Input device with a movable handling means on a capacitive detection surface and a redundant capacitive potential coupling

The invention relates to an input device including: a capacitive detector with a detection surface forming an array of electrodes; an electronic evaluation unit electrically connected to the electrodes and forming an associated array of electrical measuring fields for the spatially resolving detection of a capacitive influence on the detection surface; a handling means disposed on the detection surface in a manner movable along an adjustment path to perform an operating input by means of a movement by an operator; a coupling electrode assembly which is partially moved along with the handling means and disposed in an electrically insulated manner with respect to the operator while they touch the handling means, and where at least one position of the handling means is provided where two measuring fields are capacitively influenced by a means of the coupling electrode assembly, where these influences are detected to obtain position information.

This application claims priority to the German Application No. 10 2018 120 576.7, filed Aug. 23, 2018, now pending, the contents of which are hereby incorporated by reference.

The present disclosure relates to an input device having a capacitive detection device, wherein the detection device in each case has a detection surface while forming an array of electrodes associated with the detection surface, and wherein a handling means is movably disposed on the detection surface defined by the detection device and the detection device is configured for detecting the position of the handling means. The present disclosure moreover relates to a corresponding method for capacitive position detection. For example, the capacitive detection device is a capacitive touchpad or a capacitive touchscreen. The input device further includes an electronic evaluation unit, which is connected in an electrically conducting manner to the electrodes, in order to form, by means of the electrode array, an associated array of measuring capacitances, which is preferably generated in a sequence in time, for the spatially resolving detection of a capacitive influence on the input surface. The input device includes a handling means, which is movably disposed on the detection surface in order to perform an operating input when the handling means is moved, in particular when the handling means is manually moved while being touched by an operator. Furthermore, the handling means comprises a coupling electrode assembly in order to cause at least one of the measuring capacitances to be detectably influenced, from which position and/or movement information can be derived. Such a combination of a touchpad or touchscreen with a handling means movably disposed thereon is becoming increasingly popular, because flexible inputting options are being provided in this manner, and because a variety of functions and function information can be associated with the handling means particularly in the case of a touchscreen, due to the flexible displaying options. On the other hand, however, the handling means provides a familiar haptic feedback and can easily be located by feel by the driver without any visual contact. Because of the intended utilization for position detection of the region of the capacitive electrode structure which is located underneath the rotary adjuster and covered by the rotary adjuster, a capacitive coupling between the handling means and the capacitive touchscreen or touchpad is required. For example, this coupling is provided by an electrode assembly which is in an electrically conducting contact with the operator grasping the handling means. It was found that the establishment of this contact is unreliable, so that the detection of the position of the handling means is unreliable.

Against this background, there was a demand for a generic input device in which an improved capacitive coupling is obtained between the capacitive detection device, e.g. the capacitive touchscreen, and the handling means. This object is achieved by an input device according to claim1. An equally advantageous use and a method for positional evaluation are each the subject matter of the independent claims. Advantageous embodiments are in each case the subject matter of the dependent claims. It must be noted that the features cited individually in the claims can be combined with each other in any technologically meaningful manner and represent other embodiments of the present disclosure. The description, in particular in connection with the figures, additionally characterizes and specifies the invention present disclosure.

The present disclosure relates to an input device including a capacitive detection device, in which case the detection device has a detection surface while forming an array of electrodes associated with the detection surface. For example, the electrodes are disposed in a common plane or on two or more parallel planes. For example, the detection device is a capacitive touchpad or a capacitive touchscreen. According to the present disclosure, an electronic evaluation unit is provided, which is electrically connected, preferably in an electrically conducting manner, to the electrodes, in order to form, by means of the array of electrodes, an associated array of electrical measuring fields, which is preferably generated in a sequence in time and varies in time, for the spatially resolving detection of a capacitive influence on the detection surface. For example, this is a capacitive detection device with a projected capacitive technology, in particular with a self-capacitance structure or a mutual-capacitance structure. In the so-called self-capacitance structure, each individual electrode is electrically connected to the evaluation unit, and the evaluation unit scans all electrodes during detection. If the measuring field, or the measuring capacitance, is influenced by the external approach of an object, e.g. by the approach of the coupling electrode assembly described below, this is detected and can be associated with a location on the detection surface due to the individual electrical connection with the respective electrode. In the mutual-capacitance structure, measuring fields, and thus measuring capacitances, are generated at intersection points between two electrically insulated intersecting electrode structures. The evaluation unit is capable of measuring the measuring capacitance of each individual intersection point. If the respective measuring field is influenced by the external approach of an object, e.g. by the approach of the coupling electrode assembly described below, the electrical measuring capacitance measured by the evaluation unit is reduced at the respective intersection point and detected, and can be associated with a location on the detection surface due to the electrode structure and arrangement of intersection points, which is structured in rows and columns.

According to the present disclosure, the input device includes a handling means, which is disposed on the detection surface in a manner movable along an adjustment path, in order to perform an operating input when the handling means is moved, in particular when the handling means is being touched by an operator. For example, this is a handling means that is mounted so as to be translationally movable along a direction parallel to the detection surface. Preferably, the handling means is mounted on the detection surface in a manner rotatable about a rotation axis orthogonal to the detection surface, thus qualifying the input device as a rotary adjuster.

According to the present disclosure, a coupling electrode assembly is further provided, which is at least partially moved synchronously with the handling means and which, for example, is at least partially, preferably completely, attached to a rotary knob substantially forming the handling means. The coupling electrode assembly is arranged in an electrically insulated manner with respect to the operator while they touch the handling means, so that an electric charge equalization between the operator and the coupling electrode assembly is excluded according to the present disclosure. The coupling electrode assembly substantially consists of a conductive material. The coupling electrode assembly has a first portion and at least one second portion, which are electrically connected to each other, e.g. coupled in an electrically conducting or capacitive manner. At least one position along the adjustment path of the handling means resulting from the movability of the handling means is provided, in which a first portion of the coupling electrode assembly is disposed adjacent to a first electrode of the array in order to enable a capacitive coupling between the first portion and the first electrode, and at least one second portion of the coupling electrode assembly is disposed adjacent to a second electrode of the array that differs from the first electrode in order to enable a capacitive coupling between the second portion and the second electrode.

In order to be able to detect several positions, several first electrodes that can be selectively contacted by the evaluation unit and several second electrodes that can be selectively contacted by the evaluation unit are in each case preferably provided and arranged in such a way that several positions along the adjustment path of the handling means are detectable by the evaluation unit given a corresponding position of the handling means, i.e. that associated first electrodes that are different from position to position are in each case provided, and associated second electrodes that are different from position to position are in each case provided, in order to detect the respective position.

According to the present disclosure, the evaluation unit is configured to generate a first measuring field emanating from at least the first electrode and to apply a predetermined electric potential to the second electrode in a first measuring step, in order to influence the first measuring field emanating from the first electrode by means of the capacitive coupling and the electric connection to the first portion.

According to the present disclosure, the evaluation unit is further configured to generate a second measuring field emanating from at least the second electrode and to apply a predetermined electric potential to the first electrode in a second measuring step, in order to influence the second measuring field emanating from the second electrode by means of the capacitive coupling and the electric connection to the second portion. Preferably, the first and second measuring steps are separated in time, i.e. they take place sequentially.

For example, the predetermined electric potential is the earth or ground potential or a fixed potential, such as 5 V, 10 V or 12 V. For example, the predetermined electric potential changes during the measuring process on the first electrode, e.g. using a Schmitt trigger or the like.

According to the present disclosure, the electronic evaluation unit is configured for determining both the influence on the first measuring field and on the second measuring field and for providing in each case an associated detection result, i.e. a first detection result associated with the influence on the first measuring field and a second detection result associated with the influence on the second measuring field. It is further configured for determining, from the first and/or the second detection result, preferably from both, position and/or movement information of the handling means and to output the latter, for example, for performing a control or switching function. For example, the two detection results are compared, and a position information or movement information is outputted only in the case of a minimum conformity. In another configuration, the position information or movement information is determined by interpolation of the first and second detection results.

According to the present disclosure, one first and second measuring step are to be provided, respectively, for at least one position, in which, on the one hand, the measuring field stemming from the first electrode is influenced by means of the capacitive coupling caused by means of the second electrode and this influence is detected, and, on the other hand, the measuring field stemming from the second electrode is influenced by means of the capacitive coupling caused by means of the first electrode. Therefore, a redundant capacitive influence on two different capacitive measuring fields, which are preferably spaced apart from each other in space, is used for position detection, whereby its accuracy and/or reliability can be enhanced.

In the process, the conceptual advantage of the capacitive coupling by means of the array electrodes is maintained, namely that the respective measuring field, under constant and predetermined conditions, can be influenced depending on the position in order to obtain a more reliable position detection. In contrast to a coupling electrode connected to the hand of an operator in an electrically conducting manner, the issue of a quality of the electrical connection between the operator and the coupling electrode being dependent on external conditions, such as skin resistance, is eliminated. With a simple design, the solution according to the present disclosure increases the reproducibility and reliability of the position detection by not only providing a first and second detection result, according to the present disclosure, but also by providing these two detection results by capacitive application to the coupling electrode assembly in different locations.

Since, by means of the coupling electrode assembly, at least two measuring fields are capacitively influenced and these influences are detected, according to the present disclosure, in order to obtain position information, i.e. the mutual influence of the measuring fields generated by the respective electrodes by the respective other electrodes is the basis of position detection, the functional reliability of the input device can be increased because several, in particular equivalent, detection results can be used for determining the position and/or movement information. In addition, a particularly space-saving design of the input device thus becomes possible, because an additional electrode, which is provided especially for influencing the measuring fields, can be dispensed with.

Furthermore, the input device described herein may be freely positioned on any commercially available touchpad or touchscreen, e.g. with a rectangular grid, i.e. electrode array, without any loss of accuracy in determining position and/or movement information.

According to a preferred embodiment of the input device, the clear distance between the detection surface and the second portion and the clear distance between the detection surface and the first portion for each position are in each case smaller than a minimum distance of 1 mm, preferably smaller than 0.5 mm and more preferably smaller than 0.1 mm. According to another embodiment, the distance between the first portion and the second portion is at least twice as large as the minimum distance.

According to another embodiment, the second portion or the entirety of the second portions has a surface, relative to a plane parallel to the detection surface, which is greater than the surface of the first portion relative to the same plane.

According to a preferred embodiment, the position-dependent variation of the capacitive coupling of the coupling field formed between the second electrode and the second portion over the entire adjustment range of the handling means corresponds to the variation of the capacitive coupling of the coupling field formed between the first electrode and the first portion. “Corresponding” means a deviation in the variation not exceeding 20 percent, preferably 10 percent.

Preferably, it is provided that the second portion or portions are connected in an electrically conducting manner to the first portion via one or more conductor portions of the coupling electrode assembly, which is or are spaced further apart from the detection surface than the first portion and the second portion.

According to another embodiment, several second portions are provided for improving the coupling, which are distributed about the rotation axis of the input device configured as a rotary adjuster.

Preferably, the first portion and the second portion are disposed in a common plane which is parallel to the detection surface.

In one embodiment, the potential is applied to several, preferably all, second electrodes, with the exception of the first electrode provided for generating the measuring field. Preferably, the evaluation unit is configured to determine the second electrodes most closely adjacent to the second portion depending on a position detection directly precedent in time, in order to apply to this determined second electrode the predetermined electric potential.

Furthermore, the present disclosure relates to the use of the input device in one of the above-described embodiments in a motor vehicle.

The present disclosure further relates to a method for evaluating the position of a handling means of an input device with the following steps. In a step of providing, the input device with a capacitive detection device is provided, which has a detection surface while forming an array of electrodes associated with the detection surface, with an electronic evaluation unit, which is electrically connected to the electrodes, in order to form, by means of the array of electrodes, an associated array of electrical measuring fields for the spatially resolving detection of a capacitive influence on the detection surface, and with a handling means, which is movably disposed on the detection surface, in order to perform an operating input in case of a movement while the handling means is touched by an operator. The input device provided has a coupling electrode assembly, which is at least partially moved along with the handling means and which is disposed in an electrically insulated manner with respect to the operator while they touch the handling means, and at least one position of the handling means is provided in which a first portion of the coupling electrode assembly is disposed adjacent to a first electrode of the array, and at least one second portion of the coupling electrode assembly electrically connected to the first electrode is disposed adjacent to a second electrode of the array that differs from the first electrode, in order to enable a capacitive coupling between the second portion and the second electrode.

In a first generation and application step, a first electric measuring field emanating from at least the first electrode is generated by means of the evaluation unit and a predetermined electric potential is applied to the second electrode by means of the evaluation unit, in order to influence the first measuring field by means of the capacitive coupling and the electric connection to the first portion provided by the coupling electrode assembly.

In a second subsequent generation and application step, a second electric measuring field emanating from the second electrode is generated by means of the evaluation unit and a predetermined electric potential is applied to the first electrode by means of the evaluation unit, in order to influence the second measuring field by means of the capacitive coupling and the electric connection to the second portion provided by the coupling electrode assembly.

The respective influence on the first and the second measuring field is detected by means of the evaluation unit and a first and second detection result is provided during the corresponding generation and application step. Position and/or movement information of the handling means is determined, by means of the evaluation unit, from the first and/or second detection result in a determination step.

In a subsequent evaluation step, the data obtained in the preceding detection steps are used for obtaining position and/or movement information of the handling means.

The solution according to the present disclosure makes it possible that the respective measuring field can be influenced depending on the position, not only under constant and predetermined conditions, in order to obtain a more reliable position detection. In contrast to a coupling electrode connected to the hand of an operator in an electrically conducting manner, the issue of the quality of the electrical connection between the operator and the coupling electrode being dependent on external conditions, such as skin resistance, is eliminated. Furthermore, the reproducibility and reliability of position detection is increased with a simple design by the solution according to the present disclosure, because it draws upon the mutual influence of the measuring fields generated by the respective electrodes by the respective other electrodes.

According to the present disclosure, one first and second measuring step are provided, respectively, for at least one position, in which, on the one hand, the measuring field stemming from the first electrode is influenced by means of the capacitive coupling caused by means of the second electrode and this influence is detected, and, on the other hand, the measuring field stemming from the second electrode is influenced by means of the capacitive coupling caused by means of the first electrode.

Preferably, several of these positions are provided along the adjustment path of the handling means, wherein associated first electrodes that are different from position to position are in each case provided, and associated second electrodes that are different from position to position are in each case provided, in order to detect the respective position.

Therefore, a redundant capacitive influence on two different capacitive measuring fields, which are preferably spaced apart from each other in space, is used for position detection, whereby its accuracy and/or reliability can be enhanced. On the whole, the functional reliability can be enhanced because several equivalent detection results can be used for determining the position and/or movement information. In addition, a particularly space-saving design of the input device thus becomes possible, because an additional electrode, which is provided especially for influencing the measuring fields, can be dispensed with.

Furthermore, the input device described herein may be freely positioned on any commercially available touchpad or touchscreen, e.g. with a rectangular electrode grid, without any loss of accuracy in determining position and/or movement information.

According to a preferred variation of the above-described method, a selection step, which precedes the application step in time, is provided, in which the second electrodes adjacent to the second portion are determined depending on a position detection directly precedent in time, in order to apply to this determined second electrode the predetermined electric potential in the subsequent application step.

FIG. 1shows an input device1according to the present disclosure, with a touchscreen functioning as a capacitive detection device2. The detection device2defines a detection surface10facing towards the operator B, on which a handling means3is disposed so as to be mounted rotatably about a rotation axis D, thus forming a so-called rotary adjuster. The capacitive detection device2has an array of electrodes5ato5g,which is not depicted in full and to scale in the Figures and is only supposed to serve for schematic illustration of the general structure. An electronic evaluation unit12is electrically connected to the electrodes5ato5g,which, for generating an associated measuring field, applies a potential V1 to each of the electrodes selectively and in a sequence in time, in order to detect a touch by the operator B or, depending on the position of the respective electrode relative to the handling means3, a position of the handling means3, based on the influence on the measuring field. For influencing the respective measuring field, the handling means3has on the side thereof facing towards the detection surface10a coupling electrode assembly8, which is disposed in an electrically insulating manner with respect to the operator B while they are touching the handling means3. Several positions are provided, which are, in particular, evenly distributed across the rotary adjustment range of the handling means3and of which one possible position is shown in each case in the Figures, and in which one first portion8aof the coupling electrode assembly8is in each case disposed adjacent to a first electrode5aof the array, in order thus to obtain a capacitive coupling between the first portion8aand the first electrode5a,and at least one second portion8bof the coupling electrode assembly, which is electrically connected to the first portion8avia the conductor portion8c,is disposed adjacent to a second electrode5dof the array that differs from the first electrode5a,in order to obtain a capacitive coupling between the second portion8band the second electrode5d.In this case, the evaluation unit12is configured to generate a first measuring field emanating from the first electrode5aand to apply a predetermined electric potential V0 to the second electrode5d,in order to influence the first measuring field emanating from the first electrode5aby means of the capacitive coupling existing between the second electrode5dand the second portion8band by means of the electric connection8cto the first portion8a.The evaluation unit12is further configured to generate a second measuring field emanating from the second electrode5dand to apply a predetermined electric potential V0 to the first electrode5a,in order to influence the second measuring field emanating from the second electrode5dby means of the capacitive coupling existing between the first electrode5aand the first portion8aand by means of the electric connection8cto the second portion8b.

Due to the fact that the electronic evaluation unit12is configured for detecting the respective influences on the measuring fields, dual and redundant position information is obtained for the respective position of the handling means3. The principle of the present disclosure will explained again with reference to another embodiment shown inFIG. 2.

The latter substantially differs from the embodiment shown inFIG. 1in that the coupling electrode assembly8has not only one, but two, second portions8bwhich are connected in an electrically conducting manner with one another and with the first portion8aof the coupling electrode assembly8via several conductor portions8c.In this case, the evaluation unit12is configured to generate a first measuring field emanating from at least the first electrode5aby means of the potential V1 and to apply a predetermined electric potential V0 to the second electrodes5bto5e,in order to influence the first measuring field stemming from the first electrode5aby means of the capacitive coupling existing between the second electrodes5bto5e,particularly between the respective most closely adjacent second electrodes5c,5d,and the respective second portion8band by means of the electric connections8cto the first portion8a.The evaluation unit12is further configured to generate a second measuring field emanating from one of the second electrodes5c,5dby means of the potential V1 and to apply a predetermined electric potential V0 to the first electrode5a,in order to influence the second measuring field stemming from the one of the second electrodes5c,5dby means of the capacitive coupling existing between the first electrode5aand the first portion8aand by means of the electric connections8cof the second portion8b.

Due to the fact that the electronic evaluation unit12is configured for detecting the respective influence on the measuring field and thus the change of the latter, dual and redundant position information is again obtained with respect to the respective position of the handling means3.

FIG. 3is a sectional view associated withFIG. 2. It substantially serves for illustrating the coupling electrode assembly8, which is attached to the handling means3in its entirety and moved along with it. The first portion8aof the coupling electrode assembly8, which is situated across from the first electrode5awith the clear distance Δa, has a surface Fa with respect to a plane with respect to the detection surface10that is smaller than the surface Fb of the second portion8brelative to the same plane, and thus also smaller than the entirety of the surfaces Fb of the two second portions8b.The clear distance Δa between the detection surface10and the second portion8band the clear distance Δb between the detection surface10and the first portion8a are in each case smaller than a minimum distance of 0.1 mm. The conductive connection between the second portions8band the first portion8aof the coupling electrode assembly8is realized by means of several electrical conductor portions8cwhich, as symbolized by the ohmic resistance R, are generally lossy. The detection device2has an upper transparent cover layer2aforming the detection surface10, a transparent layer2bforming the array of electrodes, and an electronic pixel matrix display layer2cdisposed thereunder.

The equivalent circuit diagrams, based on which the operation of the input device1according to the present disclosure is described again, are shown in theFIGS. 4aand 4b. In this case, the embodiment shown inFIG. 4ais a detection device2with a self-capacitance design at a time of the electrode5agenerating a measuring field. In this case, the first electrical measuring field is generated only by applying the potential V1 to the first electrode5a.Also, the capacitive coupling between the second electrode5cand the second portion8bof the coupling electrode assembly8takes place, so that the first portion8ais charged via the conductor portion8cin order to influence the measuring field generated exclusively by the first electrode5a.In the embodiment shown inFIG. 4b, the detection device2is configured with a mutual-capacitance design, at a time of the electrode5agenerating a measuring field. That is, the first electrode5a,to which a potential V1 is applied, is associated with a counter-electrode with the counter-potential E1, with the measuring field forming between the two. The second electrode5cis also associated with a counter-electrode to which the potential E0 is applied, and the second portion8bof the coupling electrode assembly8is coupled into the field formed between the two, also referred to as the coupling field.

FIG. 5shows another embodiment in which, in contrast to the embodiments ofFIGS. 1 to 4b, the coupling electrode assembly8is synchronously moved along with the handling means3, not completely, but only partially. The stationary part of the coupling electrode assembly8has several conductor portions8dprovided for each position to be detected, which are stationary relative to the detection surface10, extend substantially orthogonally relative to the detection surface10and are electrically insulated from one another, and whose end faces, on the one hand, are disposed most closely adjacent to one of the electrodes5a,5dof the detection device2, and whose opposite end face, given a corresponding position of the handling means2, faces most closely adjacent towards the part of the coupling electrode assembly8attached to the handling means. Thus, given a corresponding position of the handling means3, a capacitive coupling15aand15brespectively forms between the stationary part8dof the coupling electrode assembly8and the moved part8cof the coupling electrode assembly8. Alternatively, this capacitive coupling15a,15bcould be realized by a sliding contact, i.e. an electrically conductive contact.

The corresponding equivalent circuit diagram for the two possible designs of the detection device4is shown, with respect to the self-capacitance structure, inFIG. 6a, and with respect to the mutual-capacitance structure, inFIG. 6b, which differ from the equivalent circuit diagrams of theFIGS. 4aand 4bonly in the capacitive couplings15aand15band the additional capacitances C11and C01.