Abstract: Techniques for data-capable band management in association with, for example, an autonomous advisory application and network communication data environment are described. In some examples, a method can detect a signal configured to initiate a synchronization function being transmitted from a wearable computing device to an application, as an example. In some cases, a method can include performing a synchronization function to, for example, transfer data from the wearable computing device to the application. Further, a method can include causing presentation to an interface on a computing device to display information associated with a wearable computing device, as determined by the data transferred to the application, for example, after a synchronization function is performed and/or a type of motion is synchronized.

Abstract: Embodiments relate generally to wearable electrical and electronic hardware, computer software, wired and wireless network communications, and to wearable/mobile computing devices. More specifically, various embodiments are directed to, for example, a flexible substrate. In one example, a wearable device may include a framework configured to be worn or attached, and a flexible substrate coupled to the framework. The flexible substrate may include a first end and a second end, and may include one or more conductive layer structures and a conductive laminate structure. The flexible substrate may include rigid regions configured to receive one or more components including a sensor, an electrode, and/or a logic circuit (e.g., bioimpedance logic circuit).

Abstract: An apparatus is described that includes an audio power amplifier having an input and an output. An alternating-current to direct-current power converter is coupled to the audio power amplifier in a single package to supply power to the audio power amplifier.

Abstract: Embodiments relate generally to electrical and electronic hardware, computer software, human-computing interfaces, wired and wireless network communications, data processing, computing devices, watches, watch bands, and wrist-worn watch-enabled devices. More specifically, techniques for adopting electronic devices using data from a wearable device, such as a data-capable watch band are described. In some examples, a wearable device can include an adoption controller configured to detect the short-range communication link. Further, the wearable device can be configured to transmit key data to an electronic device to transition the electronic device from a lender mode of operation to a lendee mode of operation to enable the wearer to use the electronic device.

Abstract: Embodiments of the present application relate generally to electronic hardware, computer software, wireless communications, network communications, wearable, hand held, and portable computing devices for facilitating communication of information. A wearable personal emergency event transponder includes a processor, data storage, a sensor system, and a communications interface. The transponder processes signals from the sensor system using algorithms included in the data storage and determines if an event related to a medical emergency has occurred to a user wearing the transponder. Upon detecting one or more events, the transponder may selectively communicate one or more datum from the data storage including user specific emergency medical data, user contact data, system data, or some combination of those data. The communication may be by a radio configured to transmit the datum at a low RF power sufficient for near field communication with an external device and/or by a hardwired communications link (e.g.

Abstract: Systems and methods are described for clamping a headset in a calibration system using a clamp system that includes a clamp, platform, and one or more spindles (e.g., cushion spindles) to minimize or eliminate issues associated with positioning of headsets. The clamp system comprises a mount having a receptacle. When a device is introduced to the mount the receptacle receives at least a portion of a device. The clamp system includes a clamp attached to the mount and having a first arm rotateably coupled to a second arm that controls the first arm between an open position and a closed position. A platform and at least one spindle are connected to the first arm. When the device is present in the receptacle and the first arm is in the closed position the spindle contacts the device and seats or secures the device in the receptacle.

Abstract: Embodiments of the present application relate generally to personal electronics, portable electronics, wearable electronics, and more specifically to a structure and method for a protective covering for a wearable device. Interior and exterior structures of the wearable device are configured to be flexed into a configuration and to retain the configuration after the flexing. Interior structure may include a first flexible substrate having a first relaxation structure and a second flexible substrate having a second relaxation structure. Components or other structures may be connected with the first and/or second flexible substrates. The first and second relaxation structures may be positioned relative to each other to define a flexure point. At least one flexible and electrically non-conductive cover, that may undergo shirking, may conformally cover at least a portion of the interior structure. A flexible overmolding may be formed over the cover and may comprise the exterior structure.

Abstract: Embodiments of the invention relate generally to electrical and electronic hardware, computer aided simulation and design, high-level language numerical computation, analysis, programming, and visualization of designs, target hardware compilers, assembly code, executable firmware, computer software, wired and wireless network communications, wearable, hand held, and portable computing devices for facilitating communication of information. More specifically, disclosed is a framework for computer aided simulation and design of wireless media devices for one or more target hardware platforms.

Abstract: Techniques for data-capable band management in an integrated application and network communication data environment are described, including receiving input from one or more sensors coupled to a wearable computing device, receiving a parameter used to determine when a synchronization between the wearable computing device and a device in data communication with the wearable computing device is to be performed, processing the input to determine if the parameter is satisfied, performing the synchronization between the wearable computing device and the device if the parameter is satisfied, and presenting an interface on the device, the interface being configured to display information associated with the synchronization.

Abstract: Embodiments relate generally to wearable electrical and electronic hardware, computer software, wired and wireless network communications, and to wearable/mobile computing devices configured to process audio, in view of noise, and communicate audio. More specifically, disclosed are wearable devices, platforms and methods directed to, for example, provide wearable communication devices, such as a headset. In various embodiments, a wearable communication device includes an array of microphone, an audio processor coupled to the array of microphones, and a vibration detector including, for example, a skin surface microphone (“SSM”).

Abstract: Embodiments of the invention relate generally to electrical and electronic hardware, computer aided simulation and design, high-level language numerical computation, analysis, programming, and visualization of designs, target hardware compilers, assembly code, executable firmware, acoustic, mechanical, and electrical sensors, computer software, wired and wireless network communications, wearable, hand held, and portable computing devices for facilitating communication of information. More specifically, disclosed is a framework for computer aided simulation and design of sensor systems for wireless media devices for one or more target hardware platforms.

Abstract: Embodiments relate generally to wearable electrical and electronic hardware, computer software, wired and wireless network communications, and to wearable/mobile computing devices configured to process audio, in view of noise, and communicate audio. More specifically, disclosed are wearable devices, platforms and methods directed to, for example, provide wearable communication devices, such as a headset. In various embodiments, a wearable communication device includes an array of microphone, an audio processor coupled to the array of microphones, and a vibration detector including, for example, a skin surface microphone (“SSM”).

Abstract: Embodiments relate generally to wearable electrical and electronic hardware, computer software, wired and wireless network communications, and to wearable/mobile computing devices configured to process audio, in view of noise, and communicate audio. More specifically, disclosed are wearable devices, platforms and methods directed to, for example, provide wearable communication devices, such as a headset. In various embodiments, a wearable communication device includes an array of microphone, an audio processor coupled to the array of microphones, and a vibration detector including, for example, a skin surface microphone (“SSM”).