Abstract: An image processing method, an image processing circuit, and a display apparatus using the same are discussed. The image processing method can include sensing a viewing distance of a user and determining a predetermined viewing distance mode, upon determining that the viewing distance corresponds to a short distance mode, performing blurring processing on four-color data of each pixel of an input image for each color channel by applying a predetermined blurring mask to reduce data of an edge portion of the input image and to output the image, and upon determining that the viewing distance corresponds to a long distance mode, performing sharpening processing on white data of four-color data of each pixel of the input image by applying a predetermined sharpness mask to increase the white data of the edge portion of the input image and to output the image.

Abstract: Aspects of the present invention relate to user interface control of a head-worn computer.

Abstract: The description relates to a smart ring. In one example, the smart ring can be configured to be worn on a first segment of a finger of a user. The example smart ring can include at least one flexion sensor secured to the smart ring in a manner that can detect a distance between the at least one flexion sensor and a second segment of the finger. The example smart ring can also include an input component configured to analyze signals from the at least one flexion sensor to detect a pose of the finger.

Abstract: A mobile device and control method thereof are provided. The mobile device includes a life sensor, a driver, a touch detector, a heartbeat detector, a controller and a processor. The controller controls the driver to send a first driving signal. The life sensor generates a first sensing signal in response to the first driving signal. The touch detector determines whether the mobile device is touched according to the first sensing signal. When the touch detector determines that the mobile device is touched, the controller controls the driver to send a second driving signal. The life sensor generates a second sensing signal in response to the second driving signal. The heartbeat detector determines whether the second sensing signal includes a heartbeat pattern. The processor executes a corresponding operation according to whether the second sensing signal includes the heartbeat pattern.

Abstract: Sensor data is obtained regarding an environment around a guidance device. A model of the environment is generated based on the data. The model is mapped at least to an input/output touch surface of the guidance device. Tactile output is provided to a user of the guidance device via the input/output touch surface based at least on the mapping. Other output based on the model may also be provided. The guidance device may include a variety of different components such as sensors that obtain data regarding the environment, input/output mechanisms for receiving input from and/or providing input to the user, processing units and/or other components for generating the model and/or mapping the model to various input/output mechanisms, and so on. Additionally, the guidance device may cooperate and/or communicate with a variety of different electronic devices that have one or more such components in order to perform such functions.

Abstract: The present invention relates to a new process for the synthesis of Colesevelam, which is used in therapy in cases of hypercholesterolemia due to low density lipoproteins. Said process comprises the reaction, in a basic environment, of polyallylamine with: i) at least one alkylating agent of formula X—(CH2)9—CH3 and at least one alkylating agent of formula Y—(CH2)6—N+ (CH3)3Z?, wherein X and Y are each independently a leaving group, and Z is a halogen; and ii) at least one crosslinking agent. The present invention also relates to the Colesevelam obtainable by the above process.

Abstract: Methods and systems are disclosed herein for a media guidance application that determines the tactile attributes (e.g., an amount of pressure applied by a user, a length of time pressure is applied by a user, a velocity of the user input, etc.) associated with a received user input and determines which media guidance function, of a plurality of media guidance functions, is associated with the tactile attributes.

Abstract: A handheld apparatus includes a top surface that includes a touch screen defining a plurality of keys, and a bottom surface on an opposite side of the first surface. The apparatus further includes a processor and an actuator coupled to the processor and located on the bottom surface. The processor is adapted to detect an object moving across the keys and in response generate an actuation signal to the actuator to generate a haptic feedback on the back surface.

Abstract: Methods, articles of manufacture, and devices related to generating six degree of freedom (DOF) haptic feedback are provided. A computing device can receive first depth data about an environment. The computing device can generate a first plurality of points from the first depth data. The computing device can determine a virtual tool, where the virtual tool is specified in terms of a translation component for the virtual tool and a rotation component for the virtual tool. The computing device can determine a first force vector between the virtual tool and the first plurality of points. The computing device can send a first indication of haptic feedback based on the first force vector.

Abstract: Embodiments of the present invention provide a pointing interaction method, apparatus, and system. The method includes: obtaining a hand image and an arm image; determining spatial coordinates of a fingertip according to the hand image, and determining spatial coordinates of an arm key portion according to the arm image; and performing converged calculation on the spatial coordinates of the fingertip and the spatial coordinates of the arm key portion, to determine two-dimensional coordinates, on a display screen, of an intersection point between fingertip pointing and the display screen. Therefore, the pointing interaction apparatus can implement high-precision pointing only by using the spatial coordinates of the fingertip and the spatial coordinates of the arm key portion, and the pointing has good realtimeness.

Abstract: Systems and methods are disclosed that, in various embodiments, improve chart performance by allowing users to interactively split and unsplit charts with dual-Y axis using dragging gestures or a button.

Abstract: Presented is method and system for processing a gesture performed by a user of an input device. The method comprises detecting the gesture and determining a distance of the input device from a predetermined location. A user command is then determined based on the detected gesture and the determined distance.

Abstract: An accessory for an electronic device, such as a mobile computing device, includes a housing and a support element that are configured to support the electronic device in an inclined orientation. The support element of the accessory may comprise an elongated recess that receives a portion (e.g., an edge portion) of an electronic device to orient and support the electronic device in the inclined orientation. The accessory may also include a peripheral component, such as a user interface component (e.g., a keyboard, a track pad, etc.) or any other component that may enhance or supplement functionality of the electronic device.

Abstract: A method at an electronic device including a touch-sensitive display for receiving touch input and a keyboard comprising a plurality of buttons, the method comprising: detecting actuation of a button on at least one of the plurality of buttons; detecting a touch input at the touch-sensitive display while the button is actuated; responding to the touch input, wherein response to the touch input while the button is actuated is different to response to touch input detected while the button is not actuated.

Abstract: A keypad capable of being configured with multiple button configurations with buttons of various heights is configured to recognize the button configuration through actuations of the buttons. The keypad is placed in a configuration mode by inputting an unresolvable condition to the keypad. Once in the configuration mode, the buttons are individually actuated in a predefined order to configure the size and function of each button.

Abstract: A touch panel is provided in the present disclosure, comprising: a sensing patterned layer, comprising a plurality of first sensing electrode units not in contact with each other along first axis; and a bridging line, electrically connected with the adjacent first sensing electrode units along the first axis; wherein the bridging line are made by at least a metallic layer and a conductive oxidized layer. By this way the touch panel lowers light reflection, thereby reducing flashes and bright-spots on the touch panel and improving appearance of the touch panel.

Abstract: A human machine interface (HMI) system controls operation of a graphical user interface (GUI) being displayed on a display located in a vehicle. The HMI system includes an interface device, an interface operation module, and a device selection module. The interface device is operable to control the GUI and includes a knob member and a touchpad. The interface operation module receives input data from the interface device in response to an operation of the interface device. The device selection module designates at least one of the knob member or the touchpad as an active device based on a device selection criteria. The interface operation module transmits data from an active device to a display module controlling the GUI and disregards data from an inactive device.

Abstract: An input device including an operating portion and a palm rest is provided. The operation portion includes an operating surface for accepting an operating input from a fingertip. The palm rest is positioned forward of the operating surface as viewed from an operator who places a palm on the palm rest. A tangent plane of a palm-resting surface of the palm rest is disposed on a front surface side of the operating surface. A portion of the operating surface that is close to the palm rest is inclined so that the portion of the operating surface becomes closer to the palm-resting surface of the palm rest as the portion of the operating surface is closer to the palm rest, as compared with another portion of the operating surface that is apart from the palm rest.

Abstract: The embodiments described herein relate to systems, methods, and devices for capturing arm motion. The arm motion can be transformed into a rendered object that can interact with a three dimensional scene that allows a user to intuitively grab, move, manipulate and hit objects within the scene.

Abstract: An electronic device for providing content includes a sensor configured to sense a user input with respect to the electronic device and a controller configured to stop providing the content in response to determining that the electronic device is in a moving state based on the sensed user input while providing the content, and to resume providing the content in response to determining that the electronic device exits the moving state.

Abstract: Disclose is an electronic device system that includes an electronic device having a display unit on at least one surface, a detector, and a controller. The system includes a cover that is selectively attachable to the electronic device. The cover includes a cover assembly that closes to cover the display unit and opens to expose the display unit when the cover is attached to the electronic device. The cover includes a window of the cover assembly that exposes a portion of the display unit in response to the window being in an open state and the cover being closed. The controller causes the display unit to display device information associated with the electronic device at the portion of the display unit that is exposed by the window in response to the detector detecting that the window is in an open state.

Abstract: An input device includes an input interface, a near field communication unit and a controlling unit. The near field communication unit receives a device setting information from a portable electronic device. Consequently, the controlling unit reads the device setting information and performs an input setting task corresponding to the device setting information. When the user operates the input interface, a personalized operating signal corresponding to the device setting information is transmitted from the input interface to a computer host that is connected with the input device. Consequently, the computer host performs a corresponding operation. Under this circumstance, it is not necessary to install a corresponding driver in the computer host.

Abstract: In embodiments of a passive stylus with RFID-enabled sensing, a computing device includes a touchscreen that senses touch contact, and includes an RFID interrogator to interrogate passive RFID tags. The stylus includes a conductive tip designed for interaction with the touchscreen of the computing device. The stylus integrates a pressure sensor that senses pressure when the conductive tip of the stylus contacts the touchscreen. The stylus also includes at least one RFID antenna that is positioned in a body of the stylus to prevent detuning the RFID antenna when the stylus is held for use. The passive RFID tag can receive pressure sensor data from the pressure sensor in the stylus, and the passive RID tag can be read by the RFID interrogator to determine the pressure applied to the conductive tip of the stylus in order determine whether the stylus is contacting the touchscreen or only hovering above it.

Abstract: An input device having sufficient countermeasure against static electricity is disclosed. The input device includes a touch pad as an operation-input part that is movably supported above a metal base plate. The operation-input part includes a pad plate to receive an input operation, a board plate stacked below the pad plate to detect an input operation to the pad plate, and a resin housing plate stacked below the board plate. The base plate has an upper face, on which a protruding piece is disposed so as to be inserted between the board plate and the housing plate and come into contact with a ground line as a conductive part provided at the board plate.

Abstract: A touch electrode layer includes a plurality of first touch electrodes and a plurality of second touch electrodes. The first touch electrodes are arranged to form a rectangle, wherein shapes of the first touch electrodes have the same size. The second touch electrodes are disposed around a periphery of the first touch electrodes. The second touch electrodes and the first touch electrodes are arranged to form a circle or a quasi-circle so as to define a circuit touch area or a quasi-circle touch area. A shape of each of the second touch electrodes is an arcuate triangle.

Abstract: In a display system which includes a mobile terminal as an input device and a projector as a display device, the mobile terminal includes a control unit which detects an operation performed on a touch screen and generates coordinate information indicative of an operation location on the touch screen, and a wireless communication unit which transmits the coordinate information generated by the control unit, and the projector includes a wireless communication unit which receives the coordinate information, and a control unit which generates an image based on the received coordinate information and displays the image on a screen.

Abstract: This invention relates to methods, apparatus, and computer programme code for processing acoustic signal data to determine where an object has been tapped with a stylus, finger nail or the like. The method involved storing a set of labelled training data comprising digitised waveforms from a sensor for taps at a plurality of different locations. The labelled training data is then processed to determine mean value and covariance data for the waveforms, which is afterwards used in conjunction with a digitised waveform of a tap at an unknown location to identify the location of the tap. Preferably the covariance is decomposed into a plurality of basis functions for each region each with a respective weighting, which are used to represent captured data for an unknown tap and parameters of the representation are classified to locate the tap.

Abstract: In one implementation, a capacitive sensing structure comprises rows of first sensors electrically coupled together and columns of second sensors electrically coupled together, wherein the first sensors include: a first arm extending in a first direction and having a first plurality of finger structures extending therefrom, a second arm extending in the first direction and having a second plurality of finger structures extending therefrom, and an end portion connecting the arms, wherein the first sensors define open regions that are occupied by the second sensors. In a second implementation, a capacitive sensing structure comprises rows of first sensors and columns of second sensors, wherein each of the first sensors includes an elongated portion having finger structures extending therefrom, and wherein each of the second sensors includes a primary portion connected to secondary portions via arms, wherein the secondary portions occupy gaps defined by the finger structures of the first sensors.

Abstract: The present invention is directed to a method of driving an in-cell touch screen. Source lines underlying a current VCOM electrode are divided into n groups. A first voltage is applied at the current VCOM electrode in a conversion phase of each sensing period. A second voltage is applied at each group of the source lines underlying the current VCOM electrode in a manner such that no net charge being contributed to the VCOM electrode by the underlying source lines, thereby parasitic capacitors associated with the current VCOM electrode having no effect on touch sensing result.

Abstract: Aspects of the present invention relate to user interface control of a head-worn computer.

Abstract: Driving a touch-sensing-enabled active matrix LCD display panel for enhancing touch sensing by reducing parasitic capacitances is considered. In one embodiment, a plurality of driving voltages is generated. The driving voltages include a common voltage, and a first and a second gate-drive reference voltages for configuring a thin film transistor (TFT) in the panel to switch on and off, respectively. When the panel is operated in a sensing mode, the common voltage that is generated includes a pulse-train waveform. Furthermore, each of the first and the second gate-drive reference voltages is substantially time-synchronized to and includes the pulse-train waveform of the common voltage during the sensing mode. In one option, the driving voltages further include a sensing-mode source-drive voltage acting as a source-drive signal for the TFT during the sensing mode. The sensing-mode source-drive voltage is substantially time-synchronized to and includes the pulse-train waveform of the common voltage.

Abstract: To provide a display capable of reducing each resistance of a drive electrode and a detection electrode, in the display which is provided with an input device having the drive electrode and the detection electrode formed on the same plane. A drive electrode includes a plurality of first electrode portions arranged in an X-axis direction, and a plurality of first connection portions each of which electrically connects the two first electrode portions adjacent to each other. A detection electrode includes a plurality of second electrode portions arranged in a Y-axis direction, and a plurality of second connection portions each of which electrically connects the two second electrode portions adjacent to each other. The first connection portion overlaps with the second connection portion in a planar view. Each of the first electrode portion and the second electrode portion contains metal or alloy, and has a mesh shape.

Abstract: To improve detection reliability of an input device provided with a display device. A display device includes an array substrate having an upper surface and a lower surface on an opposite side of the upper surface, a display functional layer provided on the upper surface side of the array substrate, a plurality of first wirings provide on the upper surface side of the array substrate and applied with a signal for driving the display functional layer, a conductive pattern provided on the lower surface of the array substrate so as to be separated from the array substrate, and a detection circuit unit detecting a change in a capacitance value between the plurality of first wirings and the conductive pattern.

Abstract: A capacitance detecting method disclosed herein, which achieves a good detection accuracy, a good resolution, and a high-speed operation, (A) (a) drives, on the basis of code sequences (di (=di1, di2, . . . , diN, where i=1, . . . , M)) which are orthogonal to one another and include ±1 and each of which has a length N, drive lines (DL1 through DLM) in parallel for each of (I) a first capacitance column (Ci1) between the drive lines and a first sense line (SL1) and (II) a second capacitance column (Ci2) between the drive lines and a second sense line (SL2) so that voltages ±V are applied and (b) outputs outputs (sFirst=(s11, s12, . . . , s1N)) from the first capacitance column (Ci1) and outputs (sSecond=(s21, s22, . . .

Abstract: Provided are a touch-panel that is capable of reliably electrically connecting a terminal-portion and a flexible-printed-circuit board even in a case in which a groove formed in a resin layer is not completely filled with a conductive material in the terminal-portion and a method for manufacturing the touch-panel. A touch-panel includes a plurality of first terminal-portions that are provided so as to correspond to a plurality of first detection electrodes. The first terminal-portion includes a first resin layer that is provided on a first substrate and has a first terminal groove formed therein and a first conductive material that fills the first terminal groove. First conductive connection portions each of which comes into contact with the first conductive material of the first terminal-portion and covers at least a portion of the outer surface of the first resin layer are provided in a plurality of first terminal portions so as to be separated from each other.

Abstract: A method of patterning a conductor on a substrate includes providing an inked elastomeric stamp inked with self-assembled monolayer-forming molecules and having a relief pattern with raised features. Then the raised features of the inked stamp contact a metal-coated visible light transparent substrate. Then the metal is etched to form an electrically conductive micropattem corresponding to the raised features of the inked stamp on the visible light transparent substrate.

Abstract: The present invention relates to a touch panel having pen touch and electrode touch functions. Specifically, the present invention relates to a touch panel, which can enhance visibility of a view area and simplify the process of manufacturing the touch panel by improving wiring of sensing patterns for pen touch and arranging overlap structures, which are created as the sensing patterns cross each other, in a separate area other than the view area.

Abstract: Systems and methods for improving display image quality on electronic displays are provided. One embodiment of an electronic display includes display pixels that share a common electrode. Each of the display pixels includes a first conductive path electrically coupled between a pixel electrode and a data line, in which the first conductive path only enables the data line to charge the pixel electrode; and a second conductive path electrically coupled between the pixel electrode and the data line in parallel with the first conductive path, in which the second conductive path enables the data line to discharge the pixel electrode such that discharge rate of the pixel electrode is approximately equal to charge rate of the pixel electrode. Additionally, the embodiment includes a touch pixel that detects occurrence and position of a touch on a screen of the electronic display using the first common electrode.

Abstract: Disclosed are a touch apparatus and an operating method of the touch apparatus. The touch apparatus includes: a depth camera device, a display screen disposed within a viewing range of the depth camera device, and a controller connected to the display screen and the depth camera device. The depth camera device is adapted to capture a depth image within the viewing range and send the depth image to the controller. The controller is adapted to receive the depth image, calculate based on the depth image and identify a current touch operation, and output an operation interface corresponding to the current touch operation to the display screen.

Abstract: An LED switch device and a matrix thereof are disclosed. There is an electroluminescent semiconductor element with a first polarity contact and a second polarity contact. There is also a first polarity LED lead frame, to which the electroluminescent semiconductor element is mounted. The first polarity contact of the electroluminescent semiconductor element is electrically connected to the first polarity LED lead frame. The LED switch device has a second polarity LED lead frame electrically connected to the second polarity contact of the electroluminescent semiconductor element. The LED switch device also has a touch sensor lead frame that is electrically connected to a touch sensor lead.

Abstract: An in-cell touch display structure includes: an upper substrate, a lower substrate, a liquid crystal layer configured between the upper and lower substrates; a black matrix layer, and a thin film transistor and sensing electrode layer. The thin film transistor and sensing electrode layer includes a gate line sub-layer having a plurality of gate lines and a plurality of connection segments separated by the gate lines, and a source line sub-layer having a plurality of source lines and a plurality of sensing conductor segments separated by the source lines, wherein part of the sensing conductor segments and part of the connection segments are electrically connected together to form a plurality of sensing conductor blocks.

Abstract: A display module includes a front panel, a backlight panel, a pressure sensor and a panel frame. The front panel includes an array of display pixels. The backlight panel is disposed under the front panel. The pressure sensor is disposed under the backlight panel. The panel frame is disposed under the pressure sensor. When an applied pressure is received by the front panel, a magnitude of the applied pressure is sensed by the pressure sensor.

Abstract: A pressing sensor that includes a first substrate, a second substrate, and a piezoelectric film between the first substrate and the second substrate. A thickness of the first substrate is greater than a thickness of the second substrate.

Abstract: An input device 1 includes a panel unit 10, a pressure-sensitive sensor 60 which detects a pressing force applied through the panel unit 10, a seal member 70 which is disposed outside the pressure-sensitive sensors 60, and a support member 80 which supports the panel unit 10 through the pressure-sensitive sensors 60 and the seal member 70. The thickness of the pressure-sensitive sensors 60 is relatively thinner than the thickness of the seal member 70, a space which is formed between the panel unit 10 and the support member 80 includes a first part S1 where the pressure-sensitive sensors 60 are arranged and the second part S2 where the seal member 70 is arranged, and the distance of the first part S1 is relatively narrower than the distance of the second part S2.

Abstract: Disclosed are a method and corresponding touch sensitive device that can be altered to change sensitivity and distance over which it interacts with an object. A touch sensor is configured to detect location of a touching object hovering above a touch surface. A ground plane is located behind the touch surface at a predetermined distance from the touch surface. A processor in the touch sensor is configured to control the effective distance between the ground plane and the touch surface and sensitivity of detection of a finger or touching object hovering above the touch surface.

Abstract: Disclosed are a touch sensitive device and corresponding method that utilizes distance fields for frame matching. The device includes a touch interface having row conductors and column conductors. A row signal generator transmits a row signal on at least one of the row conductors. A touch processor is used to process column signals from data received on at least one of the column conductors. The touch processor is configured to use discrete values from the column signals to compute a distance field function and store a representation of a distance field grid for a current frame, use the representation of the distance field grid to determine data representing a state change, and use the data representing a state change to match at least one touch location from a previous frame to at least one touch location in the current frame.

Abstract: Disclosed are a method and corresponding touch sensitive device that detects touch and provides tactile feedback. In an embodiment, the device includes a touch interface having row conductors and column conductors. A first row signal generator transmits a first row signal on a first row conductor. A second row signal generator transmits a second row signal on a second row conductor, the second row signal being orthogonal to the first row signal. A third row signal generator generates an electrotactile discharge signal on at least one of the row conductors. In an embodiment, the electrotactile discharge signal is time multiplexed with at least one of said first row signal or said second row signal. A touch processor identifies a touch event on the touch interface by processing signals present on at least one of the column conductors.

Abstract: A touch alphabet and communication system is provided. The communication system uses a predetermined set of touch gestures, such as fingertip touch patterns performable on keyless touch-sensitive surfaces, to express the user's desired communication. The touch-sensitive surface may be the touch screen display of a computer, tablet device, cell phone, or a touch-sensitive pad, for example. The finger touch patterns are based on a limited set of unique and ergonomically pleasing finger positions that may be performed in a limited area. The touch alphabet allows the user to comprehensively communicate without looking at the communication device, and with just one hand, or in another implementation, with two hands. Thus, a user can comfortably tap an entire alphabet and related functions, with one hand, without having to visualize the user interface surface or hunt for individual keys.

Abstract: A device having a dynamic tactile interface communicates with an external electronic device to provide tactile output (e.g., tactile display) based on communication with the external electronic device. Data is tactilely displayed on a computing device. Data is received from an external electronic device. The data is converted into a tangible data structure and a portion of a dynamic tactile layer is deformed corresponding to the tangible data structure. The dynamic tactile layer is arranged over a surface of the computing device and includes a set of deformable regions, wherein each deformable region deforms into an elevated tactile formation. The portion of the dynamic tactile layer includes a subset of deformable regions in the set of deformable regions.

Abstract: Some embodiments of the present invention include a method of differentiating touch screen users based on characterization of features derived from the touch event acoustics and mechanical impact and includes detecting a touch event on a touch sensitive surface, generating a vibro-acoustic waveform signal using at least one sensor detecting such touch event, converting the waveform signal into at least a domain signal, extracting distinguishing features from said domain signal, and classifying said features to associate the features of the domain signal with a particular user.