Abstract: A mobile ultrasound system will pair with a wireless ultrasound probe for exclusive communication between the two for an ultrasound exam when the wireless probe is brought to within a predetermined distance of the mobile ultrasound system. The ultrasound system determines that the wireless probe is within the predetermined distance from the strength of the signal received by the system from the wireless probe. Pairing can proceed automatically when a wireless probe is within the predetermined distance, or after a user actuates a control to initiate the pairing. The ultrasound system may display the identity of a probe within range on the display of the system for selection by the user so that the user will be confident that pairing will be done with the desired wireless probe.

Abstract: Devices implementing light communications use waveguides to efficiently collect wavelength-specific light used for the light communications and propagate that collected light to a sensor. More particularly, light comprising a plurality of wavelengths and collected from one or more entrances propagates along a TIR waveguide until disrupted by a diffusive element, which effectively directs the propagating light to one or more sensors. Each sensor detects a subset of the plurality of wavelengths. In so doing, the solution presented herein increases the amount of light available for the light communications and/or reduces the number of sensors needed for the light communications, e.g., by providing light collected from multiple different locations to a single sensor. The waveguide solution presented herein may be implemented inside a device and/or along an exterior surface, e.g., housing or casing, of a device.

Abstract: Devices implementing light communications use waveguides to efficiently collect light used for the light communications and propagate that collected light to a sensor. More particularly, light collected from one or more sensors propagates along a TIR waveguide until disrupted by a diffusive element, which effectively directs the propagating light to a sensor. In so doing, the solution presented herein increases the amount of light available for the light communications and/or reduces the number of sensors needed for the light communications, e.g., by providing light collected from multiple different locations to a single sensor. The waveguide solution presented herein may be implemented inside a device and/or along an exterior surface, e.g., housing or casing, of a device.

Abstract: The present invention shows an apparatus for a chamfer machining of a toothed workpiece comprising a workpiece spindle having a workpiece holder rotatably supported about an axis of rotation for holding the workpiece, a tool spindle having a tool holder rotatably supported about an axis of rotation for holding a finger mill, wherein the tool spindle is travelable relative to the workpiece holder via at least one linear axis of the apparatus, and a control having a machining function that rotates the workpiece held in the workpiece holder by controlling the workpiece spindle for the chamfer machining of a toothed workpiece while a finger mill held in the tool holder engages at the edge to be machined. It is characterized in that the machining function varies the rotational speed of the workpiece during the chamfer machining.

Abstract: The invention concerns an electronic wearable device (1) adapted to form a loop around a body part of a user and comprising an elongated member (10) being a part of the loop and a control unit (20). The elongated member (10) comprises an electroactive polymer (11), whereby the shape of the electroactive polymer is adapted to be changed by regulating a voltage applied to the electroactive polymer. The invention also concerns an electronic wireless communication system comprising the electronic wearable device and a mobile electronic communication device for wireless communication with the electronic wearable device.

Abstract: A mobile ultrasound system will pair with a wireless ultrasound probe for exclusive communication between the two for an ultrasound exam when the wireless probe is brought to within a predetermined distance of the mobile ultrasound system. The ultrasound system determines that the wireless probe is within the predetermined distance from the strength of the signal received by the system from the wireless probe. Pairing can proceed automatically when a wireless probe is within the predetermined distance, or after a user actuates a control to initiate the pairing. The ultrasound system may display the identity of a probe within range on the display of the system for selection by the user so that the user will be confident that pairing will be done with the desired wireless probe.

Abstract: A computing device includes a display having a striped polarizer, the striped polarizer includes a set of sub-areas having a first polarization interspersed between another set of sub-areas having a second polarization. The sub-areas are arranged to provide an alternating polarization across a dimension of the display. The computing device may be configured to receive information specifying a privacy display mode, select a privacy display mode based upon the received information, receive input display data configured to represent information for display, generate, in response to selecting the privacy display mode, output display data by inverting a first portion of pixels in the input display data which are associated with a first polarization, and not inverting a second portion of pixels in the input display data which are associated with a second polarization, and provide the output display data to a display.

Abstract: A touch sensor is presented. The touch sensor comprises a first electrode (21a); a second electrode (21b); a spacing layer (22) disposed between the first and second electrodes to separate the first and second electrodes; a first sealing layer (23a) and a second sealing layer (23b), wherein the first and second electrodes and the spacing layer are disposed between the first and second sealing layers; wherein the first electrode, the second electrode, the spacing layer, the first sealing layer and the second sealing layer are bendable; a capacitive touch circuitry (24) arranged to sense a capacitive coupling between the first and second electrodes and to output a capacitive touch signal as a response to a change in the capacitive coupling; and a charge inducing circuitry (25) connected to the first and second electrodes arranged to independently induce electric charge to the first and second electrodes. A touch sensitive system comprising the touch sensor is also presented.

Abstract: The disclosure relates to the technical field of capacitive touch panels and discloses a touchpen which may be used in mobile phones, computers and other devices with touch panels for writing characters, letters and other symbols. In particular it relates to a capacitive touchpen 10 for inputting information into an electronic device 1 through touching of a capacitive touch panel 30, the capacitive pen comprising an elongated body member 11 comprising a conductive part 13 and a tip 12 disposed at one end of the body member 11 having a contact surface 14 for contacting the capacitive touch panel 30. The conductive part 13 is configured such that the distortion of the touch panel's electrostatic field caused by the conductive part 13 when changing the position of the touchpen 10 in relation to the capacitive touch panel 30, when the contact surface is kept in contact with the touch panel 30, is sufficient to register a change in capacitance by the capacitive touch panel 30.

Abstract: A method, a device, and a non-transitory storage medium having instructions to analyze a characteristic of an ultrasonic signal that propagated on a face of a user of the computational device and effected by an on-body touch, by the user, in an area in which the ultrasonic signal has propagated, wherein the characteristic includes at least one of facial expression or contraction state of a facial muscle; select an input based on an analysis of the ultrasound event; and perform an action specified by the input.

Abstract: The present invention relates to the field of devices with a possibility of recording light data, the device having a flash and more particular to such devices having a flash (300) which light cone (306) is adaptable. The present invention provides a method for adapting a light cone (306) from a flash (300) of a device using a liquid lens (302) and a device implementing such a method.

Abstract: A computing device may be configured to authenticate a user for access control, and may include at least one ground electrode configured for contact with a user, an impedance sensor coupled to the least one ground electrode, where the impedance sensor may be configured to perform a measurement based on a touch input from the user, a memory which stores instructions, and a processor, coupled the impedance sensor and the memory, where the processor may be configured to execute the instructions. The instructions may cause the processor to: receive the touch input from the user, receive an impedance value based on the touch input measured by the impedance sensor, and determine whether the received impedance value corresponds to at least one stored impedance value associated with a user profile.

Abstract: The present invention presents a mobile electronic device comprising dynamic hardware controls and a method for controlling dynamic hardware controls. The mobile electronic device comprises a pressure sensing film arranged to detect a pressure applied on at least one portion of at least one side of the mobile electronic device and electroactive polymer film with a conductive coating arranged overlaying the pressure sensing film. The electroactive polymer film comprises at least one deformable segment that may be deformed temporarily by the application of a voltage over the at least one deformable segment in the electroactive polymer film, the mobile electronic device further comprises a control unit arranged to control the dynamic hardware controls.

Abstract: A touch sensor is presented. The touch sensor comprises a first electrode (21a); a second electrode (21b); a spacing layer (22) disposed between the first and second electrodes to separate the first and second electrodes; a first sealing layer (23a) and a second sealing layer (23b), wherein the first and second electrodes and the spacing layer are disposed between the first and second sealing layers; wherein the first electrode, the second electrode, the spacing layer, the first sealing layer and the second sealing layer are bendable; a capacitive touch circuitry (24) arranged to sense a capacitive coupling between the first and second electrodes and to output a capacitive touch signal as a response to a change in the capacitive coupling; and a charge inducing circuitry (25) connected to the first and second electrodes arranged to independently induce electric charge to the first and second electrodes. A touch sensitive system comprising the touch sensor is also presented.

Abstract: A headset equipped with one or more materials that can change in size to facilitate the wearing experience by the user. The change in size may provide for a more accurate fit for the user to prevent or reduce the likelihood of the headset inadvertently moving away from the user's ear (e.g., falling out from the ear canal). The changeable size may also be used to convey aspects of the received sound to provide a more powerful listening experience. The material may be constructed from an electroactive polymer that changes in size when stimulated by an electric field. The headset includes a controller with an input for a user to control the size of the material.

Abstract: A display device comprising an organic light emitting diode (OLED) display; and an electrophoretic display (EPD). The OLED display and the EPD share a common backplane, the common backplane comprising thin-film transistors (TFTs) of the OLED display and TFTs of the EPD thereon.

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 may comprise a housing, wherein the housing comprises one or more recesses; a display panel; a backlight; one or more light sources, wherein within each of the one or more recesses of the housing, one or more of the one or more light sources reside and are configured to emit light into the backlight; and a printed circuit board, wherein each of the one or more of the one or more light sources are connected to the printed circuit board, wherein each of the one or more recesses comprises at least one wall that comprises an electrical attachment area for the one or more of the one or more light sources.

Abstract: The present invention relates to the field of devices with a possibility of recording light data, the device having a flash and more particular to such devices having a flash (300) which light cone (306) is adaptable. The present invention provides a method for adapting a light cone (306) from a flash (300) of a device using a liquid lens (302) and a device implementing such a method.

Abstract: A headset equipped with one or more materials that can change in size to facilitate the wearing experience by the user. The change in size may provide for a more accurate fit for the user to prevent or reduce the likelihood of the headset inadvertently moving away from the user's ear (e.g., falling out from the ear canal). The changeable size may also be used to convey aspects of the received sound to provide a more powerful listening experience. The material may be constructed from an electroactive polymer that changes in size when stimulated by an electric field. The headset includes a controller with an input for a user to control the size of the material.