Abstract: Embodiments relate generally to electrical and electronic hardware, computer software, wired and wireless network communications, and computing devices, and, in particular, to a wearable device implementing a touch-sensitive interface in a metal pod cover and/or bioimpedance sensing to determine physiological characteristics, such as heart rate. According to an embodiment, a wearable device includes a selectably opaque surface configured to emit arrangements of light to form a display, and a touch-sensitive I/O control circuit coupled to the selectably opaque surface to detect a capacitance value as an input signal to modify the display. Also, the wearable device can include one or more straps coupled to a wearable pod, at least one of the one or more straps including electrodes for sensing a physiological characteristic. A display controller can be configured to display a representation as a function of a value of the physiological characteristic via the selectably opaque surface.

Abstract: Device-based activity classification using predictive feature analysis is described, including evaluating an indicator associated with a predictive feature, identifying an application, using the name, to be performed, and invoking the application, the application being configured to interpret the indicator to determine an operation to perform at one or more levels of a protocol stack using data generated from evaluating a signal detected by a sensor, the sensor being coupled to a wearable device, and the application being configured to perform the operation using other data generated from evaluating another signal detected by another sensor, the another sensor being substantially different than the sensor.

Abstract: Embodiments relate generally to electrical/electronic hardware, computer software, wired and wireless network communications, portable, wearable, and stationary media devices. RF transceivers and/or audio system in each media device may be used to wirelessly communicate between media devices and allow configuration and other data to be wirelessly transmitted from one media device to another media device. The proximity detection system may be configured to detect a presence of a user or multiple users and upon detecting presence, access content on a user device, and record the content while also playing back the content on the media device. One or more user devices in proximity of the media device post detection may wirelessly communicate with the media device and the media device may orchestrate handling of content from those devices or from a wirelessly accessible location such as the Cloud or Internet.

Abstract: Embodiments relate generally to electrical and electronic hardware, computer software, wired and wireless network communications, and computing devices. More specifically, an insight micro-engine is configured to present insights relating a detected activity. According to an embodiment, a method includes detecting at a wearable computing device an absence of a communication link and activating an insight micro-engine configured to operate responsive to the absence of the communication link. Further, the method can include receiving a subset of sensor data from a first subset of sensors implemented in the wearable computing device, determining an activity based on a subset of triggers, determining an aggregate value representative of a state of the activity, correlating the aggregate value to a target value, and deriving data representing an insight that associates the aggregate value with a parameter.

Abstract: Techniques associated with a wearable device structure with enhanced motion detection by a motion sensor are described, including a band configured to be worn, a nodule coupled to the band, the nodule including a structure configured to enhance detection of movement of an adjacent skin surface, the structure having an articulator configured to rotate in a plurality of planes, and a sensor coupled to the structure and configured to detect rotational motion.

Abstract: Techniques for component protective overmolding using protective external coatings include a device having a framework configured to be worn, a button assembly coupled to the framework, the button assembly configured to send a signal to a circuit, the button assembly including a button configured to be depressed to displace a button shaft, a button inner housing coupled to the button and the button shaft, and a button outer housing coupled to the button inner housing, a first ring configured to form a first seal disposed substantially between the button inner housing and the button shaft, a second ring configured to form a second seal disposed substantially between the button inner housing and the button outer housing, and an outer molding formed over a portion of the button assembly.

Abstract: A housing (e.g., a wearable structure) includes one or more sensors operative to capture sensor data and a plug operative to electrically communicate data (e.g., the sensor data) to another device via a hard wired connection. A wirelessly enabled cap may be removably coupled with the housing and may include: a cavity operative to house the plug; a RF chip disposed within the housing; and one or more antennas electrically coupled with the chip. The chip is operative to wirelessly communicate data (e.g., the sensor data) in accordance with one or more wireless communication protocols (e.g., short-range, long-range, near field). The one or more antennas may form an exterior portion(s) of the housing and/or may be embedded in a portion(s) of the housing. The chip may be passive powered from an external RF source (e.g., an externally generated RF signal electrically coupled with the chip through one or more antennas).

Abstract: Embodiments relate generally to electrical/electronic hardware, computer software, wired and wireless network communications, portable, wearable, and stationary media devices. Media devices may include a plurality of RF transceivers, an audio system, and a proximity detection system. The RF transceivers and/or audio system may be used to wirelessly communicate between media devices and allow configuration and other data to be wirelessly transmitted from one media device to another media device. The proximity detection system may be configured to detect a presence of a user or multiple users and upon detecting presence, take some action defined by a user preference and/or environmental conditions around the media device. One or more user devices in proximity of the media device post detection may wirelessly communicate with the media device and the media device may orchestrate handling of content from those devices or from a wirelessly accessible location such as the Cloud or Internet.

Abstract: The various embodiments relate generally to systems, devices, apparatuses, and methods for providing audio streams to multiple listeners, and more specifically, to a system, a device, and a method for providing independent listener-specific audio streams to multiple listeners using a common audio source, such as a set of loudspeakers, and, optionally, a shared audio stream. In some embodiments, a method includes identifying a first audio stream for reception at a first region to be canceled at a second region, and generating a cancellation signal that is projected in another audio stream destined for the second region. The cancellation signal and the first audio steam are combined at the second region. Further, a compensation signal to reduce the cancellation signal at the first region can be generated.

Abstract: Techniques for generating summaries and action items associated with speech are described. Disclosed are techniques for presenting a first audio signal including a portion of a first audio stream at a loudspeaker, identifying data representing an audiolink associated with the first audio stream, and determining data representing a cue and data representing a second audio stream associated with the audiolink. A second audio signal including the cue may be presented, and a third audio signal including a portion of the second audio stream may be presented at the loudspeaker.

Abstract: A method and apparatus are described for regenerating a local clock within a wireless module and synchronizing the local clock with a wireless host clock. For one embodiment, the wireless module generates a local clock, counts the cycles of the clock during a common timing reference period maintained wirelessly between the wireless module and the host, receives a count of the host clock during the same common timing reference period, and adjusts the local clock signal based upon a comparison of the two counts. For one embodiment, the wireless module further receives timing references from the host and, in addition, receives packets of audio samples from the host accompanied by a timestamp, the timestamp based upon the host timing reference, and outputs the audio sample at the time designated by the timestamp.

Abstract: Embodiments relate generally to a wearable device implementing a touch-sensitive interface in a metal pod cover and/or bioimpedance sensing to determine physiological characteristics, such as heart rate. According to an embodiment, a method includes receiving an amplified signal including a portion of the physiological-related signal component including data representing a physiological characteristic, the amplified signal being derived from bioimpedance signal based on an impedance value of a tissue, and identifying a magnitude of a portion of the physiological-related signal component. Also, the method can compare the magnitude of the portion against another magnitude of a data model (e.g., in a time-domain) to form a matched value.

Abstract: Techniques associated with intelligent device connection for wireless media in an ad hoc acoustic network are described, including receiving a radio signal at an intelligent device connection unit implemented in a media device, determining a source of the radio signal to be outside of an acoustic network being associated with the media device, generating a location data associated with a location of the source, receiving an acoustic signal from the source, evaluating the acoustic signal and metadata associated with the acoustic signal to determine additional location data, updating the location data, generating acoustic network data using the location data, the acoustic network data associating the source with the acoustic network, and sending setup data to the source.

Abstract: Techniques associated with intelligent device connection for wireless media in an ad hoc acoustic network are described, including receiving a radio signal from an outside media device, determining whether the radio signal includes identifying information, evaluating the radio signal to calculate location data associated with a location of the outside media device, determining whether the location of the outside media device is within a threshold proximity of a primary media device, sending request to the outside media device, the request comprising an instruction to the outside media device to provide an acoustic output, receiving response data from the outside media device, capturing an acoustic signal using an acoustic sensor, determining the acoustic signal to be associated with the acoustic output from the outside media device, and generating acoustic network data using the acoustic signal, the acoustic network data identifying the outside media device as being part of the acoustic network.

Abstract: Techniques for generating summaries and action items associated with speech are described. Disclosed are techniques for receiving data representing an audio signal including speech, determining one or more words associated with the speech, determining one or more vocal fingerprints associated with the speech, and identifying a keyword associated with the speech using the one or more words and the one or more vocal fingerprints. Presentation of the keyword may be made at a loudspeaker, a display, another user interface, and the like. A summary, including meta-data and a content summary, may be generated from one or more keywords, and the summary may be presented to a user.

Abstract: Embodiments of the invention relate generally to electrical and electronic hardware, computer software, wired and wireless network communications, and computing devices. More specifically, the embodiments related to structures and techniques for implementing multiple logical representations of audio functions in a wireless audio transmitter, such as a USB dongle configured to transmit and to receive audio data wirelessly via, for example, a Bluetooth link. In one embodiment, a wireless USB audio transceiver can include a multiple mode transmitter configured transmit wireless signals at multiple data rates. Further, the wireless USB audio transceiver can include a first data path modeled as a first audio function, and a second data path modeled as a second audio function. Also, included is a signal detector configured to determine the presence of the audio data on a data path for modifying transmission data rates as a function of the presence of the audio data.