Abstract: A method of driving an actuator using a shape memory alloy is provided. An impact-driven actuator is activated by a pulse voltage generated by an action of a transistor. A keyboard outputs a key event at the timing of an input operation. A stress monitoring unit calculates a stress amount of an impact-driven actuator based on parameters of a key event and a pulse voltage. A stress adjustment unit changes the parameter of the pulse voltage when the stress amount reaches a permissible value. The parameter may be a wave crest value or a pulse width of the pulse voltage. The stress adjustment section is also able to stop the action of the impact-driven actuator in response to a key event corresponding to a break code.

Abstract: An apparatus for driving an actuator using a shape memory alloy is provided. The apparatus includes an actuator having a shape memory alloy, a pulse signal generating device for generating a pulse signal, and a switch for applying a pseudo single pulse voltage signal to the actuator. The pseudo single pulse voltage signal is generated by performing switching control of a predetermined voltage according to a set of successive micro-pulse signals.

Abstract: A haptic touch screen including a lower layer including a plurality of control electrodes, an upper layer including a plurality of haptic electrodes, a middle layer between the lower layer and upper layer, where the haptic electrodes are not conductively connected to control electronics.

Abstract: Aspects of the disclosure are directed to processing flex gesturing in a computing device that includes a plurality of display panels movable in relation to one another. Flex movement of a first display panel as detected by at least one flex sensor is assessed. The flex movement is interpreted according to predefined criteria to recognize a flex gesture. In response to the flex gesture, an action to be performed is ascertained from among a plurality of possible actions associated with the flex gesture.

Abstract: A user desires to complete a call utilizing a head-mounted display and a communication device. A call-initiating event is detected at the communication device. In response to the call-initiating event, an intended call recipient is identified utilizing the head-mounted display. A call is then initiated with the intended call recipient utilizing the communication device.

Abstract: A single pose is used in multiple postures to deliver at least a minimal core set of free space gestures for navigating within an interface, so as to be intuitive to users, easily remembered, straightforward for developers, and clearly defined for processing. A “thumb-extended” pose with fingers together and clenched and thumb extended and raised is oriented in four cardinal directions so as to manifest four distinct postures: right, left, up, and down. Thumb-right and thumb left invoke scrolling forward and scrolling back, respectively, and thumb-up and thumb-down invoke yes and no respectively.

Abstract: Methods and systems for recognition of pickup and glance gestures for a mobile device are provided. An example method includes acquiring sensor data generated by at least one sensor of a mobile device. Based on the sensor data, a particular transport mode associated with a motion of the mobile device may be determined. Based on the particular transport mode, a corresponding on/off body detector designed for the particular transport mode may be selected. The selected on/off body detector can be used to determine if the mobile device is located on or off a user's body. The example method includes, if the mobile device is determined to be on the user's body, analyzing the sensor data to detect a glance gesture. The example method also includes, if the mobile device is determined to be off the user's body, analyzing the sensor data to detect a pickup gesture.

Abstract: The present disclosure provides a method for user interaction. The method includes pointing a first device having a sensor, towards a panel defining a physical area having a plurality of markers rendered thereon, recognizing an interaction area defined by the plurality of markers on the panel, and rendering a plurality of graphical user interface elements on the panel in an Input/Output viewport. The plurality of markers includes at least one of an object and a shape recognizable by suitable computer vision means. Further, the Input/Output viewport includes a spatial volume between the first device and the panel.

Abstract: A system and method for improved detection and usability of personal electronic devices for field engineers is disclosed. A personal electronic device stores a list of commands in memory. The personal electronic device presents a user interface in a relative motion input mode, wherein the user interface in the relative motion mode is divided into a plurality of user interface zones. The personal electronic device receives relative motion input, wherein the relative motion input is received through one or more relative motion sensors of the personal electronic device. The personal electronic device determines whether the received relative motion input matches input associated with a respective command in a list of reference commands. In accordance with a determination that the received relative motion input matches input is associated with a respective command in the list of reference commands, the personal electronic device executes the respective command.

Abstract: A character input method includes receiving an input of at least one base shape and a base shape input signal from a user, generating a root shape by combining the at least one base shape input before the input of the base shape input signal, according to the input of the base shape input signal, receiving an input of an input complete signal from the user, and generating a character by combining the at least one root shape generated before the input of the input complete signal, according to an input of the input complete signal.

Abstract: Systems and methods for virtualized tangible programming are described. In an example implementation, a method includes detecting an object in image data, performing a comparison between the object and a predefined set of object definitions, recognizing the object as a visually quantified object or a visually unquantified object based on the comparison, processing a command region and a quantifier region for the visually quantified object and identifying a corresponding command, and executing a set of commands for the object.

Abstract: A method for providing a virtual keyboard displayed on a display with visual cues is provided. The method includes: receiving an input of a character from the virtual keyboard; displaying one or more sets of predicted input characters in a prediction bar displayed on the display, wherein each set of predicted input characters is located within the prediction bar at a position corresponding to a key of subsequent candidate input character in the set of predicted input characters.

Abstract: In some embodiments, apparatuses and methods are provided herein useful for detecting traffic in a shopping facility. A system for detecting traffic in a shopping facility comprises: a plurality of light emitters coupled to motion sensors configured to emit light when motion is detected by the motion sensor; a light detector having a field of view including at least one of the plurality of light emitters; a database; and a control circuit configured to obtain data from the light detector relating to light emitted from the light emitters, estimate a location of the light emitted from the light emitters based on location data associated with the light emitter stored in the database, and track a path of a customer based on successive light emissions from the light emitters.

Abstract: There is provided a cylindrical mobile data processing device comprising a first touchscreen display at a first end of the mobile data processing device; a second touchscreen display at a second end of the mobile data processing device; a data processor communicatively coupled to the first and the second touchscreen displays; and an orientation detection sensor communicatively coupled to the data processor. Methods of using the device are also provided.

Abstract: In an approach to pointer positioning, a computing device receives an instruction to enter a Move Mode. The computing device magnifies, in Move Mode, screen content to generate a virtual display. The computing device displays a first portion of the virtual display and a fixed pointer on the virtual display. The computing device receives physical movement data. The computing device analyzes the physical movement data. The computing device displays a second portion of the virtual display based on the analyzed physical movement data. The computing device receives an instruction to leave Move Mode. The computing device deactivates Move Mode.

Abstract: Systems, methods, and media for providing a multipurpose remote control are provided.

Abstract: A jog dial according to the present invention can be used in an electronic device. The jog dial according to the present invention comprises: a dial knob rotatably provided on an upper surface of an operation panel of the electronic device; an object provided on the dial knob; and a detector provided below the operation panel, and detecting the object so as to output a signal, wherein the dial knob and the detector are separated from each other.

Abstract: A resistive force sensor may be configured with two exposed pads, each exposed pad electrically connected to a terminal. When a force is applied to a force applicator, a conductive pad moves into contact with the exposed pads, thus completing an electrical circuit and providing a precise measurement of the point in time when a user has supplied sufficient force to switch the apparatus from one mode of operation to another. In another implementation, two resistive sensors may be disposed above and below portions of a conductive pad with an elastic member disposed between the two resistive sensors. When a force is applied to the force applicator of the apparatus, a differential resistance may be calculated between the two resistive sensors. Since resistive sensors may experience thermal drift due to changes in environmental temperature conditions, the differential resistance between the two resistive sensors allows a temperature-independent measurement of force.

Abstract: The present invention relates to a mouse for a computer, which is a computer input device. The mouse has an upper case with a vertical cushioning function against force imposed on the mouse, and thus can operate smoothly. The present invention provides a cushioning function to a mouse, thereby eliminating fatigue and muscle pain of the wrist and fingers even when a user uses the mouse for a long time. The mouse is manufactured by assembling an upper case and a lower case, and is configured such that a protrusion box which protrudes upwards is formed on the lower case, a boss is fixed on the lower side of the upper case and penetrates the protrusion box, thereby being joined with the same, and a spring which is supported by the protrusion box is inserted into the boss from the outside while the lower side of the boss can be prevented from being separated from the protrusion box.

Abstract: The described technology provides a force sensor apparatus. An elastic pad may be disposed between two force sensors with a force applicator extending at least partially into the elastic pad. When a force is applied to a force applicator, the force applicator transmits the force to one or both of the force sensors via the elastic pad. In an implementation, the force sensors may be resistive sensors. Since resistive sensors may experience thermal drift due to changes in environmental temperature conditions, the differential resistance between the two resistive sensors allows a temperature-independent measurement of the applied force.

Abstract: A non-transitory computer readable medium stores a program causing a computer to execute a process. The process includes: generating a first path which represents positions on a medium specified by a digital pen; obtaining a second path which represents positions on the medium specified by the digital pen and which satisfies a predetermined condition; obtaining information for specifying an area on the medium, the area having a predetermined positional relationship with the second path; and erasing the first path in accordance with a positional relationship between the area and the first path.

Abstract: An earphone plug able to be utilized as a touch stylus comprises a column base, a conductive portion, a conductive tip, and a conductive core. A grip ring connects to the column base. The conductive core and conductive wires are received in the earphone plug. The conductive core connects to the conductive tip. The wires connect with the conductive core and the grip ring. When a user holds the conductive tip and makes the earphone plug contact a capacitive touch panel, a current from user's body in the position where the earphone plug makes contact changes the capacitive touch panel to record a touch.

Abstract: In one embodiment, a stylus includes a controller, a delay line, a coefficient line and a computer-readable non-transitory storage medium. The controller is operable to receive a synchronization signal that is transmitted from a computing device and received by the stylus. The delay line is operable to store a first consecutive edges of the synchronization signal. The coefficient line includes a pre-determined coefficient vector.

Abstract: A fob includes a housing, a processor positioned within the housing, and a transceiver positioned within the housing and coupled to the processor. The transceiver is configured to send signals to a remote device. The fob also includes a touchpad supported by the housing and coupled to the processor. The touchpad is operable to discern a plurality of different gestures. Each gesture corresponds to a different signal being sent by the transceiver.

Abstract: A touch sensor including a substrate, a plurality of first sensing electrodes arranged on the substrate, a plurality of first split electrodes respectively adjacent to the plurality of first sensing electrodes, a plurality of second sensing electrodes insulated from the plurality of first sensing electrodes, and a plurality of second split electrodes respectively adjacent to the plurality of second sensing electrodes.

Abstract: A device for analyzing the surface structure of an object, the device comprising a touchable Lambertian light diffusing surface that covers a cavity containing a light source and an image sensor. The image detector senses the contact of the outer Lambertian surface of the device by a contacting object, for example a finger-tip, by means of light from the light source reflecting back to the image detector. At the same time, ambient light from objects external to the device is diffusely scattered by the Lambertian surface as it enters the cavity and does not affect the ability of the image detector to clearly determine the surface structure of the contacting object. Thus, for example, the surface contours of a fingerprint may be determined with a high signal-to-noise ratio.

Abstract: An input/output device for a computing device including one or more touch sensors and one or more force sensors. The touch sensors sense data including one or more locations at which a contact or near-contact occurs. The force sensor sense data including a measure of an amount of force presented at the one or more locations at which a contact occurs. The touch sensors and the force sensors responsive to signals occurring in response to whether the signals are in response to contact or in response to an amount of force. The input/output device also includes one or more circuits coupled to the touch sensors and to the force sensors, and capable of combining information from both sensors.

Abstract: An apparatus includes an integrator circuit, a compensation circuit, and a sense circuit. The compensation circuit applies a positive charge and a negative charge to the integrator circuit during a first time period and a second time period respectively. The integrator circuit integrates a signal and the positive charge to produce a first sense signal. The signal is based on a charge at an electrode of a touch sensor. The integrator circuit integrates the signal and the negative charge to produce a second sense signal. The sense circuit detects a touch based on the first sense signal and the second sense signal.

Abstract: Embodiments of an active in-cell sub-pixel in an LCD panel are provided for time multiplexing image display and touch sensing so as to reduce pin counts required in display driver integrated circuits. In one embodiment, the sub-pixel comprises a liquid crystal capacitor, a storage capacitor and an active switching element. One terminal of the liquid crystal capacitor is connectable to a data line via a thin film transistor switch. The active switching element is connected to another terminal of the liquid crystal capacitor, and is externally controllable. In one configuration, the active switching element connects the liquid crystal capacitor to a second common electrode of the panel, causing the display-driving mode to be turned on. In another configuration, the active switching element connects the liquid crystal capacitor to the data line, causing the touch-sensing mode to be turned on.

Abstract: A touch control device, a driving method of a touch control device, a touch display device, and a driving method of a touch control device are provided. The touch control device comprises a first electrode layer and a second electrode layer. The first electrode and the second electrode layer are electrically insulated from each other. The first electrode layer includes a plurality of mutually insulated first electrodes arranged in an array. The second electrode layer is disposed on a different layer other than the first electrode layer, and includes at least one second electrode. The first electrode is configured to detect a touch position in a first touch control time period, and the first electrode and the second electrode are configured to detect a touch force in a second touch control time period.

Abstract: An in-cell touch display apparatus includes a substrate structure, a display driving integrated chip (IC), and a plurality of touch sensor units arranged in a matrix. Each of the touch sensor units includes a plurality of connecting lines of difference lengths and a plurality of compensating portions corresponding to the connecting lines in a one-to-one relationship. Each of the connecting lines establishes an electrical connection between the touch sensor unit and the display driving IC. The compensating portions are electrically connected to the display driving IC. The connecting lines and the compensating portions receive a common voltage from the display driving IC during the display period. A sum of the lengths of the connecting line and the compensating portion is constant throughout the plurality of connecting lines so as to compensate for different capacitances of the connecting lines.

Abstract: A display device including a sensor screen having a touch recognition function and a fingerprint recognition function is disclosed. The display device includes a display panel having a first display area and a second display area that are adjacent to each other, a first touch sensor being disposed in the first display area, and a sensor screen having a first transparent substrate and a second transparent substrate that are sequentially disposed on the display panel, and a fingerprint sensor and a second touch sensor that are disposed between the first transparent substrate and the second transparent of the sensor screen corresponding to the second display area of the display panel.

Abstract: An input device includes an input surface having a first axis and a second axis, and force sensor electrodes. The force sensor electrodes have a cumulative capacitive sensor response to a force on the input surface. The cumulative capacitive sensor response is, within a specified tolerance, uniform along the first axis based on the plurality of sizes of the plurality of force sensor electrodes.

Abstract: Disclosed are a touch detection electrode, a touch detection method and a touch detection device. The touch detection electrode can realize ordinary capacitive touch by inputting corresponding sensing signals to a part of or all touch sensing electrodes in a first time period; and can realize force touch by inputting corresponding sensing signals to a part or all of the touch sensing electrodes in a second time period. That is, the determination of touch coordinate and the sensing of pressure can be simultaneously realized by driving the ordinary capacitive touch and the pressure touch in time division mode.

Abstract: Provided is an optically transparent conductive material which is suitable as an optically transparent electrode for capacitive touchscreens, the optically transparent conductive material not causing moire even when placed over a liquid crystal display, having a favorably low pattern conspicuousness (non-conspicuousness), and having a high reliability.

Abstract: The present invention relates to a film touch sensor in which a separation layer is formed on a carrier substrate prior to the formation procedures of the touch sensor, and a method of preparing the film touch sensor. The film touch sensor according to the present invention comprises a separation layer; an electrode pattern layer formed on the separation layer and comprising a sensing electrode and a pad electrode formed at one end of the sensing electrode; and an insulation layer formed on the electrode pattern layer and used as a base film layer.

Abstract: Disclosed are a color filter array having a touch sensor and a display panel having the same. The color filter array may comprise: a plurality of color filters arranged in first and second directions on a substrate; a touch block electrode disposed on the color filters to sense a user touch position; a black matrix disposed on the touch block electrode between the color filters; and a touch-sensing line which is disposed in any one of the first and second directions and at least one of which is connected to the touch block electrode. Thereby, when the color filter array is applied to a bending-type or folding-type display device, generation of cracks in the touch sensing line is reduced or minimized.

Abstract: A capacitive touch panel includes a substrate having a touch sensing layer on the surface thereof, and an electrode module mounted in the touch sensing layer and including first electrodes arranged in parallel in X-axis direction and second electrodes arranged in parallel in Y-axis direction. Each first electrode includes multiple first electrode elements and multiple first signal lines arranged in X-axis direction and respectively electrically connected between each two adjacent first electrode elements. Each second electrode includes multiple second electrode elements respectively disposed adjacent to and spaced from the first electrode elements of one respective first electrode and multiple second signal lines arranged in Y-axis direction and respectively electrically connected between each two adjacent second electrode elements. Thus, the electrode module accurately senses the touch signal of the touch sensing layer without distortion.

Abstract: An electronic device is provided which includes a touch sensor, a pressure sensor, and a processor electrically connected with the touch sensor and the pressure sensor. The processor is configured to determine at least one of a location of a first touch sensed by the touch sensor or pressure of the first touch sensed by the pressure sensor as a user input in a first state and to determine at least one of a location of a second touch sensed by the pressure sensor or pressure of the second touch as a user input in a second state.

Abstract: The various embodiments described herein provide input devices configured to selectively operate in two different sensing regimes. The first sensing regime is configured to determine positional information for ungloved fingers in the sensing region. The second sensing regime is configured to determine positional information for gloved fingers in the sensing region. The input devices are further configured to switch from operating in the first sensing regime to the second sensing regime responsive to detecting an input gesture that meets each of a set of criteria, where the set of criteria includes a measure of sensor value stability corresponding to the input gesture being beyond a sensor value stability threshold level. So implemented, the input device allows a user to easily switch between two different sensing regimes, and thus can facilitate the use of the device with both gloved and ungloved fingers providing input.

Abstract: A multi-layer conductive coating is substantially transparent to visible light, contains at least one conductive layer comprising silver that is sandwiched between at least a pair of dielectric layers, and may be used as an electrode and/or conductive trace in a capacitive touch panel. The multi-layer conductive coating may contain a dielectric layer of or including zirconium oxide (e.g., ZrO2), silicon nitride, and/or tin oxide in certain embodiments, and may be used in applications such as capacitive touch panels for controlling showers, appliances, vending machines, electronics, electronic devices, and/or the like.

Abstract: A capacitive discharge circuit includes a line having a capacitance, a switched capacitor circuit including a capacitor, a switched circuit coupled to the line, and a voltage regulator coupled between the switched capacitor circuit and the switched circuit. A controller operates the switched capacitor circuit and switched circuit to in a first phase, charge the capacitor by coupling the capacitor between a common mode and a power supply, and in a second phase, discharge the capacitor by coupling the voltage regulator in series with the capacitor between the power supply node a ground. The controller is also configured to in a third phase, charge the capacitor by coupling the capacitor between the common mode and the power supply, and in a fourth phase, share charge between the line and the capacitor by coupling the voltage regulator and the capacitor in series between the line and the ground.

Abstract: An inspection apparatus is provided with a holder configured to set an inspection target thereon, the inspection target configured to detect a contact position on the inspection target touched by a human finger; pseudo finger(s) configured to be detected as the human finger upon contact with the inspection target; a positioner configured to move the pseudo finger(s) relative to the inspection target and to change the contact position of the pseudo finger(s) relative to the inspection target; a memory configured to store, respectively, a value of a pressing force in a range of pressing forces said range including a zero pressing force for each of the pseudo finger(s) on the inspection target; a controller configured to regulate the pressing force for pseudo finger(s) of the pseudo finger(s) based on the respective value; and a sensor configured to acquire an electric signal output from the inspection target.

Abstract: A touch panel includes: an transparent substrate; an X wiring line; a Y wiring line; and an inter-layer insulating film which electrically separates the X wiring line and the Y wiring line at an intersection at which the X wiring line and the Y wiring line intersect in a plan view. At the intersection, the bottom layer of one wiring line of the X wiring line and the Y wiring line continues on the lower surface side of the inter-layer insulating film, and layers of the one wiring line except the bottom layer are divided. Further, at the intersection, layers of the other wiring line of the X wiring line and the Y wiring line except the top layer of the other wiring line are divided, and the top layer of the other wiring line continues on the upper surface side.

Abstract: The present disclosure provides a touch display panel including a a display substrate, a touch electrode layer, and an insulating layer located between the display substrate and the touch electrode layer. The touch electrode layer includes a touch graph with grooves. The touch display panel further includes a transparent conducting film layer insulated from the touch electrode layer by the insulating layer.

Abstract: A display apparatus including a display panel, a polarizing member having an absorption axis and a transmission axis, and a first touch electrode extending in a first direction is disclosed. The first touch electrode includes first touch patterns and a connection pattern connecting adjacent first touch patterns in the first direction. The connection pattern has a minimum width in a direction perpendicular to a second direction. The first direction and the absorption axis direction form a first directional angle equal to or less than about 90 degrees. The first and second directions form a second directional angle equal to or less than about 90 degrees. The second and absorption axis directions form a third directional angle equal to or less than about 90 degrees. The first directional angle is the sum of the second directional angle and the third directional angle.

Abstract: Provided is a display device including: a base film having a display region, a touch region, and a boundary region between the display region and the touch region; an image-displaying portion in the display region and on a first face side of the base film; and a touch portion in the touch region and on a second face side of the base film. The boundary region is sandwiched between the image-displaying portion and the touch portion, and the base film is folded in the boundary region so that a front face of the touch portion overlaps with the image-displaying portion with the touch portion interposed therebetween.

Abstract: According to one embodiment, a display device includes a display panel which displays an image, a touch panel provided on the display panel and including a sensor area in which a plurality of electrodes for detecting touch operation are provided and a peripheral area provided around the sensor area, a controller which controls the plurality of electrodes, lead lines provided in the peripheral area to connect the electrodes provided in the sensor area to the controller and a conductive layer provided in a region which overlaps at least part of the lead lines.

Abstract: Provided is a touch force sensing device. The touch force sensing device comprises a first substrate, a resistor on one surface of the first substrate, a second substrate facing the first substrate, a driving electrode disposed on a surface of the second substrate facing the first substrate and spaced from the resistor and a sensing electrode disposed on the same surface as the driving electrode and electrically connected to the driving electrode through the resistor by an external touch input.

Abstract: A mirror display is described. The mirror display includes a plurality of first electrodes disposed on a first substrate, a plurality of sensor lines disposed on the first substrate, the plurality of sensor lines connected to the plurality of first electrodes, a plurality of second electrodes disposed on a second substrate, the plurality of second electrodes facing the first substrate, a liquid crystal layer interposed between the plurality of first electrodes and the plurality of second electrodes, a plurality of mirror driving lines on the second substrate, the plurality of mirror driving lines connected to the plurality of second electrodes, and a reflective polarizing film attached to the second substrate.