Abstract: An electronic equipment comprises a sensor circuit operative to measure at least one electrical property of a user at a plurality of frequencies to thereby capture frequency-resolved electrical characteristics of the user. The electronic equipment comprises a processing circuit operative to perform a comparison between the frequency-resolved electrical characteristics of the user and reference characteristics to authenticate the user. The processing circuit is operative to perform an unlocking operation based on a result of the comparison.

Abstract: A device includes a capacitive sampling unit that measures, at the multiple instances of time during a touch interval, capacitance values of a capacitive touch screen display associated with an area in contact with a finger touching the capacitive touch screen display. The device further includes a touch deformation area unit that determines, at the multiple instances of time, a size of the area upon the capacitive touch screen display in contact with the finger touching the capacitive touch screen display. The device also includes a touch force estimation unit that determines a rate of change in the size of the area in contact with the finger, and estimates a touching force of the finger touching the capacitive touch screen display based on the determined rate of change in the size of the area.

Abstract: A device, having a touch screen display, performs a mutual capacitance scan of rows and columns of an array of capacitive touch sensors associated with the touch screen display. The device selects a subset of the rows, and a subset of the columns, of the array of capacitive touch sensors, and performs a self capacitance scan of the selected subset of the rows, and the selected subset of the columns, of the array of capacitive touch sensors based on results of the mutual capacitance scan. The device identifies an accidental or false touch input on the touch screen display based on results of the self capacitance scan.

Abstract: A device and a method provide for transmitting, via a communication interface operating in a low frequency body area network (BAN) communication mode, a low frequency, on-body signal to another device; determining whether to continue a BAN communication with the other device based on whether an on-body BAN signal is received from the other device that is responsive to the low frequency, on-body signal; and switching the communication interface to a high frequency BAN communication mode based on a determination that the on-body BAN signal is received, wherein the high frequency BAN communication mode configures the communication interface to transmit and receive an on-body signal within a frequency band different from a frequency band of the low frequency BAN communication mode.

Abstract: An apparatus and method for determining a user activity include or define a plurality of baseline signatures, each baseline signature corresponding to a type of user activity and having data formed from a first data representing a varying static electric field and a second data representing motion. Data responsive to a varying static electric field is obtained from a first sensor, and data responsive to motion is obtained from a second sensor. The first data is combined with the second data, and the user activity is identified based on a comparison of the combined first and second data with the plurality of baseline signatures.

Abstract: A method, system and devices provide for transmitting, by a first device, a body area network (BAN) session initiation signal indicating an availability to establish an on-body communication with a second device. At least one BAN acknowledgement signal is received by the first device from the second device. The first device determines whether one of the at least one BAN acknowledgement signal is received via conducting across a body. The first device proceeds with BAN session initiation based on determining that one of the at least one BAN acknowledgement signal is received via conducting across a body and terminates BAN session initiation based on not determining that one of the at least one BAN acknowledgement signal is received via conducting across a body.

Abstract: A device comprising a display, a predictive input system coupled to the display and configured to store zone data indicating zones of the display, wherein each zone constitutes a portion of a display area; store predictive parameter data, wherein each zone is assigned a subset of predictive parameter data, wherein each subset indicates at least one of a look-ahead prediction value that indicates a time period corresponding to how far in the future a predictive user input pertains, an indication of a particular prediction algorithm, or at least one value used by the particular prediction algorithm, and wherein at least two zones of the display have different values for the subsets of predictive parameter data; receive input data via the display; determine the zone in which the input data is received; and generate prediction data based on the input data, the zone data, and the subset of predictive parameter data.

Abstract: A device and a method provide for transmitting, via a communication interface operating in a low frequency body area network (BAN) communication mode, a low frequency, on-body signal to another device; determining whether to continue a BAN communication with the other device based on whether an on-body BAN signal is received from the other device that is responsive to the low frequency, on-body signal; and switching the communication interface to a high frequency BAN communication mode based on a determination that the on-body BAN signal is received, wherein the high frequency BAN communication mode configures the communication interface to transmit and receive an on-body signal within a frequency band different from a frequency band of the low frequency BAN communication mode.

Abstract: The present invention relates to a touch screen device, a handheld device and a method for operating a touch screen device.

Abstract: A device and method detect user input for an electronic device based on linear acceleration and/or linear acceleration rate of the electronic device. More particularly, at least one of linear acceleration or linear acceleration rate of the electronic device is detected, the detected linear acceleration or acceleration rate is correlated to a gesture for controlling the electronic device.

Abstract: The present invention relates to a touch screen device, a handheld device and a method for operating a touch screen device.

Abstract: The present disclosure provides a projection device for adapting a property of a projected user interface. The device determines at least one property of a surface onto which a user interface is projected. The property of the projected user interface is changed based on the at least one property of the surface onto which the projected user interface is projected.

Abstract: An electronic device includes a proximity-sensitive touch sensor array which extends along an input surface of the electronic device and a processing device coupled to the touch sensor array. The processing device is configured to process data captured by the touch sensor array to determine a finger angle at which a finger is directed towards the input surface and an actuation position on the input surface. The processing device is configured to establish an offset-corrected actuation position as a function of the actuation position and the finger angle.

Abstract: A device, having a touch screen display, performs a mutual capacitance scan of rows and columns of an array of capacitive touch sensors associated with the touch screen display. The device selects a subset of the rows, and a subset of the columns, of the array of capacitive touch sensors, and performs a self capacitance scan of the selected subset of the rows, and the selected subset of the columns, of the array of capacitive touch sensors based on results of the mutual capacitance scan. The device identifies an accidental or false touch input on the touch screen display based on results of the self capacitance scan.

Abstract: A device includes a capacitive sampling unit that measures, at the multiple instances of time during a touch interval, capacitance values of a capacitive touch screen display associated with an area in contact with a finger touching the capacitive touch screen display. The device further includes a touch deformation area unit that determines, at the multiple instances of time, a size of the area upon the capacitive touch screen display in contact with the finger touching the capacitive touch screen display. The device also includes a touch force estimation unit that determines a rate of change in the size of the area in contact with the finger, and estimates a touching force of the finger touching the capacitive touch screen display based on the determined rate of change in the size of the area.

Abstract: A method, a device, and a non-transitory storage medium having instructions to receive a touch event originating from a touch panel; compare a timing of the touch event and a timing of a display refresh event; determine whether to adjust a time during which a next scan of the touch panel occurs based on a comparison of the timing of the touch event and the timing of the display refresh event; calculate a time value that indicates when the next scan occurs based on a determination to adjust the time; and adjust the time during which the next scan occurs based on the time value.

Abstract: Devices and methods for controlling the functionality of a pair of earbuds. The first earbud establishes a connection between the first earbud and an electronic device, searches for the second earbud of the pair of earbuds using Body Coupled Communication, BCC, and sends a signal from the first earbud to the electronic device including information defining whether the first earbud detected the second earbud during the search. The electronic device receives a signal from the at least one of the earbuds, the signal comprising information defining whether the earbud has detected the other earbud of the pair of earbuds using Body Coupled Communication, BCC, and sends a signal to the at least one earbud wherein the signal is controlled based on the received signal and includes information associated with controlling the functionality of the pair of earbuds.

Abstract: An electronic device includes a proximity-sensitive touch sensor array which extends along an input surface of the electronic device and a processing device coupled to the touch sensor array. The processing device is configured to process data captured by the touch sensor array to determine a finger angle at which a finger is directed towards the input surface and an actuation position on the input surface. The processing device is configured to establish an offset-corrected actuation position as a function of the actuation position and the finger angle.

Abstract: A control unit includes an electric field sensor and a motion sensor. Signals from the electric field sensor and the motion sensor are interpreted to generate corresponding graphical user interface control signals for a graphical user interface displayed by a separate electronic device. The graphical user interface control signals include movement control signals for a moveable element of the graphical user interface that correspond to movement of the control unit and a select control signal that corresponds to detection of a change in electric field sensed by the electric field sensor that is indicative of a change in a physical configuration of a user's body part.

Abstract: Electronic devices and related methods employ a static electric field sensor to detect variations in the electric field around the electronic device. Detected changes in the electric field invoke the performance of associated functions, thereby achieving efficient user interaction with the electronic device and/or reducing power consumption by the electronic device.