Abstract: Detection of a position of a stylus includes a touch screen, a plurality of detectors, and a control unit. The control unit is configured to detect a position of a stylus using the touch screen in an active touch input mode wherein the touch screen detects first signals from the stylus, determine a signal to noise ratio (SNR) of the active touch input mode, switch to detection of the position of the stylus using the detectors in an active non-touch input mode wherein the detectors detect second signals from the stylus when the SNR of the active touch input mode is below first a threshold, determine a SNR of the active non-touch input mode, and switch back to detection of the position of the stylus using the active touch input mode when the SNR of the active non-touch input mode is lower than a second threshold.

Abstract: A display device control pen comprises a pen body and at least one detachable accessory. The detachable accessory comprises an electronic component. The pen body is detachably assembled with the detachable accessory. The pen body comprises at least one variable-voltage circuit, a signal generating unit and a signal transmitter. When the detachable accessory is assembled to the pen body, the electronic component is electrically connected to the variable-voltage circuit and varies a voltage value of the variable-voltage circuit. The signal generating unit is coupled to the variable-voltage circuit and generates a color signal based on the varied voltage value. The signal transmitter is coupled to the signal generating unit and transmits the color signal to the display device, such that the display device displays a color on a trace formed by the pen body according to the color signal.

Abstract: A manipulation apparatus includes a body, a connection cable, a connector, and a flexible conduit. The body includes a control element, buttons, and a directional control lever. The control element is in the body and is configured to receive a control signal generated by the buttons and the directional control lever. The buttons are at a first side of the body, and the directional control lever is at a second side of the body. The connection cable is connected to the control element. The connection cable includes a first end and a second end, and the first end is connected to a third side of the body. The connector is connected to the second end of the connection cable. A flexible conduit is outside the connection cable in a sleeve manner, where the flexible conduit extends from the first end of the connection cable to the second end.

Abstract: An input display device includes a display unit that displays a screen for handwriting input on an input screen including a plurality of input fields, a stroke data processing unit that groups stroke data which is input to a capture screen by handwriting into stroke data representing characters to generate grouped stroke data as grouping stroke data, a character recognition unit that conducts character recognition on the grouping stroke data to convert the grouping stroke data into at least one recognized character, and a control processing unit that displays the at least one recognized character at the plurality of input fields of the input screen correlated with positions, at which handwriting input was performed, in the screen for handwriting input.

Abstract: A method manipulates a 3D image in three dimensions using two-dimensional gestures on a touchpad. The method moves the 3D image within an x-y plane in the direction of a multiple-finger linear gesture. A number of fingers used for the multiple-finger linear gesture is programmed in an instinct library associated with the touchpad. The method detects a multiple-finger linear gesture on a mutual capacitance touchpad and rotates the 3D image in the direction of the multiple-finger linear gesture about an axis in the x-y plane perpendicular to the multiple-finger linear gesture. The method also rotates the 3D image about the x-y plane in the direction of the multiple-finger linear gesture at a speed proportional to the speed of the multiple-finger linear gesture.

Abstract: An article, such as globe, comprises a housing portion or substrate, which may be non-flat, and a capacitive touch device, such as an x-y touch pad. The capacitive touch device comprises a first capacitive touch device part which comprises a first substrate supporting a first conductive track or pad and a second capacitive touch device part which comprises a second substrate supporting a second conductive track or pad. The first and second capacitive touch device parts overlap so as to capacitively couple the first conductive track or pad and the second conductive track or pad. The capacitive touch device is disposed adjacent to the housing portion.

Abstract: Certain example embodiments relate to capacitive touch panels. First and second glass substrates are substantially parallel and spaced apart from one another. At least one multi-layer transparent conductive coating (TCC) is patterned into electrodes and located between the first and second substrates. The TCC(s) include(s) at least one conductive layer including silver, a dielectric layer including zinc oxide under and directly contacting the conductive layer including silver, and a dielectric layer(s) including tin oxide or silicon nitride over the conductive layer including silver. Processing circuitry electrically connects to the electrodes and measures an aspect of the electrodes' capacitance. A laminate material is located between the first and second glass substrates. The TCC(s), when blanket deposited, may have a visible transmission of at least 88%, a sheet resistances of no more than 10 ohms per square, and a haze of no more than 0.5%. Mutual and self-capacitance designs are disclosed.

Abstract: A projected capacitive touch panel, including a substrate, a silver-inclusive transparent conductive coating which forms a plurality of row electrodes, a plurality of column electrodes, and a plurality of conductive traces, and a signal processor which sequentially measures a capacitance between each of row electrodes and an adjacent column electrode. The row electrodes, the plurality of column electrodes, and the plurality of traces are on a plane substantially parallel to the substrate. Each of the row electrodes is electrically connected to the signal processor by one of the plurality of conductive traces. The plurality of traces are at least partially substantially parallel to the column electrodes.

Abstract: According to an aspect, a display device with a touch detection function includes a plurality of drive electrodes that face a plurality of pixel electrodes in an orthogonal direction to the surface of the substrate, and extend in a direction parallel to the direction in which a plurality of signal lines extend. The display device with a touch detection function also includes a scan driving unit that applies a touch drive signal to a signal line that faces, in an overlapping manner in the orthogonal direction, a drive electrode to which the touch drive signal is applied.

Abstract: A low cost, two-dimensional, fingerprint sensor includes a pixel array, each pixel including a switch and a pixel electrode for forming a capacitance with a fingertip. One or more active transmission electrodes are spaced from a selected row of the pixel array, and transmit a carrier signal into the finger without direct coupling into the selected pixels. Signals sensed by the pixel array are coupled to an independent integrated circuit, and connections between the IC and the pixel array are reduced by demultiplexing row select lines, and by multiplexing sensed column data. Differential sensing may be used to improve common mode noise rejection. The fingerprint sensor may be conveniently incorporated within a conventional touchpad LCD panel, and can mimic the performance of lower density touchpad pixels.

Abstract: The present application provides a touch sensor and a fabricating method thereof and a touch display panel, comprising: a substrate, where the substrate includes a plurality of grooves which are strip-shaped and intersected with each other to define a grid shape; a first infiltrating adjustment layer, disposed on an inside wall of the grooves; and a touch electrodes filled in the groove. The first infiltrating adjustment layer is positioned between the groove and the touch electrodes. An infiltration angle between the touch electrodes in solution state and the first infiltrating adjustment layer is ?, an infiltration angle between the touch electrodes in solution state and the substrate is ?, wherein ? is not equal to ?.

Abstract: A capacitance sensing circuit includes: a front-end circuit, a first subtracting and summing circuit and a capacitance judging circuit; wherein the front-end circuit is coupled to the detection circuit; the first subtracting and summing circuit is coupled between the front-end circuit and the capacitance judging circuit, and includes: a subtracting unit; a summing unit, coupled to the subtracting unit; a first converter, coupled between the summing unit and the capacitance judging unit; and a second converter, coupled between the first converter and the subtracting unit; and the capacitance judging circuit is configured to judge a capacitance change of the detection capacitor. According to the present application, resistance against noise may be improved.

Abstract: The present exemplary embodiments provide a touch display device which connects a touch driving circuit and a plurality of touch sensors using a plurality of dummy pixels disposed on a display panel to recognize touch event of a user. When the touch wiring line is implemented, the same material as the pixel electrode or the source line included in the plurality of dummy pixels is used so that a separate process for implementing the touch wiring line is not necessary. Further, in a pixel structure in which one data line is disposed for every two pixels, the source line is disposed in a region where the data line is not disposed to be used as a touch wiring line. Therefore, the touch recognizable area may expand as compared with a case using a pixel metal.

Abstract: A display device is provided. An input/output device is provided. A data processing device is provided. A display method is provided. The display device includes a display panel and a control portion. The control portion has a function of receiving image data and control data, a function of generating first data on the basis of the image data, a function of generating second data on the basis of the image data, a function of detecting a contour portion from the image data, a function of generating third data in which the contour portion is emphasized, and a function of supplying the first to third data. The display panel has a function of receiving the first to third data and includes a pixel. The pixel includes a first display element and a second display element. The first display element has a function of displaying an image on the basis of the first data, and the second display element has a function of displaying an image on the basis of the second or third data.

Abstract: A flexible display device including a display panel configured to display an image and including first and second bending areas configured to be bent along first and second folding axes, respectively, and a touch sensing unit disposed on the display panel. The touch sensing unit includes a base insulation layer, a first touch electrode part disposed on a first surface of the base insulation layer and overlapping the first bending area to detect an external input, and a second touch electrode part disposed on a second, opposing surface of the base insulation layer and overlapping the second bending area to detect an external input. A portion of the display panel is disposed between the first folding axis and the touch sensing unit, and a portion of the touch sensing unit is disposed between the second folding axis and the display panel, when the flexible display device is bent.

Abstract: The present invention relates to a man-machine interface device comprising (i) a display with display pixels distributed within a display zone, (ii) display control elements (302, 304) disposed in said display zone and used to control said display pixels, (iii) capacitive measurement electrodes (502) distributed within said display zone, (iv) capacitive excitation and detection means, (v) at least one guard element disposed in proximity to the capacitive measurement electrodes (502), in which at least one display control element (302, 304) is also used as guard element or as capacitive measurement electrode (502). The invention also relates to an apparatus comprising the device.

Abstract: A touch panel includes plural scanning electrodes, plural detection electrodes that are formed to intersect with the plural scanning electrodes, one or a plurality of layers being disposed between the plural detection electrodes and the plural scanning electrodes, plural holes that are arrayed apart from each other on each of the plural detection electrodes, and shaped into polygons each shaped to have five or more corners in a plan view, and plural dummy electrodes that are formed between the respective adjacent detection electrodes, made of the same material as that of the detection electrode, and electrically isolated from each other, in which the plural dummy electrodes are shaped into the polygons in a plan view.

Abstract: Provided are a dual-screen tablet computer and a display and touch control method therefor. The dual-screen tablet computer includes a first display screen, a second display screen, a first touch screen and a second touch screen. The first touch screen is bonded to the first display screen. The second touch screen is bonded to the second display screen. The first display screen and the second display screen are connected to each other through a rotating shaft or a hinge. The first touch screen and the second touch screen are electrically connected to one single touch main control module simultaneously. When the display mode of the dual-screen tablet computer is configured to the expanded display mode, different touch screens can be operated simultaneously.

Abstract: A slim type touch panel is provided. The slim type touch panel includes an upper substrate, a first sensor electrode layer disposed at a lower part of the upper substrate, an insulating film disposed at a lower part of the first sensor electrode layer, and a second sensor electrode layer disposed at a lower part of the insulating film, or includes a first sensor electrode cover sheet in which a sensor electrode layer is patterned, a first adhesive layer disposed at a lower part of the first sensor electrode cover sheet, and a film layer disposed at a lower part of the first adhesive layer and comprising a second sensor electrode layer.

Abstract: An input device is configured to detect force being applied to an input region of the device by an input object, in addition to the position of the input object using touch sensing methods. Aspects include driving a force sensing electrode of the input device using an anti-guarding voltage alternating with a ground or guard voltage, while driving the touch sensing electrodes with a reference voltage, to obtain touch measurements, force measurements, interference measurements, double the force signal, and/o double the touch signal for differential touch and force detection. Aspects also include driving sensor electrodes using orthogonal signals and performing in-phase and quadrature demodulation of the received signal for simultaneous and independent touch and force measurements.

Abstract: A device has a touch processing module that processes touch screen input to determine if the manner in which the input was entered indicates that the user intends for execution of a particular command. In one embodiment, the module may acquire fingerprint data from the user's input and analyze the data to determine if the input was entered with a particular finger or finger sequence. In another embodiment, the module may also acquire timing data from the user's entry of a plurality of inputs and analyze the timing data to determine if the touch screen input was entered with a particular timing or cadence. In still another embodiment, the module may also acquire force data from the user's entry of a plurality of touch screen inputs and analyze the force data to determine to determine if the touch screen input was entered with a particular force.

Abstract: Variable rate display interfaces are disclosed. In an exemplary aspect, a high-speed reverse data transfer is enabled over plural lanes of a display serial interface (DSI) bus during blanking periods. Further increases in bandwidth of each high-speed reverse data transfer may be achieved by increasing DSI clock speed during the blanking periods. Since a display relies on a host clock to send reverse data, the frequency of the reverse data is increased, which effectively increases the bandwidth of reverse channel lanes. By increasing the reverse bandwidth over existing pins in the DSI bus, more data may be transferred to the host, including raw touch/stylus data rather than processed data. The raw data may then be processed by the host's relatively powerful processors. By shifting the processing to the host, the need for a powerful touch screen controller (TSC) and/or a powerful touch display driver integrated circuit (TDDI) may be avoided.

Abstract: An input device described herein includes at least one hybrid electrode that is used to perform both capacitive sensing to detect an input object (e.g., a finger or stylus) and force sensing to determine the force applied by the input object on the input device. During a first time period, the input device drives a modulated signal on one more capacitive sensor electrodes to perform capacitive sensing. However, during a second time period, the input device drives a DC voltage across one or more of the capacitive sensor electrodes to perform force sensing. In one example, during the first time period, the input device drives the modulated signal on transmitter electrodes and measures resulting signals on receiver electrodes. During the second time period, however, the input device may drive the DC voltage across the transmitter or receiver electrodes to measure a force applied by the input object.

Abstract: A touchscreen device includes: a touch sensing unit including a transmission module configured to transmit a touch measurement signal and a reception module configured to receive the touch measurement signal from the transmission module; a control unit configured to control the transmission module and the reception module and calculate a touch position according to an output signal of the touch sensing unit; a position indication unit disposed adjacent to the touch sensing unit and configured to emit visibly recognizable light; and a support member configured to support the touch sensing unit and the position indication unit. When the touch sensing unit senses a motion of a user in a sensing region, the control unit controls the position indication unit to emit light that is turned on and off to be visibly recognizable.

Abstract: An input device and associated processing system and method are disclosed for operating a plurality of sensor electrodes. The method comprises driving, during a first period, a first portion of a plurality of sensor electrodes to a first voltage. The first portion corresponds to a first number of sensor electrodes. The method further comprises driving, during the first period, a second portion of the plurality of sensor electrodes to a second voltage less than the first voltage. The second portion corresponds to a second number of sensor electrodes. The first number and second number are based on a plurality of digital codes used to drive the first and second portions. The method further comprises transferring charge between the first portion and second portion to drive the second portion to an intermediate voltage, and driving, during a second period, the second portion from the intermediate voltage to the first voltage.

Abstract: In one embodiment, a touch sensor includes a substrate and a mesh of conductive material formed on the substrate and configured to extend across a display. The mesh includes first lines of conductive material that are substantially parallel to each other. The first lines extend across at least a portion of the display at a first angle relative to a first axis. The first lines are separated from each other along the first axis by a sequence of separation distances having corresponding magnitudes, where magnitudes of more than one separation distance from among the sequence of separation distances are based on a phasor step ? and a phasor magnitude of at least one phasor.

Abstract: A dual-mode capacitive touch display panel includes first and second substrates, a display layer disposed between the first and second substrates, at least two first touch electrodes, at least two second touch electrodes, plural pressure sensing electrodes, and a shielding conductive layer. The first and second touch electrodes are disposed on the first substrate and overlap sub-pixels thereon. The first and second touch electrodes are respectively separated. The pressure sensing electrodes are disposed on the second substrate, and overlap the corresponding first or second touch electrodes in a vertical projection direction. The shielding conductive layer is disposed on the second substrate and includes plural openings, the pressure sensing electrodes overlap the corresponding openings, and the pressure sensing electrodes have a lower surface resistance than the shielding conductive layer does.

Abstract: An input device described herein includes at least one dual purpose electrode that is used to perform both capacitive sensing to detect an input object (e.g., a finger or stylus) and force sensing to determine the force applied by the input object on the input device. During a first time period, the input device performs capacitive sensing using a first electrode of the plurality of sensor electrodes. However, during a second time period, the input device excites the first electrode and measures a resistance corresponding to the first electrode. The input device determines a force applied by an input object on the input device based on the measured resistance.

Abstract: The drive control device includes a display control part and a touch control part. The display control part includes a control circuit operable to control first and second frame modes, and a clock pulse generator operable to produce a display line clock signal in synchronization with a display line switching cycle. The control circuit changes display and non-display drive terms in start timing on an individual display frame period basis in the first frame mode. In the second frame mode, each display frame period includes only one display drive term; the display drive term is not interrupted by a non-display drive term halfway. The second frame mode is arranged so that the cycle of the display line clock signal in synchronization with the display line switching cycle is made longer than that in the first frame mode.

Abstract: A capacitance-type touch panel, allowing disturbance noise and touch detection time to be reduced and having a simple configuration, is provided. The capacitance-type touch panel including: a plurality of drive electrodes each having a strip shape; a drive control circuit performing control such that a drive signal for touch detection is selectively applied to the drive electrodes; a plurality of touch detection electrodes arranged to intersect with the drive electrodes in such a manner that capacitance is formed in each intersecting part, and each outputting a detection signal in synchronization with the drive signal; and a detection circuit detecting an external proximity object based on the detection signal. The drive control circuit controls application of the drive signal in such a manner that the detection signal is a polarity-alternating signal including a positive-negative asymmetrical signal component which is due to presence of the external proximity object.

Abstract: The present disclosure discloses a smart wearable device and an information input method thereof.

Abstract: An input device is configured to detect force being applied to an input region of the device by an input object, in addition to the position of the input object using touch sensing methods. Aspects include driving a force sensing electrode of the input device using an anti-guarding voltage alternating with a ground or guard voltage, while driving the touch sensing electrodes with a reference voltage, to obtain touch measurements, force measurements, interference measurements, double the force signal, and/o double the touch signal for differential touch and force detection. Aspects also include driving sensor electrodes using orthogonal signals and performing in-phase and quadrature demodulation of the received signal for simultaneous and independent touch and force measurements.

Abstract: An input method is provided. The method includes receiving a touch operation in a first region of a touch screen, the first region corresponding to an input region of a virtual input unit; measuring a pressure of the touch operation; determining a first input key corresponding to a location of the touch operation; and determining an instruction corresponding to the touch operation based on the measured pressure and the first input key.

Abstract: A touch panel is disclosed herein. In an embodiment, the touch panel includes a substrate with first and second surfaces, a drive electrode facing the first surface, a plurality of touch detection electrodes facing the second surface, and a dummy electrode between adjacent touch detection electrodes. Each touch detection electrode includes a first conductive thin wire extending parallel to the first and second surfaces. The dummy electrode includes a second conductive thin wire extending along the first conductive thin wire. The first conductive thin wire includes a first bent portion and a second bent portion alternately arranged with the first conductive thin wire having a zigzag pattern. The second conductive thin wire includes a third bent portion and a slit that are alternately arranged. The third bent portion is arranged on a virtual straight line formed by virtually connecting the first bent portions of one first conductive thin wire.

Abstract: A touch electronic device and method are provided. In one implementation, a touch electronic device includes a wireless transmission module, utilized to receive a data request information transmitted by a first external electronic device, and to transmit an identification information to the first external electronic device to execute identification of the touch electronic device. The electronic device further includes a touch panel, utilized to display a normal interface and an interface pattern, or only display the normal interface. Further, the electronic device includes a touch link module, utilized to develop a touch link between the touch electronic device and a second external electronic device through the touch panel after the wireless transmission module receives the data request information and the normal interface is not used, and to receive the identification information transmitted by the second external electronic device through the touch link.

Abstract: A display device with a touch panel includes a display panel, and a touch panel formed above the display panel. The touch panel includes X electrodes which extend in a first direction, and Y electrodes which extend in a second direction different from the first direction. The X electrodes and the Y electrodes respectively include intersection portions each formed where the X electrodes and the Y electrodes overlap each other, and electrode portions each formed between the intersection portions, wherein the electrode portions of one of the X electrodes is smaller in area than the electrode portions of one of the Y electrodes, and wherein floating electrodes are formed close to the electrode portion of the one of the X electrodes or Y electrodes, and over a reduced portion of the X electrode.

Abstract: A hand or a finger detection device and a computing device comprising a hand or a finger detection device includes a proximity sensor grid having a plurality of proximity sensors, and a processor. The proximity sensor grid is configured to provide a sensor image, where the sensor image is a proximity sensor grid representation of a hand or a finger in proximity to the proximity sensor grid.

Abstract: The disclosure provides an array substrate and a color filter substrate of a capacitive touch control screen, a touch control display device and a method for driving the touch control display device, so as to achieve the self-capacitive multi-point touch. The array substrate of the capacitive touch control screen includes: a peripheral area and a display area; a plurality of pixel units with pixel electrodes arranged in the display area; a plurality of touch control electrodes; and touch control electrode lead wires connected with a module configured to detect a touch control signal, wherein each of the touch control electrodes is connected respectively with one of the touch control electrode lead wires.

Abstract: Discussed is a touch screen apparatus according to an embodiment having a flat, curved or bending type display device, and an electronic device including the same. The touch screen apparatus includes a touch sensing circuit for outputting three-dimensional (3D) touch information by sensing a touch position through a first touch sensor and sensing a touch force through a second touch sensor.

Abstract: A touch panel driving device that can easily perform a force sensing drive with a touch drive unit and a force drive unit that can be integrally formed in one-chip, a touch panel device can include the one-chip touch panel drive device, and a driving method thereof are provided. The touch panel device can include a bypass path that supplies a second touch sensing signal to a drive unit without passing through a sensing unit. Accordingly, the touch panel device can perform both touch sensing based on a first touch sensing signal and force sensing based on a second touch sensing signal using a single drive unit and prevent an erroneous second touch sensing signal from being transmitted to the drive unit due via the sensing unit, thereby easily and more accurately performing the force sensing.

Abstract: According to one embodiment, a display device includes drive electrodes, sensing electrodes, a driver, a first sensor circuit, and a second sensor circuit, wherein the drive electrodes include first drive electrodes and second drive electrodes which are arranged between the adjacent first drive electrodes, and a first width of the first drive electrodes in a first direction is an integer multiple of a second width of the second drive electrodes in the first direction.

Abstract: A measuring process unit for executing a measuring process of, in correspondence with a plurality of combinations obtained by respectively combining a plurality of connection terminals Tx and a plurality of connection terminals Ty, and in respect of the connection terminals Tx, Ty corresponding to each of the combinations, supplying an AC voltage SA to the connection terminals Ty by means of an AC current source 2 and detecting electric current flowing in the connection terminals Tx by means of an ammeter 3, to thereby acquire currents corresponding to each of the combinations; and a calculating unit for executing a calculating process of, based on the size of the currents detected by the ammeter 3 in the measuring process and on information indicating the currents' phases, calculating capacitance and resistance values corresponding to each of the combinations.

Abstract: Various techniques may be employed for assigning user inputs such as a touch on a touchscreen to various input controls such as buttons or other features provided on a touchscreen. One example input assignment technique is a nearest neighbor technique, whereby a touch may, for example, be assigned to an input control that is positioned closest to the touch location. Another example input assignment technique is an angle and distance technique, whereby a touch may, for example, be assigned to an input control based on an angle and a distance of the touch relative to a prior touch.

Abstract: An information processing apparatus includes an image obtaining unit configured to obtain an image obtained while imaging is performed by pointing an imaging unit towards a target surface, a distance obtaining unit configured to obtain, with regard to a plurality of areas constituting the image, information equivalent to distances from a position corresponding to a reference to surfaces to be imaged in the respective areas, and a recognition unit configured to use the information obtained by the distance obtaining unit with regard to a first area where a predetermined region of an object is imaged in one of the images obtained by the image obtaining unit and the information obtained by the distance obtaining unit with regard to a second area that is a part of the image and in contact with a surrounding of the first area to recognize an input state to the target surface by the object.

Abstract: Aspects of the technology include receiving (702) data indicative of a change from a first status to a second status, generating (704) a timestamp indicative of a time at which the change in status occurred, and storing (706) the timestamp in memory. Further aspects include receiving (708) data indicative of a reversion to the first status and, responsive thereto, retrieving (710) data indicative of the timestamp from memory. Additionally, aspects include providing (712) data indicative of the timestamp to an application configured for making content available to a user. The data indicative of the timestamp may initiate playback of the content to a time at which the change in status occurred.

Abstract: Methods and systems for selecting candidate content for insertion into a content presentation to generate tailored user interface screens are described. According to various embodiments, the system receives a set of publication data including a plurality of content pages with content elements. The system determines a set of content divisions among the content pages and one or more insertion points corresponding to one or more content divisions. The system determines a set of candidate insertion content based on the set of content elements and the insertion points. The system causes presentation of the set of publication data including the plurality of content pages. Upon presentation of a content page proximate to an insertion point, the system selects a candidate insertion content item for insertion into the insertion point and causes presentation of the candidate insertion content during presentation of the set of publication data.

Abstract: A computing system providing access to electronic files is provided. The computing system includes a processor and a data store coupled to the processor and configured to store the electronic files. A user interface component is coupled to the processor and is configured to generate a user interface that allows a first user to select an electronic file to be re-shared with second user. The processor is configured to detect re-sharing of the selected electronic file by the first user and automatically generate a notification to a third user. The notification is configured to allow the third user to cancel the re-sharing of the electronic file.

Abstract: A set of reconfigurable clip-on modules for mobile computing devices includes two or more modules and at least one of the modules has an input button or other control and at least one of the modules can communicate with the computing device without needing to be connected to it via a wire. The input button is mapped to a user input in a program, such as a game, which is running or displayed on the computing device to which the modules are clipped. In an embodiment, user inputs via the buttons or other controls on the clip-on modules are mapped to user inputs in a game running on the device, which may be a touch-screen device, and the mapping between user inputs via the buttons and user inputs in the game may change dependent upon the game being played, user preference, or other criteria.

Abstract: Presenting a list of personalized strings to a user in response to the user's interaction with a single key of a keyboard. Interaction of a user with a single key of a keyboard is detected. Responsive to detecting the user interaction at the single keyboard key, a string type associated with the user interaction is identified. One or more personalized strings that are associated with the user and that are of the identified string type are also identified. A list of strings with the one or more personalized strings of the string type associated with the user interaction is then populated. The populated list of strings is then presented, wherein each string of the list of strings comprises a user-selectable element.

Abstract: Disclosed are some implementations of systems, apparatus, methods and computer program products for publisher and share action integration in a user interface (UI) for automated messaging. In some implementations, information is displayed in a first component and in a second component in a UI on a display. The first component is a publisher configured for composing and sharing messages on different communication channels using different share actions. The second component includes links to data items. When one of the data items is selected, a set of share actions for sharing the selected item using the publisher can be identified and displayed. When one of the displayed share actions is selected, it can be determined that the selected share action is applicable to one of the communication channels. A reference to the selected item can be provided in a message being composed in the publisher for sharing on the one communication channel.