power supply device itself is switched off or disconnected from a mains voltage. Switching to the energy-saving mode can be done using appropriate circuit breakers, ie hardware, or through appropriate programming, ie software. When switching from the energy saving mode to the active operating mode, the connection between the power supply device and the input field can be restored or the power supply device can be switched on.

Additionally or alternatively, the control electronics can be designed to transmit a signal to the input field to switch off the input field.

The button can also be based on different operating principles. For example, the button can be a mechanical button or a capacitive button or an inductive button or an optical button. Sensors such as a capacitive sensor or a force sensor can also function as buttons or be understood as such. A mechanical button is understood in particular to mean that an electrical contact can be closed by a movement. Accordingly, a button based on a mechanical operating principle can be designed, for example, as a safety mat.

A piezo button that acts as a button is also advantageous and, when actuated, can generate current based on the piezo effect to operate the control electronics and/or to switch the input field from the energy-saving mode to the operating mode. This is what makes it Energy consumption of the entire input device with the input field in energy saving mode continues and if necessary reduced to “0” Wh.

If a force sensor is used as a button, it can interact with the input field in active operation. For example, during active operation of the input field, a position of the touch and a force of the touch can be detected by the force sensor, which together represent the operator's input and can be passed on together to a device connected to the input device. If there is no more input or contact, the input field can be switched back to energy-saving mode, with the force sensor remaining active to switch the input field back to the active operating mode.

An advantageous development provides in particular that the button is a mechanical button, which is designed to measure a predetermined force acting on it via the input field or to be actuated by or at a predetermined force acting on it via the input field. If the button is designed to be actuated with a predetermined force, correspondingly strong springs or the like can be provided, for example. Furthermore, the control electronics is designed to switch the input field from the energy-saving mode to the active operating mode when the button is pressed with the predetermined force.

The input field has a flat and flat extension, particularly on the side of the input surface, and is in particular a touchscreen or a touchpad.

The input area of the input field can also have a flat and flat extent. Alternatively, however, it can also be provided that the input surface is designed as a particularly jump-free free-form surface, so that the input field has one at least on the first side does not provide a flat surface. The input field can also have a 3D contour in its entirety and z. B. be curved convexly and/or concavely at least in sections.

A particularly advantageous variant provides that the input field is mounted against the button completely and/or in sections in an actuation direction of the button. This allows, for example, a force acting on the input surface in the direction of actuation to be transmitted to the button to actuate the button.

Such a storage can be achieved by a reversible elastic deformation of the input field, so that preferably a central area of the input field can be pressed against the button by bending the input field.

Alternatively and according to an advantageous embodiment, the input field can be moved from an original position against the button into an actuation position and can be spring-returned from the actuation position to the original position. It follows that the input field can preferably be moved as a whole from a starting or original position along a displacement path into the deflected end position or actuation position and against the button, thereby generating haptic feedback. In such a variant, guide elements and/or stops can also be provided, which guide and limit the displacement along the displacement path. The displacement path along which the input field should be displaceable can be minimal and preferably less than 1 mm, more preferably less than 0.5 mm.

To generate haptic and/or acoustic feedback, a spring element can be arranged between the input field and the button or integrated into the button, through which a “click” is generated, for example, when the button is pressed or when the operating position is reached. bar, so that haptic and/or acoustic feedback is provided.

Particularly if the input field is movable relative to the button or the control electronics, in order to compensate for the relative movement to one another, it can be provided that the input field is connected to the control electronics and/or a power supply device of the input field via a flexible power and/or data line.

A particularly advantageous development provides that the input device is completely closed on the first side of the input field and in particular is completely determined by the input area. If the button is designed, for example, as an optical button or as a capacitive or inductive button, the button can partially extend into the input field, which has a smaller thickness in the area of the button than in adjacent areas. Adjacent to the button, the input surface can also have, for example, a transparent section to enable optical detection.

Furthermore, the input device can provide a housing which frames the input field, particularly on the visible side, i.e. on the side of the input surface of the input field, and to which the control electronics and/or the button can be fixed. The housing can be connected to the input field via an elastic and in particular frame-shaped element, so that the input device can be completely closed on the visible side or on the first side of the input field even if the input field is movable relative to the housing.

In order to enable targeted actuation of the button, the input surface has, according to an advantageous development, a predetermined and in particular marked functional area. The button is designed here exclusively by pressing the input field Functional area and / or to be actuated exclusively by a force acting in the functional area on the input surface in the direction of the button and / or exclusively by the operator approaching the functional area of the input surface. The functional area can also, for example, be visually or haptically detectable and, in particular, color-coded or have a different shape than the surrounding areas of the input surface.

Alternatively, and for example in the case of a touchscreen, an electronic display area is provided overlying the input area, which can also be active when the input field is in its energy-saving mode and on which one or more functional areas is/are displayed. If the operator wants to trigger a function belonging to a function area, he touches the input area or the input field in the area of the respective function area and at the same time presses the button.

If the control electronics or the button are not required as long as the input field is in its active operating mode, the control electronics can be designed to switch itself to an operating mode when the input field is switched to the energy-saving mode and to an energy-saving mode when the input field is switched to the operating mode switch.

The control electronics are preferably formed by electrical components arranged on a circuit board, which is arranged in particular parallel to the input field, with the button being arranged on the circuit board.

Alternatively, the control electronics can also be formed by electrical components arranged on several circuit boards, with at least one or exactly one of the circuit boards being arranged parallel to the input field. In such a variant, the button can be provided on the circuit board arranged parallel to the input field, the circuit boards, for example are electrically connected to each other by flexible cables.

If the button is arranged on a circuit board of the control electronics, a variant is particularly advantageous in which the button is designed in two parts, with a first part of the button being arranged on the circuit board and a second part of the button adjacent to it on the input field, so that the first Part and the second part can be brought into contact by moving the input field in the direction of the circuit board or in the direction of the first part of the button, whereby an electrical contact can be established and the button can therefore be actuated. The first part of the button can provide two contacts, which are contacted with each other by the second part. Alternatively, the second part of the button can also be contacted, for example, via the flexible line connecting the control electronics to the input field.

A further aspect of the invention relates to a method for operating an input device according to the invention. According to the method, the control electronics switches the input field from the energy-saving mode to the operating mode when the button is pressed, the control electronics then switching the input field from the operating mode to the energy-saving mode when the predetermined waiting time has expired after the input field has been pressed. Preferably, the waiting time is reset within the waiting time when the input field is pressed again.

The features disclosed above can be combined in any way, as long as this is technically possible and they do not contradict each other.

Other advantageous developments of the invention are characterized in the subclaims or are shown in more detail below together with the description of the preferred embodiment of the invention with reference to the figures. Show it: Fig. 1 input device in a first state;

Fig. 2 input device in a second state;

Fig. 3 input device in a third state;

Fig. 4 Process for controlling the input device.

The figures are exemplary schematic. The same reference numbers in the figures indicate the same functional and/or structural features.

An input device 1 is shown in different states in FIGS. 1 to 3.

In Figure 1, the input field 10 is in its energy-saving mode, so that it requires little or no energy but also cannot detect any touch by the operator 2 and accordingly cannot determine the position of the touch.

If the operator 2 wants to operate the input device 1, he places his finger on the input surface 13 of the input field 10, as shown, and exerts pressure or a force on the input surface 13.

As a result, the movably mounted input field 10 is moved or pressed from the starting or original position shown in FIG. 1 in the actuation direction X in the direction and, as shown in FIG. It is sufficient that the displacement path from the starting position shown in Figure 1 to the end or actuation position shown in Figure 2 is minimal and, for example, less than 1 mm. If the input device 1 has a housing 15 as shown, which together with the input surface 13 determines the visible side of the input device, the input field sinks into the housing 15 as it moves in the direction of the button 11 or is moved into it. To record the position of the touch by the operator 2, the input field 10 can have a capacitive film and be designed as a touchpad or touchscreen.

In the variant shown, the button 11 is designed as a mechanical button, which is switched or actuated by contact with the input field 10. When the button 11 is pressed, the input field 10 is switched by the control electronics 12 from its energy-saving mode to its active operating mode, in which position detection or determination of the position of the touch is possible.

The control electronics 12 is shown here as a circuit board on which electronic components of the control electronics 12 as well as the button 11 are arranged and connected. To compensate for the relative movement of control electronics 12 and input field 10 to one another, these are connected by a flexible power and/or data line 14, so that the control electronics can switch the input field 10 between its modes or the input field 10 can be powered via the control electronics 12.

After pressing the button 11, as shown in FIG is shown.

If the button 11 is no longer pressed, the input field 10 is still in its active operating mode, with the control electronics switching back to energy-saving mode after a predetermined waiting time of, for example, 30 seconds, if the input field 10 is not pressed within the waiting time, ie no contact with the input area is detected by the input field. An actuation, ie a touch of the input field 10 by the user can be triggered by the input field 10 can be reported to the control electronics 12 via the flexible line 14.

This method is shown in simplified form in FIG. 4, based on a flow chart.

A: The input field 10 is in its energy saving mode.

B: Is button 11 pressed?

No: The input field is still in its energy saving mode.

Yes: The input field is switched to its active operating mode (state C).

C: The input field 10 is in its active operating mode.

D: The waiting time or the waiting timer is restarted. Is the input area 13 of the input field 10 touched by the user 2 during the waiting time?

Yes: The input field remains switched to its active operating mode (state C).

No: The input field is switched to its energy saving mode (state A).

The implementation of the invention is not limited to the preferred exemplary embodiments given above. Rather, a number of variants are conceivable, which make use of the solution presented even in fundamentally different designs.

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Claims

Patent claims 1 . Input device (1) with an input field (10) that can be actuated by touching an operator (2), a button (11) and control electronics (12), the input field (10) having a touch-sensitive input surface (13) on a first side and the Button (11) is arranged on a second side of the input field (10) opposite the first side, the button (11) being designed by actuating the input field (10) and/or by acting on the input surface (13) in the direction the force acting on the button (11) and/or by the operator (2) approaching the input surface (13), and the control electronics (12) is designed to open the input field (10) when the button (11) is actuated. to switch from an energy-saving mode to an active operating mode in which the input field (10) consumes more energy than in the energy-saving mode and is designed to determine a position of the touch on the input surface (13). 2. Input device according to claim 1, wherein the control electronics (12) or the input field (10) is designed to switch the input field (10) from the operating mode to the energy-saving mode when a predetermined waiting time has elapsed after actuation of the input field (10). 3. Input device according to claim 1 or 2, wherein the control electronics (12) is designed to separate the input field (10) from a power supply device of the input field when switching to the energy saving mode or to switch the power supply Switch off the supply facility. 4. Input device according to one of the preceding claims, wherein the button (11) is a mechanical button or capacitive button or inductive button or optical button. 5. Input device according to one of claims 1 to 3, wherein the button (11) is a mechanical button which is designed to measure a predetermined force acting on it via the input field (10) or at a predetermined one via the input field (10). to be actuated by force acting on it, and wherein the control electronics (12) is designed to switch the input field (10) from the energy-saving mode to the operating mode when the button (11) is actuated with the predetermined force. 6. Input device according to one of the preceding claims, wherein the input field (10) has a flat and flat extension and is in particular a touchscreen or touchpad. 7. Input device according to one of the preceding claims, wherein the input field (10) is mounted movably against the button (11) completely and / or in sections in an actuation direction (X) of the button (11). 8. Input device according to the preceding claim, wherein the input field (10) can be moved from an original position against the button (11) into an actuation position and is spring-returned from the actuation position into the original position. 9. Input device according to one of the two preceding claims, wherein between the input field (10) and the button (11) or a spring element is arranged integrated into the button (11), which is designed to generate haptic and/or acoustic feedback, in particular when the button (11) is actuated. 10. Input device according to one of the preceding claims, wherein the input field (10) is connected to the control electronics via a flexible power and / or data line (14). 11. Input device according to one of the preceding claims, wherein the input device (1) is completely closed on the first side of the input field (10) and in particular is completely determined by the input area (13). 12. Input device according to one of the preceding claims, wherein the input surface (13) has a predetermined and in particular marked functional area and wherein the button is designed exclusively by actuating the input field (10) in the functional area and / or exclusively by pressing the button in the functional area Input surface (13) acting force in the direction of the button (11) and / or to be actuated exclusively by the operator (2) approaching the functional area of the input surface (13). 13. Input device according to one of the preceding claims, wherein the control electronics (12) is designed to switch itself into an operating mode when the input field (10) is switched into the energy-saving mode and into an energy-saving mode when the input field (10) is switched into the operating mode. 14. Input device according to one of the preceding claims, wherein the control electronics (12) is formed by electrical components arranged on a circuit board, which are in particular parallel lei is arranged to the input field (10), and wherein the button (11) is arranged on the circuit board, so that the control electronics (12) and button (11) form a unit. Method for operating an input device according to at least the preceding claims 1 and 2, wherein the control electronics (12) switches the input field (10) from the energy-saving mode to the operating mode when the button (11) is actuated and wherein the control electronics (12) switches the input field (10 ) switches from the operating mode to the energy saving mode when the predetermined waiting time has expired after pressing the input field (10).