Abstract: The wearable article 200 comprises an electronics module 100. An electronics module holder 203 holds the electronics module 100. A visual marker 205 is located on an outside surface of the wearable article 200 at a position corresponding to the electronics module holder 203. The module 100 comprises a housing, and a processor 101 and electronics component 111 disposed within the housing. The electronics component 111 detects an object being brought into proximity with the electronics module 100. The visual marker 205 indicates the location of the electronics component 111 in the electronics module holder 203. The electronics component 111 generates a signal in response to the object being brought into the vicinity of the visual marker 205. The processor 101 is arranged to receive the signal generated by the electronics component 111 and is arranged to perform an action in response to receiving the signal.

Abstract: An interface (101) is arranged to communicatively couple with an electronics arrangement of the wearable article so as to receive a signal from the electronics arrangement. A controller (103) is communicatively coupled to the interface (101) and arranged to receive the signal from the interface (101). A power source (105) is coupled to the controller (103) and arranged to supply power to the controller (103). A first antenna (107) is arranged to communicatively couple with a mobile device over a first wireless communication protocol. A second antenna (109) is arranged to communicatively couple with the mobile device over a second wireless communication protocol. In response to the mobile device being brought into proximity with the electronics module (100), the first antenna (107) is triggered to transmit information to the mobile device over the first wireless communication protocol.

Abstract: The wearable article (200) comprises a sensing component. The electronics module (100) is removably coupled to the wearable article (200). The electronics module comprises a housing and a processor disposed within the housing (101). An interface element (121, 123) interfaces with the sensing component so as to receive signals from the sensing component and provide the same to the processor. A sensor (105) is disposed within the housing (101). The sensor (105) monitors a property of the environment external the electronics module (100) through the housing (101). The housing (101) is constructed such that the sensor (105) has line of sight through the housing (101).

Abstract: A wearable article incorporates a sensor device (10) which comprises a sensor module (101) and an input-output interface (105) arranged to send and receive data over a bidirectional line (11). A buffer (103) is arranged to store time-series sensor data. A programmable and erasable non-volatile memory (109) receives and stores an identifier for the sensor device (10). The sensor module (101) generates an inference using the sensor data. The sensor device (10) is arranged to switch between sending, over the bidirectional line (11), data sensed by the sensor module (101) and the generated inference. The sensor device (10) is a single-wire sensor device. The input-output interface (105) is a single-wire input-output interface. The sensor module (101) is a motion, electropotential, electroimpedance, chemical, or optical sensor module. The sensor device (10) is provided in a system comprising a master device.

Abstract: A wearable article comprising: a first biosensor; an erasable and programmable memory configured to store information relating to the wearable article and/or the first biosensor; and an interface for connection to an electronic module. The interface is configured to permit the transfer of information between the memory and an electronic module connected to the interface. The electronic module is able to read information from the memory and write information to the memory via the interface. The memory may have a single-wire input-output interface. The information may comprise wearable article size information. The wearable article size information may be used to determine a compensation that should be performed to sensor data received from the wearable article to compensate for electrical properties of the wearable article.

Abstract: The sensor device (10) comprises a sensor module (101) and an input-output interface (105) arranged to send and receive data over a bidirectional line (11). A buffer (103) is arranged to store time-series sensor data. A programmable and erasable nonvolatile memory (109) receives and stores an identifier for the sensor device (10). The sensor module (101) generates an inference using the sensor data. The sensor device (10) is arranged to switch between sending, over the bidirectional line (11), data sensed by the sensor module (101) and the generated inference. The sensor device (10) is a single-wire sensor device. The input-output interface (105) is a single-wire input-output interface. The sensor module (101) is a motion, electropotential, electroimpedance, chemical, or optical sensor module. The sensor device (10) is provided in a system comprising a master device. The sensor device (10) or system is incorporated into a wearable article.

Abstract: The wearable article 200 comprises a sensing component. The electronics module 100 is removably coupled to the wearable article 200. The electronics module comprises a housing and a processor disposed within the housing 101. An interface element 121, 123 interfaces with the sensing component so as to receive signals from the sensing component and provide the same to the processor. A sensor 105 is disposed within the housing 101. The sensor 105 monitors a property of the environment external to the electronics module 100 through the housing 101. The housing 101 is constructed such that the sensor 105 has line of sight through the housing 101.

Abstract: The wearable article comprises a sensing component. The electronics module (100) comprises an (interface 109) arranged to couple with the sensing component to receive signals. A processor (101) of the module (100) is configured to process the signals. The signals relate to the activity of a user wearing the wearable article. The processor (101) is configured to process the signals to determine whether the activity of the user is within a predetermined allowable range. A light source (103) of the module (100) is configured to emit light based on the determination by the processor (101). The emitted light indicates whether the activity of the user is within the predetermined allowable range. The electronics module (100) also comprises a housing. The processor (101) and light source (103) are provided in the housing. The housing is constructed such that light emitted by the light source (103) is visible from the outside surface of the housing.

Abstract: The sensor semiconductor package (100) comprises a die pad (101), external connection terminals (103), semiconductor chip 105 and sealing member. The semiconductor chip (105) is located on a top surface of the die pad (101) and is electrically connected with the external connection terminals (103) and the die pad (101). The sealing member covers the die pad (101), the external connection terminals (103) and the semiconductor chip (105) and exposes an outer terminal (115) of each of the external connection terminals (103) and an outer contact surface (117) of the die pad (101). The outer contact surface (117) of the die pad (101) forms an electrode (117) of the sensor semiconductor package (100). The article comprises the sensor semiconductor package (100). The method manufactures the sensor semiconductor package (100) and the article.

Abstract: Embodiments disclosed herein provide systems, methods, and computer readable media for synchronizing a media codec between network elements of a media communication session. In a particular embodiment, a method provides designating a first network element to be a static-clock network element during the media communication session and designating at least a second network element to be a dynamic-clock network element during the media communication session. The method further provides determining that a difference in clock speed exists between a second clock speed for the media codec at the second network element and a first clock speed for the media codec at the first network element. Also, the method provides adjusting the second clock speed to account for the difference in clock speed.

Abstract: Analyte survey systems (100) and related techniques are provided to improve the operation of handheld or unmanned mobile sensor or survey platforms. An analyte survey system includes a logic device (112) configured to communicate with a communication module (164) and a sensor assembly (166) of a modular sensor core (160), where the communication module is configured to establish a wireless communication link with a base station (130) associated with the modular sensor core and/or a mobile sensor platform (110) and the sensor assembly is configured to provide analyte sensor data as the modular sensor core is maneuvered within a survey area.

Abstract: A method can include obtaining user interaction data by monitoring a set of user interactions between a user and one or more data elements of a data table. The method can further include determining a set of data element scores based, at least in part, on the user interaction data. The method can further include generating a customized data visualization based, at least in part, on the set of data element scores and the data elements of the data table.

Abstract: A computing system is configured to: after receipt of a request to initiate synchronous playback of media content on a plurality of playback devices via a communication interface, obtain the media content from a media source; generate playback timing information; transmit the media content and the playback timing information to the plurality of playback devices for playback in synchrony; while the plurality of playback devices play back the media content in synchrony and after receipt of respective playback rate information from at least one of the plurality of playback devices indicative of a rate of playback of the at least one playback device, (i) determine a modified sample rate of the media content for the at least one playback device based on the respective playback rate information; and (ii) cause the at least one playback device to play back the media content at the modified sample rate to maintain synchrony.

Abstract: Light emitting devices attached to an item of clothing are illuminated. The light emitting devices are attached to a loom that is terminated by an interface circuit that includes a data storage device (102). Configuration data (1703) is written to the data storage device and the loom is located within an item of clothing. A control unit (1502) is connected to the interface circuit and is configured to supply power and control data to the light emitting devices. Configuration data (1805) from the data storage device is transferred to the control unit, such that the control unit supplies control data to light emitting devices in a form determined by this configuration data.

Abstract: A method can include obtaining user interaction data by monitoring a set of user interactions between a user and one or more data elements of a data table. The method can further include determining a set of data element scores based, at least in part, on the user interaction data. The method can further include generating a customized data visualization based, at least in part, on the set of data element scores and the data elements of the data table.

Abstract: Described are sensors and methods of detecting hydrogen gas. The sensor includes a polymer matrix and a dye molecule in an amount sufficient such that exposure of the polymer matrix to hydrogen gas causes a change in a spectroscopic property of the dye molecule wherein the spectroscopic property includes at least one of color, absorbance, or luminescence. The polymer matrix may further include a catalyst, such as a transition metal, sulfonated Wilkinson's catalyst, colloidal Pt, sulfonated iridium cyclooctadiene triphenylphosphine, sulfonated rhodium cyclooctadiene triphenylphosphine, sulfonated ruthenium triphenylphosphine, or combinations thereof. Embodiments of the sensor may further include a gas permeable, water impermeable membrane, an outer covering, or combinations thereof.

Abstract: An electrical connector having a detachable interface and a permanent interface is supported by connecting the permanent interface to a circuit-board. A first loom end (303) and a second loom end (305) are connected to the circuit board and an over-moulding (404) is applied to cover the permanent interface, the first loom end and the second loom end. The detachable interface is located through an orifice in an item of clothing (410) and the over-moulding is secured to an internal surface of an item of clothing by a first side flange (404) and a second side flange (405).

Abstract: An apparatus for capturing image data, includes an item of clothing and an image-capturing peripheral device attachable thereto, the item of clothing including electrical conductors connected to a peripheral device connector, the peripheral device including a clothing connector to connect to the peripheral device connector, the image-capturing peripheral device producing still-image data when attached to the item of clothing and generating video data when detached from the item of clothing, the item of clothing including a first power source for supplying power to the image-capturing peripheral device, the image-capturing peripheral device includes a second power source, the image-capturing peripheral device selectively using power from the first power source when operating at a first power level and from the second power source when operating at a second power level, with the second power level higher than the first power level.

Abstract: High-visibility garment for use by operatives working in hazardous environment has base garment and detachable light-reflecting apparatus. Base garment comprises outer shell constructed from florescent material and having internal pocket. Powered control unit with loom socket, is retained within internal pocket. Base garment also includes outer attachment material at positions intended for light-reflective material, with loom hole in outer shell and in outer attachment material. Detachable light-reflecting apparatus has light-reflecting outer material with light-emitting devices extending through device holes. Apparatus has inner attachment material and loom connecting light-emitting devices, in which restrained portion of loom is located between light-reflecting outer material and inner attachment material. Loom also has extended portion that connects to loom plug. Loom plug is inserted within loom socket by passing extended portion through loom hole.

Abstract: A peripheral device (701) is knocked against a control unit (704), whereafter the peripheral device is attached to an item of clothing, such as a jacket. The control unit is connected to a wiring loom in the jacket, to operate attached light-emitting devices. The control unit is located within the jacket to receive environmental data during an operation shift. In response to the knocking step, the control unit energizes a passive transponder attached to the peripheral device and the passive transponder transmits held signature data in response to being energized. The control unit stores the transmitted signature data and the control unit only records environment data that includes stored signature data.