EP2742406A1 - User interface with an input object and method for the computer-assisted control of a user interface - Google Patents

Abstract

The invention relates to a user interface comprising a touch-sensitive touch screen, a special token being placed thereon. Said token comprises two disks which are interconnected by means of a ball bearing and which enable a rotation to be directly recorded by means of the token and by a rotation controller. The guiding of the rotation by the ball bearing enables the input object to have a particular haptic quality. Said ball bearing enables values to be modified rapidly up to a free running state when the upper element is accelerated and the rotation is continued once the user releases the input object based on the low friction resistance in the ball bearing, but also very precise, small adjustments in which the token provides a step-by step modification and/or screening of the rotation, such that the user receives, for each modified unit, a discrete haptic resistance via the finger-tips. Any parameters can be adjusted in a fast and efficient manner due to the tokens. The structure of a technical system can be reproduced on the touch screen, the parameters of corresponding elements of the technical system being visualized and can be modified by annular elements.

Description

description

User interface with an input object and method for the computer-aided control of a user interface

The invention relates to a user interface with an input object.

Touch-sensitive touch screens in the form of touch or multi-touch displays are used in a variety of applications for the reproduction and manipulation of information. With such touchscreens various operator actions can be performed on the touch of a user. One possible control action is to change encryption parameters via the touch of the touchscreen, for example via a keyboard displayed on the touchscreen or the plus / minus arrows, over which can be riiert the value of a parameter va ^¬. It proves to be disadvantageous that the setting of the value is often associated with a multiplicity of contact interactions of the user, which can easily lead to errors in the input.

User interfaces for setting management variables can today be found in control rooms of a wide variety of technical systems, such as power plants or factories. They serve primarily the monitoring, the diagnosis and the intervention in the respective technical processes. Thus, an essential task of the operators, i. the operator of the user interfaces in the control room, in the control of critical process variables such as Current loads, number of revolutions, pressure, temperature or level of elements of the respective technical system.

To set these process variables, the operator adjusts associated command values, which are then transmitted from the user interface to the respective technical systems. The term "reference variables" will be used below in the context of the regulation both fixed setpoints understood and time-varying set points (ie Zielfunktio ^¬ NEN). The term is intended to include other variables in the control loop also because it may be useful to adjust control ^¬ sizes or manipulated variables of individual control loop elements by hand, or even sualisieren to vi itself directly controlled variable and control.

In the latter case, the operator is given the control variable via the user interface. He indicates through an interaction that he wants to increase the controlled variable, whereupon suitable setpoint values are output to the technical system in the background until the controlled variable has completed the desired increase. Furthermore, the term reference variable should also include those input variables and manipulated variables, which are provided for easy control without feedback, i. without regulation, issued by elements of the technical system to them. The reference variables can also specify intervals in which the actual value of the controlled variable may move. Furthermore, the reference variables can also be defined for fixed times or for predetermined periods of time. For complex systems, hundreds or thousands of reference variables of all types mentioned can be used.

In other technical fields reference variables must be set by user interfaces for each system - as an example of the medical regulating the flow rate of a Saugspülvor ^¬ direction for phacoemulsification in eye surgery may suffice here. This is reali ^¬ Siert for example by a rotary control. In control rooms Windows-based user interface of ^¬ len are common, representing process variables or control elements in the form of icons on an investment plan or diagram in virtual windows. In a first operating step uses the operator for selection of a Pikto ^¬ program as an input device, a mouse, via which it positions a mouse pointer over the icon ^¬ and confirmed this by pressing a button click. Subsequently, information about plant and / or process states associated with the icon is opened in a virtual control window. There, the respective process variables can be set or at least influenced directly by the operator in a second operating step, by setting suitable reference variables. For example, pressure or temperature in a boiler can be changed in this way.

The well-known Windows-based user interfaces also use the keyboard and mouse for the second operating step. Examples play is selected as an input box with the mouse, be ^¬ before there is a numeric value with the keyboard input. Different widgets or components of the Windows ^¬ based user interface are used for this application, allowing for example, a numeric entry or an incremental orientation or decrement a value by keyboard or mouse click.

In the field of mobile devices for the end consumer is known about the iPhone, which allows a touch-based input. The iPhone represents numeric values, such as a Ka ^¬ calendar date, with a "picker" element on virtual reels which can scroll a user to select the desired data vertically. Furthermore, from the document "Orbita Mouse: Product Tour", available on the Internet on 19.10.2011 under

htt: // www. orbitamouse. com / product tour. php, a wireless mouse known which consists of two about a rotational axis against ^¬ mutually rotatable members which are connected to each other via a gellager Ku. The mouse uses a compass to detect a rotation of the top element. About a small rotatable wheel at the top can The rotation can be controlled with just one finger, which allows a very fast scrolling with the mouse.

It is an object to provide a user interface with an input object and a method for controlling a user interface, which enables a more efficient setting of reference variables.

This object is achieved by the user interface according to patent claim 1 or a method for controlling a user interface according to claim 24. Erbil far ^¬ developments of the invention are defined in the dependent claims. The user interface according to the invention comprises a with ^¬ means of contact operated by a user tactile screen and a microprocessor, via which the user interface for setting a number of parameter vectors (ie, groups of parameters) each consisting of one or more parameters may be operated in which on the touchscreen the values of the parameter or parameters are visualized from a parameter value range assigned to the respective parameter and can be set by an operator of the user.

The user interface is characterized in that it comprises a loose input object which is placeable on the touch ^¬ screen and there operated, the input ^¬ object itself is configured to detect a rotation of at least part of the input object and a rotation angle for the rotation to determine.

Furthermore, the microprocessor is programmed so that a respective parameter vector on the touch screen by a number of parameters of the respective parameter vector corresponding number of ring elements is displayed so that they enclose the input object, wherein a respective ring ^¬ element is associated with a parameter and as at least one Part of a ring is played. In a preferred variant, a ring element is shown as an entire ring with an ^angular extent of 360 °. The values of the parameter from the parameter area for each ^¬ weiliges ring element are encoded according to the invention about positions along the circumference of each ring member. The parameter is set as a function of the determined angle of rotation to the value of the corresponding position along the circumference of the respective ring element.

A rotation, for example, of an upper half of the input ^object thus acts to set the parameter as a function of a rotation angle determined for the rotation to the value of the corresponding position along the circumference of the respective ring element.

In the method for computer-aided activation of a user interface, the latter comprises a tactile screen that can be operated by a user and a microprocessor. The latter sets a number of parameter vectors on the touch screen, each consisting of one or more parameters, by visualizing on the touch screen the values of the parameter (s) from a parameter value range assigned to the respective parameter and setting them in dependence on an operation of the user.

The method is characterized in that a loose object A reproducing ^¬ which placed on the touchscreen, where loading is used, detects a rotation of at least part of the Eingabeob ^¬ jekts itself and it will transmit a rotation angle for the rotation ^¬. The microprocessor provides a respective parameter vector on the touchscreen so by one of the number of parameters of each parameter vector corresponding number of ring members is that they are the input object encloses ^¬ SEN, wherein a respective ring member is supplied ^¬ assigns a parameter and as at least a part of a ring again gege ben ^¬ is. The microprocessor encodes the values of the parameter from the parameter value range for a respective ring element over positions along the circumference of the respective ring element. Furthermore, the microprocessor adjusts the parameter to the value of the corresponding position along the circumference of the respective ring element as a function of the determined angle of rotation.

The user interface according to the invention allows a simple and intuitive change of parameters via a corresponding rotation of, for example, an upper shell of the Eingabeob ^¬ jekts. This is made possible by the fact that on the Umfangspo- of the ring member sitions the values from the Parameterwertebe ^¬ range of the parameter are coded. The user interface and the method have the ^advantage that, in contrast to an operation by means of an ordinary mouse and keyboard, a reality-related manipulation of the reference variables becomes possible since the input object interacts directly and context-related on the touch screen. The use of a rotary knob is well-known from everyday life, so that here a model from the real world is used. This increases immediate physical experi- ence of the leaders in the hiring and allows an expectation-compliant interaction.

Furthermore, the optional omission of keyboard and mouse offers the advantage of collaborative working, since access is no longer limited to an input medium, which can only serve one person at a time. Instead, a synchronous multi-user input is made possible, which are particularly well supported in the necessary si ^¬ cherheitskritischen applications quick access. Especially in the case of abnormal operating conditions, synchronous multi-user input at planning tables or other workplaces unfolds their full potential.

However, the synchronous multi-user input is only possible through the user interface and the method, since they are the Provide the required interaction concept and thus enable the use of a planning table. The Ver ^¬ drive and the user interface to meet the high demands ^¬ in terms of safety and work efficiency, which makes the use in control rooms or control rooms with them.

Decisive here is the ability to enter both quickly and accurately using the Benut ^¬ cut spot and process control variables. Previously known interaction concepts such as the aforementioned "picker" element of the iPhone prove to be inadequate in this respect, since the gestures used set the values either too slow or too uncontrolled.

In the inventive user interface of Para ^¬ meter range of values of the corresponding parameter is given by a predetermined sequence of values. Preferably ^¬ the these values in accordance with this order on the circumferential of the parameter associated ring member (that is, against the clockwise or counterclockwise) as shown. The parameter value range can refer to any variables. In a particularly preferred embodiment, the parameter value range of one or more parameters of at least one parameter vector is given by a numerical value range.

In a preferred embodiment, at least one parameter vector comprises a numerical value of the digits before the decimal place and the decimal places, the decimal place and the decimal place representing respective parameters of the parameter vector.

These can thus be adjusted according to the invention via separate ring elements in a suitable manner, so that a fine adjustment of the corresponding numerical value is achieved.

In a further, particularly preferred embodiment, the extent of a respective ring element in the circumferential direction extends the entire parameter value range of the ring to ring element. Element associated parameter coded. In this way the loading ^¬ user visually conveyed in a simple manner the parameter value range on the extension of the ring members. For example, this represents a considerable advantage over the "picker" element of the iPhone.

In a further embodiment of the user interface according to the invention comprises at least one parameter vector several ^¬ re parameters, the parameters associated with the Ringele- elements are arranged concentrically around the input object.

This results in a compact representation of the adjustable parameters Pa ^¬ a parameter vector is achieved on the touchscreen.

In a further embodiment of the invention corresponding value of Pa ^¬ rameters in textual form (ie, based on Schriftzei ^¬ Chen and particular numerical figures) displayed on one or more positions along a respective annular element of the respective position, thereby be given to the user indications, how the values of the parameters change with the rotation of the contact element.

In a further variant of the invention, the set values of the parameters on the tactile screen are also reproduced in textual form, so that the user is provided with the

Manipulation of the touch element immediately visually receives a return message ^¬ over the value just set.

According to an embodiment, by touching a region on the touch screen, each of the parameters for adjustment can be selected. For example, a decimal place or a decimal place can be selected by simply tapping on associated numerical values or also of the respective ring elements on the touch screen for subsequent adjustment. This embodiment is particularly advantageous since it allows to assign several concentric rings around the input object at ^¬ and to adjust with an input object in place un ^¬ terschiedliche parameters. In a further preferred embodiment of the user interface according to the invention, the segment of each ^¬ weiligen ring member between the initial value of Parameterwer- ues Eich and the set value of the parameter ent ^¬ speaking position on the circumference of the ring element is highlighted visually. The segment thus represents a corresponding sector of a ring. For example, this segment is displayed in a different color from the rest of the ring element. In this way, the current value of the parameter of the corresponding annular ^combustion element can be played back in the manner of filling state.

In a preferred variant, the parameter or parameters of a respective parameter vector comprise reference variables of a technical system, wherein the user interface interacts with the technical system via an interface in such a way that it transmits newly set reference variables to the technical system, whereupon the technical system controls the new settings or regulation takes over.

In a further, particularly preferred embodiment, the touch screen of the user interface can be operated such that a structure of a plurality of elements and in particular a technical system is reproduced on the touch screen, whereupon a user can select the respective elements via a user interaction, whereupon for a number of parameter vectors, which are assigned to the selected element, is switched to the setting mode. In this mode, the parameters of the corresponding parameter vectors can then be visualized via ring elements as described above and contact elements can be adjusted.

The technical system which is reproduced on the touch screen or whose parameters are set can relate to any fields of application. In a preferred variant, the structure represents a technical plant, the term of the technical plant is to be understood widely and a branched network of various technical components may include, for example, a power system, a Energieverteilanlage, Telekommunikationsanla ^¬ ge, a traffic monitoring system, a Flugsicherungsanla- ge, a train control system, a traffic control system, a factory, a process plant, an automation ^¬ tion system, a heating system , a home automation ^¬ system, a synthesizer, a medical device or more of these systems or systems.

In a further development of the touchscreen is designed as a tray, monitor, table, flat screen or projection screen. In one embodiment, the input object Minim ^¬ least a switch. By pressing the switch, at least one of the parameters for setting can be selected. For example, one number or a fractional number ^¬ point associated values are selected by operating a pressure switch on the input object for subsequent SET ^¬ lung. This embodiment is particularly advantageous since it allows concentric arrangement of several rings around the input object and thus sets different parameters with an input object in place. The input object thus provides input elements for all ^necessary interactions. Interactions by touching the tactile screen become optional or can be omitted altogether. In a development, the switch is arranged on the input object. Alternatively, the switch is within the input object and can be actuated by pressing on the top of the input object. According to one embodiment, the input object consists of two elements which are rotatable relative to one another about an axis of rotation and which are connected to one another via a ball bearing. This embodiment has numerous advantages. So be it comes by guiding the rotation through a ball bearing the input object itself a special haptic quality. The ball bearing one hand allows very rapid changes in value to a free wheel, when the upper member accelerate is nigt and also continues after a release by the user's rotation due to the low frictional resistance in the ball ^¬ stock, on the other hand a very precise fine tuning ^¬ positions by the ball bearing or the input object is a gradual change or rastering of the rotation of readiness, so that the user perceives ^¬ a subtle haptic resistance across his fingertip for each changed unit. Thus, the input object achieved by this exporting ^¬ approximate shape the high tactile quality traditional setting parts ^¬. This haptic quality makes even complex processes tangible and ultimately comprehensible. In contrast to a stationarily installed control part, however, the loose input object can be arranged flexibly on the touch screen, as a result of which it can be used in a wide variety of contexts.

In one development, an interaction element, in particular a rotatable gela ^¬ gertes element (for example, a small rotatable wheel), arranged on the surface of the input ^¬ object, via which a rotation of the mutually rotatable elements with a fingertip is adjustable. Thus, a rotation of the upper element can be very easily initiated with just a fingertip by the user.

According to one embodiment, the input object is equipped with a drive, via which the mutually rotatable elements are rotated against each other. The drive is, for example, a small electric motor. Via the drive, the upper element of the input object can be rotated, for example, to set it according to a value of a Paramater. This offers itself just when a mark ^¬ is drawn on the edge of the input object, which with the representation on the touch screen and even if the parameter changes independently of user operation.

Alternatively or additionally, the input object can be moved via a drive on the touch screen. Thus, the input object can independently drive to the space required for the next interaction or visualization on the touch screen. In a further development of the input object with a wire-less interface ^¬ is equipped for communication with the user interface. About the interface, a rotation angle, which determines the input object itself, but also an authentication information to the microprocessor of the user interface are transmitted.

According to one embodiment, the input object is equipped with a compass for determining the angle of rotation. This is a possible implementation of how the input object can autonomously determine the rotation angle itself. One advantage is that an external determining the rotation angle can be eliminated by a bar code on the bottom of entranc ^¬ beobjekts and camera tracking at ^¬ play as. In one development, the input object is equipped with a light source ^¬, a display, a speaker and / or a vibrating element. In this way, the input ^¬ object can acknowledge a status, a set value, available for selection parameters or similar issue or the interactions of the user visual, acoustic or haptic itself.

According to one embodiment, the input object is equipped with a fingerprint sensor. This allows the user to be authenticated. The result will be over the wireless

Interface communicates to the microprocessor of the user interface, after which personalized features or Be ^¬ authorizations of the user interface will be unlocked. Alternatively or additionally, a user-specific protocol of its operator actions can also be stored.

A computer program is stored on the computer-readable medium, which executes the method when it is executed in a computer.

The computer program is processed in a computer and executes the procedure.

Embodiments of the invention are described below in detail with reference to the accompanying drawings.

Show it:

FIG. 1 shows a schematic illustration of an embodiment of a user interface,

FIG. 2 shows a representation of an embodiment of a user interface in the form of a planning table,

FIGS. 3-7 are illustrations of the operation of the user interface of FIG. 1 or 2 in setting parameters according to an embodiment of the invention;

FIG. 8 shows a hardware solution for recognizing input objects and touches of a user, and FIG. 9 shows labels for supporting the input object recognition.

1 shows an exemplary embodiment of a plan view of a touchscreen 5, on which a virtual user interface 1 is shown. This contains a network-like structure of a plurality of elements E (eg in the form of pictograms). Depending on the application, the network-like structure can relate to any system or system. par- particular may be the representation of a power generation ^¬ and Energieverteilanlage to a telecommunications system for a power plant, a process plant to act ei ^¬ ne traffic monitoring system and the like. Preferably, the touch screen 5 is a control table, which is set up in a control room for monitoring the corresponding system or the corresponding system. The individual ele ^¬ ments E are components of the corresponding network or the corresponding system. About the tactile screen 5, a human operator (or team of operators) to monitor the operation of the plant and alter suitably entspre ^¬ sponding parameters of the individual elements shown e. This is achieved in the embodiment of FIG. 1 in that the operator taps with his finger a corresponding element E whose parameter he wants to change, whereupon the placeholders C shown schematically in FIG. 1 are displayed to him. Each individual placeholder C is composed of annular elements, which will be described in more detail with reference to FIGS. 3 to 7. Within the annular elements is provided an area for the placement of a physical, loose input object, which will also be described in more detail with reference to the further figures. On the respective placeholder C, a command variable or any other desired value or parameter can be changed simply and intuitively with the aid of the input object.

One of the placeholders C of the correspondingly selected element shown in FIG. 1 is reproduced in an enlarged form in FIGS. 3 to 7. If necessary, there is also the possibility that the user can display the placeholder C in a separate area of the touchscreen 5 in an enlarged manner via a suitable interaction. Likewise, a new ^¬ image on the touch screen 5 can be constructed with an enlarged view of the placeholder C.

Figure 2 shows an embodiment of a user interface ^¬ point for setting at least one control variable of a technical system 7. The system 7 comprises technical examples For example, a power supply system, a Energiever ^¬ teilanlage, a telecommunications system, a Verkehrsüber ^¬ monitoring system, an air traffic control system, a Bahnleitsys ^{¬ system} , a traffic control system, a factory, a procedural plant, an automation system, a Hei ^¬ tion system, a home automation system, a Synthesi ^¬ zer, a medical device or more of these systems or systems. FIG. 2 again shows a touch screen 5, which is installed in a table. It is connected to a computer 9, which also has an interface 8, which is set up for egg ^¬ ner output of at least one command variable as defined at the beginning defi ^¬ ned to the technical system 7. The

Interface 8 can in this case be a wireless (eg WLAN) or wired (eg Ethernet) interface. The computational ^¬ ner 9 includes a microprocessor 6 which values of at least one reference variable visualized on a virtual user interface 1 on the touchscreen. 5 Furthermore, the microprocessor 6 is programmed to process a user interaction, which operates an input object 3, which is located on a placeholder C, wherein the value of the at least one reference variable is adjusted accordingly. As shown in FIG. 2, different loose physical input objects 3 are available on the touch screen 5 for the user interaction. The left placeholder C is occupied with no input object 3 and thus currently not operable. The right placeholder C is, however, staffed by an input object 3, which allows the use of this placeholder C as un ^¬ th described. The placeholder C can be displayed in a fixed position on the virtual user interface 1, even if there is no input object 3 on it. Alternatively, the placeholder C can dynamically on the virtuel- len user interface 1 to the input object around 3 are ^¬ displayed as soon as it is deposited on the tactile screen 5 at an arbitrary position. The input objects 3 can be configured for example as a palm-sized ^¬ SSE cylindrical body. In this interaction concept, they resemble a movable control element. Gege ^¬ appropriate, they are glued shown on its underside with a label as in Figure 9, whereby they can be identified and their position (and orientation) on the touchscreen using the 5 can be detected in figure 8 shown technology. An imprint of the label or an additional RFID tag on the input object 3 can also be used to identify and authenticate its owner relative to the user interface. These features are optional. Hereinafter, the variation of a command value performed via the placeholder C based on the setting of a numerical value between 0.0 and 99.99 will be described with reference to FIGS. 3 to 7. The reference variable is described here ^¬ at by a parameter vector PV. The parameter vector PV is, for example, in two parts and consists of a digit before and after the decimal point. It could also be in three ^parts and contain eg red, green and blue values for a color mixture. The interaction element 13 shown in FIGS. 3, 4 and 5 is described in FIG. 5 on behalf of FIGS. 3 and 4.

The invention is not limited to numerical values and it is also possible to set any other parameters and values via the placeholder C. For example, letters C of an alphabet or operating modes could be applied and selectable around the placeholder C in a clockwise direction. According to FIG. 3, a placeholder C comprises an outer ring R1 and an inner ring R2, wherein the outer ring R1 represents the predecessor position PI and the inner ring R2 represents the decimal place P2 of the parameter vector PV. When the rings are it become virtual image content that Darge ^¬ provides dynamically as part ei ^¬ ner virtual user 1 on the tactile screen. The value of the parameter vector PV is shown in the upper right next to the placeholder C in textual or numerical form. In the scenario of FIG. 3, the pre-decimal point PI is set to the value 11 and the decimal point P2 to the value 14. The rings are arranged concentrically around an input object 3, and the entire circumference of the rings encodes the corresponding value range of the digit before or after the decimal point of the parameter vector PV. That is, 360 ° of the outer ring Rl correspond to the range of values of the precompression point between 0 and 99, whereas 360 ° of the inner ring R2 corresponds to the value range of the fractional part between 0 and 99.

The current value of the place of the decimal place or decimal place is intuitively indicated by the highlighting of respective ring segments. A first ring segment RS1 for the digit before the decimal point is shown in FIG. 1 as well as a second ring segment RS2 for the fractional part. The highlighting can be achieved by a representation of the segment in a separate, different from the rest of the ring color. To clarify the range of values in which the digit before the decimal point or the decimal point can be moved, four, 90 ° offset from each other text fields are shown at the outer edge of the ring Rl further, which are designated by reference letter T. It can be seen that an angular position of 0 ° corresponds to the numerical value 0, an angular position of 90 ° to the numerical value 25, an angular position of 180 ° to the numerical value 50 and an angular position of 270 ° to the numerical value 75.

The change of the digit before the decimal place or the decimal place of the parameter vector PV takes place by rotating at least part of the input object 3. According to FIG. 3, a user wants to change the digit before decimal point PI. Replaced by the rotation of an upper half of the input object 3 in the clockwise or the clockwise ent ^¬ against the value of the decimal point is increases or decreases. The current value of the position before the decimal point is visualized by the size of the first ring segment RS1. This is highlighted in color relative to the second ring segment RS2, as indicated in Figure 3 by the crossed hatching. These colored high ^¬ elevation and a bold or colored marking of the decimal point PI of the parameter vector PV on the virtual Benutzeroberflä ^¬ che 1 textual or numeric shown inform the user by the fact that currently the Vorkom- mast parts PI (and not the decimal P2) Turning example, an upper shell of the input object 3 can be adjusted.

In the scenario of Figure 4 (the same reference symbols in this case denote the same elements as in Figure 3) of the Benut ^¬ zer has rotated the input object 3 at an angle, whereby the decimal point has changed PI of the parameter vector PV from the value 11 to the value 19 , The manipulation of the decimal point PI is thus carried out

Rotation of at least part of the input object 3. Here, the common direction code (clockwise) is used, ie a clockwise rotation increases the value. In Figure 5 (same reference numerals denote the same elements as in Figure 3 and Figure 4), the Benut ^¬ zeroberfläche 1 of the touch screen is shown in an oblique view, so that the input object 3 is recognizable in its cylindrical shape. Here the user has set the parameter vector to 57.19. Currently the digit of the prefix is PI

Rotation of the input object 3 is adjustable because it is highlighted in color together with the first ring segment RS1.

According to one embodiment, the input object 3 has at least one switch, for example a pressure switch. By pressing the switch, for example, the pre-decimal place or the decimal place can be selected for setting. The input object 3 thus provides input elements for all necessary interac- ready. Interactions by touching the touchscreen 5 (see Figure 6) are optional or can be omitted entirely. The switch is arranged, for example, on top of the input object 3. Alternatively, the switch is within the input object 3 and can be operated by pressing the top of the input object 3. As shown in FIG. 5, the input object 3 consists of two disks (or shells or other components) which are rotatable relative to each other about a rotation axis and which are connected to one another via a ball bearing. In a further development of an interaction element 13, in particular a rotatably mounted element (for example, a small rotatable wheel) arranged on the surface of Eingabeob ^¬ jekts 3 via which a rotation of the gegenein ^¬ other rotatable discs with a finger tip is easily adjustable. This allows a rotation of the upper

 Very easy to initiate the disk with just a fingertip by the user.

According to one embodiment, the input object 3 is equipped with a drive, via which the mutually rotatable discs are rotated against each other. The drive is, for example, a small electric motor. The drive can be used to rotate the upper pane of the input object, for example, to set it according to a value of a paramater. This is useful especially appropriate when a mark is turned ^¬ distinguished on the edge of the input object 3, which is intended to correlate with the display on the touchscreen 5, and even if the parameter changes irrespective of a user's operation.

Alternatively or additionally, the input object 3 can be moved via a drive on the touch screen. Thus, the input object can independently to each for the next interaction or visualization on the touch screen 5 required space drive.

In a further development, the input object 3 is equipped with a wireless interface for communication with the user interface. About the interface, a rotation angle, which determines the input object itself, but also an authentication information to the microprocessor of the user interface are transmitted.

According to one embodiment, the input object 3 is equipped with a compass for determining the angle of rotation. This is arranged for example in the upper disc. This is a possible implementation of how the input object 3 can autonomously determine the rotation angle itself. One advantage is that an external determining the rotation angle 3 can play be dispensed by a bar code on the bottom of entranc ^¬ beobjekts and camera tracking at ^¬. The input object 3 has a microprocessor of its own, through which the rotation angle is determined and communicated to the microprocessor 6 of the Benut ^¬ cut point using the wireless interface of the ^¬ le of the input object. 3

In a further development, the input object 3 is equipped with a light source, a display, a loudspeaker and / or a vibration element. In this way, the A ^¬ reproducing object itself visual, acoustic or haptic acknowledge a status, a set value, available for selection parameters or similar output or user interactions.

According to one embodiment, the input object 3 is equipped with a fingerprint sensor. This allows the user to authenticate. The result will be over the wireless

Interface of the input object 3 communicates to the microprocessor 6, the user interface, whereupon personalized ^¬ catalyzed functions and privileges of the user interface will be unlocked. Alternatively or additionally Also a user-specific protocol of his Bedienhand ^¬ lungs are stored.

Figure 6 (in this case, like reference numerals designate the same elements as in FIG chen 3 to 5) shows a variant of how a user PI to adjust the decimal place P2 wech ^¬ clauses can with his hand 2 of a setting of the decimal point. He touches with a fingertip of his hand 2 the representation of the decimal place P2 on the virtual user interface 1 or alternatively the inner ring R2.

Then the decimal P2 and the second annular ^combustion segment RS2 is particularly highlighted in order to inform the user that he now sets the decimal P2 (and not the decimal PI). The second ring segment RS2 (as well as the first ring segment RS1) operates as a level indicator and, like the value of continuously updated After ^¬ decimal point P2 upon rotation of the input object. 3 Subsequently, the user sets as shown in Figure 7 (same Be ^¬ reference numbers in this case denote the same elements as in Figure 3 to 6) shown the value of the decimal point P2 by rotating at least a portion of the input object 3 to the value 64 a.

The embodiments of the invention described above have a number of advantages. By coding corresponding values from a range of values to the circumferential position of the rings and changing these positions by rotating at least part of the input object, the corresponding parameter value can be changed simply and intuitively. As a visual feedback to the just one ^¬ detected value highlighting the corresponding to the set value ring segment serves. The user interface allows for a hybrid interaction as it is an indirect

Interaction by rotation of the input object with direct touch of the touch screen connects to select the parameters to be set. FIG. 8 shows an exemplary embodiment of a touch screen 5. For the realization of the touch screen 5, known technologies can be used. For example, the touch screen 5 in a housing 12 may comprise an optical system on its underside, which is realized by rear projection. In this case, the back of the touch screen 5 is illuminated as shown in Figure 8 with infrared radiators 9. Touches by an input object 3 or a hand 2 on top of which can be followed based on the change of the Reflection ^¬ onsverhaltens a high-resolution camera 10 with an infrared filter. 11 In this case, the input object is clipped or printed at ^¬ example with one of the labels or barcodes of Figure 9 with the corresponding patterns on its underside. Based on this pattern, a microprocessor from the image of the camera 10 in Figure 8 calculate a position and ^¬ direction of the input object 3 on the touch screen 5. Here, a rotation angle through which the Eingabeob ^¬ ject is rotated around its Lot 3 could very easily calculated, but this is accomplished according to the other embodiments by the entranc ^¬ beobjekt 3 itself. When the input object ^¬ 3 slightly offset to one side in the rotation (which the user may not intended) can also this displacement ^¬ environment are detected by the microprocessor in real time. Advantageously, then the associated Platzhal ^¬ ter C and the rings, etc. are also moved on the virtual Be ^¬ user surface 1, so that they continue to surround the input object 3 concentric. Alternatively, the input object 3 may be held in place by a built-in magnet and a corresponding magnet in or under the touch screen 5.

The respective pattern also allows an identification of the input object 3 or its owner, whereby protected functions of the user interface for an authorized owner of the input object 3 can be unlocked. The user recognition also makes it possible for the respective user to have an individual view, for example on a tech- niche attachment and, depending on its permissions, on the virtual user interface 1. The Be ^¬ user recognition, the input object 3 but also provide even over its wireless interface, as described above.

By the user depositing his input object 3 on the touch screen 5 on a placeholder C (see Figures 1 to 7), whereupon it is recognized according to Figure 8 and 9 on the basis of a pattern on its underside, the input object 3 provides a spatial reference between the real and the virtual world of the virtual user interface 1.

Another way to recognize the pattern is in the so-called pixel-sense technology, in which the touch screen 5 is designed as an LCD, LED or OLED display and sit in each pixel of the touch screen 5 infrared sensors, on which touches the surface can be detected by the change in the reflection behavior. Possibly. There is also the possibility that the touch screen 5 is realized in a conventional manner by a capacitive touch surface, as is commonly used in smart phones.

Since the input object 3 itself determines the angle of rotation, pattern recognition, as described for FIGS. 8 and 9, can also be dispensed with altogether. In this case, a simple tactile screen, which can be multi-touch capable, but this is not necessary. The described embodiments, developments and embodiments can be combined freely with each other.

Claims

claims

1. user interface with an input object,

 with a tactile screen (5) which can be operated by a user, and

with a microprocessor (6), via which the user interface for adjusting consisting may be operated in each case one or more ^¬ ren parameters (PI, P2) of a number of parameter vectors (PV), adding to the tactile screen (5), the values of the one or Parameters (PI,

P2) can be visualized from a parameter value range assigned to the respective parameter (PI, P2) and can be set by an operator of the user; characterized in that

- The user interface comprises a loose input object (3), which on the touch screen (5) can be placed and operated there, wherein the input object (3) is itself set to detect rotation of at least a part of the input object (3) and a rotation angle for to determine the rotation

and the microprocessor (6) is programmed to

 a respective parameter vector (PV) on the touch screen (5) by one of the number of parameters (PI, P2) of the respective parameter vector (PV) corresponding number of ring elements (Rl, R2) is shown so that they enclose the input object (3) wherein a respective ring element (R1, R2) is associated with a parameter (PI, P2) and is represented as at least a part of a ring,

- the values of the parameter (PI, P2) from the Parameterwer ^¬ ues calibrated for a respective ring member (Rl, R2) about positions along the circumference of the respective annular element (Rl, R2) are coded,

the parameter (PI, P2) is set as a function of the determined angle of rotation to the value of the corresponding position along the circumference of the respective ring element (Bl, B2).

2. User interface according to claim 1, wherein the parame ^¬ terwertebereich one or more parameters (PI, P2) is provided at least one parameter vector (PV) by a numerical value range.

3. User interface according to one of the preceding claims, wherein at least one parameter vector (PV) comprises a numeric ^¬ value from the decimal place and decimal place, the Vorkomasteile and the decimal place respective Pa ^¬ parameters (PI, P2) of the parameter vector (PV) represent, which on ring elements (Rl, R2) on the tactile screen (5) again gege ^¬ ben be.

4. User interface according to one of the preceding claims, wherein by the extension of a respective ring element (Rl, R2) in the circumferential direction of the entire parameter value range of the ring element (Rl, R2) associated Parame ^¬ ters (PI, P2) is encoded.

5. User interface according to one of the preceding claims, wherein at least one parameter vector (PV) comprises a plurality Pa ^¬ parameters (PI, P2) and the parameters (PI, P2) to ^¬ parent ring elements (Rl, R2) concentrically about the input ^¬ object (3) are arranged.

6. User interface according to one of the preceding claims, wherein at one or more positions along a respective ring element (Rl, R2) of the respective Posi ^¬ tion corresponding value of the parameter (PI, P2) is reproduced in textual or numerical form.

7. User interface according to one of the preceding claims, wherein the set values of the parameter or parameters (PI, P2) on the touch screen (5) are also reproduced in textual or numerical form.

8. User interface according to one of the preceding claims, in which each of the parameters (PI, P2) for adjustment can be selected by touching a region on the touch screen (5).

9. User interface according to one of the preceding claims, wherein the segment of the respective ring element (Rl,

R2) is visually emphasized between the initial value of the parameter value range and the position corresponding to the set value of the parameter (PI, P2) on the circumference of the ring element (R1, R2).

10. User interface according to one of the preceding claims, wherein the touch screen (5) can be operated such that on the touch screen (5) a structure of a plurality of elements (E) of a technical system (7) is reproduced, wherein a Users the respective elements

Can (E) via a user interaction, select, after which for a number of parameter vectors (PV) that the selected element (E) are associated with enabling an adjustment is ^¬ light.

11. User interface according to one of the preceding claims, wherein the parameter or parameters (PI, P2) include a jeweili ^¬ gen parameter vector (PV) command variables of a technical facility (7), wherein the user interface via egg ne interface (8) is connected to the technical system (7) interacts so that it transmits newly set reference values to the technical system (7).

12. User interface according to claim 10 or 11,

in which the technical facility (7) a Energieversorgungsan ^¬ location, a Energieverteilanlage, a Telekommunikationsanla ^¬ ge, a traffic monitoring system, a Flugsicherungsanla ^¬ ge, a path control system, a road traffic control system, a factory, a process plant, an automation system, a heating system, a home automation ^¬ system, a synthesizer, a medical device or more of these systems or systems includes.

13. User interface according to one of the preceding claims,

in which the tactile screen (5) as a tray, monitor, table,

Flat screen or projection screen is executed.

14. User interface according to one of the preceding claims,

in which the input object (3) at least has a switch ^¬, and is selectable by operating the switch when at least one of the parameters (PI, P2) for setting.

15. User interface according to claim 14,

in which the switch is arranged on the input object (3) and / or can be actuated by pressure on the upper side of the input object (3).

16. User interface according to one of the preceding claims,

in which the input object (3) consists of two elements which are rotatable relative to one another about an axis of rotation and which are connected to one another via a ball bearing.

17. User interface according to claim 16,

wherein the surface of the input object (3) an interaction tion element (13), particularly a rotatably mounted Ele ^¬ element is arranged, via which a rotation of the rotatable against each other ^¬ elements with a finger tip is adjustable.

18. User interface according to claim 16 or 17,

in which the input object (3) is equipped with at least one drive, via which the mutually rotatable elements are rotatable relative to each other and / or via which the input object (3) on the touch screen is movable.

19. User interface according to one of the preceding claims, in which the input object (3) with a wireless interface ^¬ for communication with the user interface being ^¬ is upgraded.

20. User interface according to one of the preceding claims,

in which the input object (3) is equipped with a compass for the determina tion ^¬ angle of rotation.

21. User interface according to one of the preceding claims,

in which the input object (3) is equipped with a light source, a display, a loudspeaker and / or a vibration element.

22. User interface according to one of the preceding claims,

in which the input object (3) is equipped with a fingerprint sensor.

23. input object (3),

which is adapted for use with a user interface according to any one of the preceding claims.

24. A method for computer-aided control of a user interface, which comprises a touch-operated by a user touch screen (5) and a microprocessor (6), which

on the tactile screen (5) a number of parameter vectors (PV) sets each consisting of one or more Parame ^¬ tern (PI, P2) pointing to the tactile screen (5), the values of the parameter or parameters (PI, P2) of a visualized, the respective parameter (PI, P2) assigned parameter value range and sets a function of a loading ^¬ dienung of the user;

characterized in that

a loose input object (3) which is placed on the touchscreen (5) and operated there, a rotation at at least a part of the input object (3) recognizes itself and determines a rotation angle for the rotation,

and the microprocessor (6)

a respective parameter vector (PV) on the tactile screen (5) so by one of the number of parameters (PI, P2) of the respective parameter vector (PV) is appropriate number of ring elements (Rl, R2), to the A ^¬ transfer object (3) enclose, wherein a respective ring ^¬ element (Rl, R2) is associated with a parameter (PI, P2) and is displayed as at least a part of a ring,

the values of the parameter (PI, P2) from the Parameterwer ^¬ ues calibrated for a respective ring member (Rl, R2) along the circumference of the respective annular element (Rl, R2) about positions encoded and

as a function of the determined angle of rotation sets the para ^¬ meter (PI, P2) to the value of the corresponding position along the circumference of the respective ring element (Bl, B2).

25. The method of claim 24, wherein the method is a user interface according to one of claims 2 to 22 is ^¬ controls.

26. Computer-readable data medium,

on which a computer program is stored, which executes the method according to claim 24 or 25, when it is executed in the microprocessor (6).

27. computer program,

which is processed in the microprocessor (6) and thereby carries out the method according to claim 24 or 25