Abstract: A touch panel with electromagnetic induction function comprising a light-emitting diode backlight layer, an electromagnetic antenna, a display panel layer, a touch panel layer and a protective layer. The light emitting diode backlight layer has a plurality of light emitting diode units. The electromagnetic antenna is disposed on the backlight layer for emitting an alternating electromagnetic field and receiving a resonance signal. The display panel layer is disposed on the backlight layer. The touch panel layer is disposed on the display panel layer for capacitive touch. The protective layer is disposed on the touch panel layer to protect the touch panel layer. An electromagnetic pen for electromagnetic touch is configured to receive the alternating electromagnetic field and then emit the resonance signal.

Abstract: Embodiments of a multi-form factor Information Handling System (IHS) with an accessory backpack are described. In some embodiments, an IHS may include a first display and a second display coupled to the first display, where the second display comprises a catch, and where the catch is configured to magnetically engage a corresponding hook of an accessory in response to a top surface of the accessory being placed under a back portion of the second display.

Abstract: A handwriting board is provided. The handwriting board includes a bendable support plate, a touch screen and a control module located at the bendable support plate. The touch screen and the control module are electrically connected with each other. The touch screen is configured to sense a writing operation of a stylus on a writing paper and to generate touch coordinate data of the writing operation. The control module is configured to acquire the touch coordinate data and to generate touch handwriting information according to the touch coordinate data. The handwriting board is configured to sense the writing operation of the stylus on the writing paper and to form the touch handwriting information corresponding to an actual handwriting of the stylus formed on the writing paper.

Abstract: A method of displaying a keyboard includes: determining a window state of a current window when an input operation is detected based on the current window; and displaying a floating keyboard at an upper layer of a screen in a floating manner based upon the determined window state being a split-screen state.

Abstract: Embodiments relate to bioimpedence-based spoof detection in an optical biometric reader. For example, embodiments operate in context of a biometric reader having a platen integrated with substantially transparent bioimpedance source and receiver electrodes covered by a substantially transparent protective layer. A multi-frequency input signal can be injected from the source electrode into a purported skin site (through the protective layer), so that a response signal is received by the receiver electrode. The response signal is interrogated to formulate a dispersive bioimpedance response of the purported skin site to the input signal over multiple frequencies. A biometric spoof determination can then be made according to the dispersive bioimpedance response. The spoof determination can be used for spoof detection, presence detection, and/or other functions.

Abstract: A touch event processing method, comprising: virtualizing a standard HID pen apparatus and a touch apparatus in an operating system; intercepting touch information sent by a physical touch apparatus so that the touch information is not directly received by the operating system; classifying the touch information, and sending, by using different virtual apparatuses based on the classification, the touch information to the operating system for processing. A user can directly touch, write and erase in the software based on past experience and impressions, does not need to search a toolbar for a required functional icon, and even does not need to open the toolbar.

Abstract: A gaming system including a housing and one or more deformable devices supported by the housing, wherein the deformable devices are configured to selectively take multiple different shapes.

Abstract: A position detecting device obtains information from a stylus when the stylus moves at high speed, while removing influences of noise. The position detecting device includes a differential amplification circuit that amplifies and outputs a difference in a signal at a first terminal and a signal at a second terminal, and a selection circuit that selects at least a first electrode of a sensor, connects at least the first electrode to the first terminal of the differential amplification circuit, selects at least a second electrode of the sensor, and connects at least the second electrode to the second terminal of the differential amplification circuit. The selection circuit selects electrodes separated by a first interval in a period in which a position indicated by the stylus is detected, and selects electrodes separated by a second interval that is shorter than the first interval in a period in which data is detected.

Abstract: The present disclosure provides systems, device configurations, and processes for displaying presentation control interfaces as overlays of content being displayed by an interactive whiteboard computing system in an interactive presentation environment, including one or more panels displaying selectable icons for performing various control tasks, including: viewing a present position and changing position within a sequence for the presentation; inputting, finding, and loading data to be stored for the presentation; interacting with the computing system or connected devices; and the like. Additional configurations include automatically showing, hiding, and/or repositioning control interface panels so that they are accessible by the presenter without substantially interfering with the presentation.

Abstract: A touch sensor integrated display device includes a plurality of common electrode blocks serving as touch driving blocks and touch sensing blocks. Conductive lines connected to the touch driving blocks and touch sensing blocks are routed towards an inactive area of the display device by directly across the active area. The conductive lines are positioned within one or more organic dielectric layers formed under the common electrode blocks and pixel electrodes, but above the data lines of the display device.

Abstract: A drawing device according to the present disclosure includes a device body that includes a drawing screen of a liquid crystal screen, a pressure sensor provided on the drawing screen and configured to detect pressure on the drawing screen, an eraser bar provided in the device body and configured to slide along the drawing screen, an eraser bar position detection port as an eraser bar position sensor configured to detect a position of the eraser bar, and a control unit configured to perform a drawing process in which a picture is drawn on the drawing screen along a position where the pressure on the drawing screen is detected. The control unit is configured to erase the picture on the drawing screen in accordance with a moving range of the eraser bar when the eraser bar is moved.

Abstract: A display device includes: a display panel having a display section; an operation panel disposed so as to cover the display panel, the operation panel having an operation surface which is located on an opposite side to a side facing the display panel; vibrating bodies disposed on the operation panel; a support disposed on the side facing the display panel so as to face the operation panel apart therefrom; elastic supporting members disposed between the operation panel and the support, the elastic supporting members being elastically deformable in accordance with vibration of the vibrating bodies; and a ventilatable wall member disposed across the operation panel and the support so as to externally surround the display section, the wall member being composed of a mesh structure deformable in accordance with the vibration of the vibrating bodies.

Abstract: A position detection circuit and position detection method are provided to enable more flexible position detection even if an object is present above a touch sensor. The position detection circuit is connected to a capacitive touch sensor formed with a plurality of line electrodes that are two-dimensionally arranged. At least one memory device stores processor-readable instructions that, when executed by at least one processor device, cause the position detection circuit to: recognize an electrically conductive object located above a touch sensor based on two-dimensional data indicating detection values regarding capacitance, and detect a touch position or touch area on the touch sensor based on the two-dimensional data using different touch detection conditions for an outside and an inside of an area where the object is present.

Abstract: There are provided systems, devices and methods for operating a housing for an electronic device as an input/output (I/O) device. In one embodiment, an electronic device includes a housing configured to function as an integrated housing and I/O device and one or more sensors obscured by a panel of the housing. The one or more sensors being configured to sense via the panel of the housing. The electronic device further includes a processing unit communicatively coupled to the one or more sensors and configured to interpret electrical signals generated by the one or more sensors. One or more output devices are communicatively coupled to the processing unit and configured to provide an output in response to the one or more sensors generating an electrical signal.

Abstract: An exemplary system includes: an information processing unit; a storage unit which stores information processed by the information processing unit; a touch panel which is a touch input unit which accepts a touch input; and an acceleration sensor equivalent to a force detection unit which detects a force applied to an apparatus or the touch panel at a time of the touch input, and the information processing unit evaluates an input area of the touch input and performs predetermined information processing in accordance with the input area and an acceleration value which is a detection value of the force.

Abstract: Embodiments hereof are directed to a haptic device having a pressure-sensitive suspension system. The haptic device includes a housing, a touch surface component mounted to the housing to be movable relative thereto, and a haptic actuator for providing haptic feedback to the touch surface component. At least one suspension component is disposed between the touch surface component and the housing. The suspension component is formed from an elastomer and includes pressure-sensing particles integrated into the elastomer. The pressure-sensing particles are configured to sense pressure applied to the touch surface component.

Abstract: A haptic feedback system is disclosed. The system includes a plurality of remote transmitters that are remote from a location of interest on a surface of the system. The system includes a signal generator that generates a signal for each of the remote transmitters. The remote transmitters propagate the signals through a medium of the surface and the signals interfere at the location of interest such that a localized disturbance is generated at the location of interest.

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

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

Abstract: An electronic device includes a display for displaying data stored on the electronic device; input means; sensing means for sensing the three-dimensional position of the input means relative to the device; and control means for controlling the data displayed on the display in dependence on the three-dimensional position of the input means relative to the device. The input means includes a source of electromagnetic radiation for directing an infrared conical beam onto the display. The sensing means can sense the elliptical eccentricity of the electromagnetic radiation incident on the display to determine the angle at which it strikes the display, and can sense the area of the electromagnetic radiation incident on the display to determine the distance of the input means from the display.

Abstract: This document describes techniques for, and systems that enable, a multi-stroke smart ink gesture language. The described techniques enable a digital ink user interface that allows a display, that is capable of receiving a digital ink stroke from a passive stylus or an active pen, to receive the digital ink stroke as either a content input or an action input. The digital ink stroke may be determined to be an action input based on proximity to, intersection with, or chronological immediacy to a prior-received digital ink stroke. When multiple digital ink strokes are determined to represent a multi-stroke gesture associated with an action input, the action input is provided to the application, which can then perform the action associated with the action input. The multi-stroke gesture allows users to input both content and actions using the passive stylus or active pen and natural digital inking strokes.

Abstract: In one implementation, a system for using a physical document for navigation includes a receiver engine to receive an identifier location corresponding to an area selected on the physical document, a location engine to determine a location within a digital representation of the physical document corresponding to the identifier location, and a display engine to display information relating to the identifier location based on the identifier location and the corresponding location within the digital representation of the physical document.

Abstract: A display device includes an input sensing unit. The input sensing unit includes sensors and signal lines connecting the sensors to a driving circuit for sensing a touch. The signal lines may include reception signal lines and transmission signal lines. A resistance value of the reception signal line connected to the sensor relatively far from the driving circuit is smaller than a resistance value of the reception signal line connected to the sensor relatively close to the driving circuit.

Abstract: A device includes a first control element which transitions a sensor module between an active and an inactive mode. A second control element is configured to adjust currents drawn by the sensor module during the inactive mode—such currents corresponding to sensor readings. A processor is coupled by a power signal to a sensor module, which operates over an active sensor, a transition, and a data transfer state. Currents drawn during the active sensor state are substantially constant. During transition, currents decrease from the substantially constant current to a minimum current. During data transfer, currents vary between the substantially constant current and the minimum current. A logical element is configured to monitor the current drawn by the sensor module and, based on variations therein, determine the operating state of the sensor module. A method for using the processor is also disclosed.

Abstract: Some embodiments of the present invention provide a touch detection method and system. The touch detection method comprises: performing a spread spectrum process on a driving signal to generate a spectrum-spread signal; outputting the spectrum-spread signal to a driving terminal of a touch screen; receiving, from a response terminal of the touch screen, a coupled signal formed by coupling the spectrum-spread signal received by the driving terminal to the response terminal; and performing a de-spread spectrum process on the coupled signal to obtain a touch detection signal. Employing the embodiments of the present invention, an accuracy of a detection of a location on the touch screen can be improved by a spread spectrum technology, so as to enhance an anti-interference ability of a touch-controlled device.

Abstract: The present invention provides an interface application enabling multi-functionality of a specific area part of an interface in a computerized device. The interface comprised of: at least one touch enabled surface, where in at least partial area surface is integrated with at least one fingerprint sensor for capturing at least part of distinguishing ridges and valleys of the touching fingertip touching a specific area, a processing module arranged to analyze said distinguishing ridges and valleys of the touching fingertip, for identifying characteristic of the specific touching finger differentiating said finger from other fingers of the same user (either from the same of both hands), and an activation module for determining the functionality of said specified area based on the identified touching finger(s).

Abstract: There is provided a tactile feedback device comprising: an array of surface charge generation units; and an array of pressure-generation units, wherein the array of the pressure-generation units is spaced apart from the array of the surface charge generation units, wherein the array of the pressure-generation units is movable relative to the array of the surface charge generation units, wherein an attractive or repulsive force is generated between a corresponding surface charge generation unit of the array of surface charge generation units and a corresponding pressure-generation unit of the array of the pressure-generation units, based on a polarity of surface charges induced in the corresponding surface charge generation unit.

Abstract: Embodiments of this application provide a data processing method and apparatus. The method includes: receiving a first data packet sent by a control end, the first data packet including a first touch event and a first identifier of the first touch event; determining, according to the first touch event and the first identifier of the first touch event, whether a second data packet comprising a second touch event sequentially executed with the first touch event is lost; creating the second touch event corresponding to the second data packet in accordance with a determination that a second data packet has been lost; and processing the second touch event that has been created, so that a controlled end performs an application operation in accordance with a touch operation to which the second touch event belongs. In this way, control exceptions caused by packet losses are reduced.

Abstract: The present application discloses a touch panel having a touch area and a non-touching area at a side of the touch area. The touch panel includes: a base substrate having a first surface and a second surface opposite to each other; a touch sensing electrode provided on the first surface of the base substrate and corresponding to the touch area; a first connection wire on the second surface of the base substrate; and a touch control circuit in the non-touching area. The base substrate is provided with a first through hole, the touch sensing electrode is electrically connected with the first connection wire through the first through hole, and the first connection wire is electrically connected with the touch control circuit. The present application further discloses a manufacturing method for the touch panel and a display apparatus having the touch panel.

Abstract: A touch screen includes a first electrode layer, an insulating layer on a first electrode layer, and a second electrode layer on the insulating layer. The first electrode layer or second electrode layer includes first sensing electrode columns and second sensing electrode columns. The first sensing columns include first sensing electrodes having sub-electrodes. The second sensing electrode columns are alternately arranged with the first sensing electrode columns and include second sensing electrode. The sub-electrodes of one of adjacent first sensing electrodes are electrically connected to sub-electrodes of another one of the adjacent first sensing electrodes, respectively.

Abstract: The present invention provides a mutual capacitive touch panel including a first conductive layer and a second conductive layer. The first conductive layer includes a plurality of electrodes arranged in an array and a plurality of connecting line segments. In each column of the array, the electrodes in the ((N×M)-1)th row are electrically connected to one another through some of the connecting line segments to form a first electrode series, and the electrodes in the (N×M)th row are electrically connected to one another through some of the connecting line segments to form a second electrode series. The second conductive layer includes a plurality of electrode strips extending along a row direction of the array and respectively overlapping the electrodes located at the corresponding row. Each electrode strip includes a plurality of shielding portions, each of which overlaps one corresponding of the connecting line segments.

Abstract: The present invention relates to a touch panel and, more particularly, to a touch panel capable of improving electrical conductive characteristics of the touch panel, reducing the size of the touch panel, improving the visibility of the touch panel, and minimizing damage to a substrate when a failure test is performed on the touch panel.

Abstract: A terminal device receives an input instruction on a game process that corresponds to an input reception area when a touch operation input on the input reception area has been detected by a first detection process, and disables a given input instruction that corresponds to the input reception area when a slide operation input on the input reception area has been detected by a second detection process, the slide operation input having been performed to directly follow the touch operation input performed when the input instruction regarding the game process was received.

Abstract: A force measurement system is disclosed herein. The force measurement system includes a force measurement assembly and a data processing device operatively coupled to the force measurement assembly. In one or more embodiments, the data processing device is configured to reference a stored global calibration matrix for the force measurement assembly, to determine a location of an applied load on the surface of the force measurement assembly using the stored global calibration matrix, to assign the applied load to one or more of a plurality of different load regions based upon the location of the applied load, and to compute one or more output forces or moments of the applied load using stored local calibration information for the one or more of the plurality of different load regions. A method of calibrating a force measurement system is also disclosed herein.

Abstract: Disclosed are methods, apparatus and systems for real-time gesture recognition. One exemplary method for the real-time identification of a gesture communicated by a subject includes receiving, by a first thread of the one or more multi-threaded processors, a first set of image frames associated with the gesture, the first set of image frames captured during a first time interval, performing, by the first thread, pose estimation on each frame of the first set of image frames including eliminating background information from each frame to obtain one or more areas of interest, storing information representative of the one or more areas of interest in a shared memory accessible to the one or more multi-threaded processors, and performing, by a second thread of the one or more multi-threaded processors, a gesture recognition operation on a second set of image frames associated with the gesture.

Abstract: A method of detecting a user input includes sensing one or more touch events at a device. In some embodiments, a method includes sensing a first touch event via a first housing of a device. The method also includes generating a first detection signal based on the first touch event. The method also includes sensing a second touch event via a second housing of the device, the second housing conductively isolated from the first housing. The method also includes generating a second detection signal based on the second touch event. The method also includes classifying, based on the first detection signal and the second detection signal, the first touch event as user input. The method also includes identifying one or more actions based on the classification of the first touch event as the user input, the one or more actions associated with the user input.

Abstract: Handwritten notes are captured organized and stored by a system as a digital representation. The system includes a notebook having a set of pages, wherein each page has placed thereon a folio identifier representation, such representation including a page identifier. The system also includes a non-transitory computer readable medium encoded with instructions, which, when running on a camera-equipped computing device at a time when the camera thereof views a page of the notebook, cause performance of processes. The processes performed by the instructions include: processing an image associated with the page, detecting and decoding the folio identifier representation to provide a page identifier for the page, and if the image has not been previously captured, then capturing the image of the page and saving the image in an image store.

Abstract: An eraser device 4 for inputting an erase-operation of a display image to a touch panel 2, the touch panel 2 includes an input point detection unit 31 for detecting, as input points based on a plurality of detection points arranged on or near to a display screen, detecting points where a touch operation is performed; and an erase-operation determination unit 32 for determining whether or not a user's operation is the erase-operation, according to a degree of density of the input points, wherein the eraser device 4 includes a plurality of touch parts (pillar parts 48) to be detected as the input points when brought into contact with or closer to the touch panel, and the plurality of touch parts (pillar parts 48) are formed at such a degree of density that it is determined by the erase-operation determination unit that the erase-operation is being performed. Accordingly, an improved command input system for easily performing the erase-operation to the touch panel can be provided, inexpensively.

Abstract: A touch input device configured to detect stylus signals generated by an external stylus is provided. The touch input device includes a plurality of stylus signal detectors that receive at its input a combination of stylus receive channels that are combined in a manner to minimize noise while at the same time keeping the stylus signal strength uniform independent of the position of the stylus on the device.

Abstract: An electronic system includes a hand-held controller and a computing application. The hand-held controller includes a proximity sensing circuit and a physical information sensing circuit. The proximity sensing circuit includes proximity sensors. The proximity sensors are configured to sense instant proximity values. The physical information sensing circuit is configured to sense a physical parameter. The computing application is executed by a processor. The computing application is configured to retrieve the instant proximity values and the physical parameter, to calculate maximum proximity values or minimum proximity values according to the instant proximity values and the physical parameter. The maximum proximity values or the minimum proximity values are utilized to update threshold proximity values of the proximity sensors in determining near status or far status.

Abstract: An in-cell type liquid crystal display device includes a first unit that detects whether a touch is present, or not, on the basis of a current flowing in a plurality of detection electrodes when a touch panel scanning voltage is applied to counter electrodes of each of M (M?2) divided blocks, and a second unit that detects noise on the basis of a current flowing in the plurality of detection electrodes, assuming that an (M+1)th counter electrode is present for the counter electrodes of each of the M divided blocks, and assuming that a touch panel scanning voltage synchronous with the touch panel scanning voltage applied to the counter electrodes of each of the M divided blocks is applied to the (M+1)th counter electrode.

Abstract: A touch-sensitive device includes a capacitance-based touch sensor, drive circuitry configured to drive touch sensor electrodes with a synchronization waveform to enable an active stylus to become time synchronized with the touch-sensitive device, and receive circuitry configured to determine a position of the active stylus based on electrostatically receiving a first waveform from the active stylus. Depending on when the touch-sensitive device receives the first waveform from the active stylus, the touch-sensitive device interprets the first waveform differently to determine a position of the active stylus or determine that the active stylus is hovering. In either case, the same waveform is used to communicate different information about the active stylus to the touch-sensitive device.

Abstract: Touch sensor configurations for reducing electrostatic discharge events in the border area of a touch sensor panel is disclosed. Touch sensors (e.g., electrodes formed on the cover material and/or the opaque mask) can be susceptible to certain events such as arcing and discharge/joule heating, which may negatively affect touch sensor performance. Examples of the disclosure can include increasing the trace width, spacing, and/or thickness in the border area relative to the trace width, spacing, and/or thickness in the visible/active area along one or more sides of the touch sensor panel. In some examples, touch electrodes can be located exclusively in the visible/active areas along one or more sides of the touch sensor panel, while dummy sections can be included in both the border and visible/active areas. Additionally or alternatively, one or more gaps between adjacent touch electrodes in the border area or serpentine routing can be included.

Abstract: A method for operating a touchscreen device is provided. The method identifies a status of the touchscreen device, by at least one processor, wherein the touchscreen device comprises at least a projected capacitive (PCAP) touchscreen mounted in front of a liquid crystal display (LCD) of the touchscreen device, an infrared (IR) touch sensor configured to generate an IR grid, a switch, and the at least one processor, and wherein the status comprises one of a default state lacking user touch input and a touch-state receiving active user touch input. When the status comprises the touch-state, the method adjusts the switch to enable user input selections via the PCAP touchscreen. When the status comprises the default state, the method retains a position of the switch, the position configured to disable user input selections via the PCAP touchscreen.

Abstract: The input detection device includes: a line having an end to which a driving signal is supplied and extending in a first direction; a plurality of drive electrodes extending in a second direction intersecting the first direction and arranged in parallel in the first direction; a selecting drive circuit selecting the drive electrode from the plurality of drive electrodes and connecting an end of the selected drive electrode to the line; a driving signal circuit supplying the driving signal to the end of the line; and a plurality of line patterns connected to each drive electrode. A line density of line patterns connected to a drive electrode connected to be close to the end of the line is smaller than a line density of line patterns connected to another drive electrode connected to be far from the end of the line.

Abstract: To protect confidential data, a mobile device determines whether the mobile device is at a location susceptible to visual capture of confidential data entered into the phone by external cameras. The mobile device determines whether focus of a display is on a field in which confidential data is entered. If the mobile device determines that it is at a location susceptible to an external imaging device visually capturing confidential data input into the input field, then the mobile device activate a light source on a same side as the screen presenting the display.

Abstract: An electronic device includes at least a housing having a force transmissive surface capable of receiving a force, a force sensor configured to sense the force received from the force transmissive surface in accordance with a force path and respond by outputting a signal that indicates a magnitude of the force at a first sensitivity level when the magnitude of the force is less than a threshold level, otherwise, the signal indicates the magnitude of the force in accordance with a second sensitivity level. The electronic device includes a processor in communication with the force sensor that uses the signal to alter an operation of the electronic device. In one embodiment, the electronic device is wearable.

Abstract: A circuit having a resistive touch screen, a medical imaging appliance having a resistive touch screen and a method for operating a resistive touch screen are provided. The circuit has a resistive touch screen with a resistive first layer and a resistive second layer that are arranged parallel above one another. Voltage dividers of the first and second layers are formed by contact with the touch screen and are extended by electrical resistors arranged at edges of the first and second layers.

Abstract: Touch sensor panel configurations for reducing wobble error for a stylus translating on a surface over and between electrodes of the touch sensor panel are disclosed. In some examples, electrodes with more linear signal profiles are correlated with lower wobble error. In some examples, diffusing elements formed of floating segments of conductive materials can diffuse signal from a stylus to a plurality of electrodes, thus, making the signal profiles associated with the electrodes more linear. In addition, diffusing elements can be configured to improve the optical uniformity of the touch sensor panel. In some examples, the diffusing elements can be formed on the same layer as floating dummy pixels and resemble a plurality of merged floating dummy pixels.

Abstract: An information processing apparatus is provided which includes an operation tool detection unit for detecting at least a contact operation by an operation tool on the information processing apparatus, a state detection unit for detecting a static/non-static state or an orientation of the information processing apparatus, and a mode control unit for controlling a mode for detecting an operation by the operation tool on the information processing apparatus according to the detected static/non-static state or orientation of the information processing apparatus. This enables the mode for detecting the operation by the operation tool on the information processing apparatus to be controlled according to the static/non-static state or orientation of the information processing apparatus, so that the detection mode can be appropriately controlled according to an operating state of a user.