Abstract: Techniques associated with structures for dynamically tuned audio in a media device are described, including a housing, a driver mounted to the housing and configured to produce acoustic energy, a hybrid radiator mounted to the housing and formed at least in part using a material configured to change one or more properties in response to an application of an external stimulus, and a source configured to apply the external stimulus to the hybrid radiator.

Abstract: Techniques associated with a smart media ecosystem using local and remote data sources are described, including creating accounts using a smart media device, receiving predetermined media data from separate device, associating the predetermined media data with at least one of the accounts, receiving sensor data from a sensor array, processing the predetermined media data and the sensor data using a learning algorithm configured to generate media preferences, and storing media preferences in an account profile associated with at least one of the accounts. In some embodiments, a method also includes storing sensor data in association with an account, correlating the sensor data with stored data, which includes local data and remote data, selecting media content using the sensor data and the stored data, and sending a control signal to a media player, the control signal configured to cause the media player to play the media content.

Abstract: Techniques for media device, application, and content management using sensory input determined from a data-capable watch band are described, including receiving input from one or more sensors coupled to a data-capable strapband, processing the input to determine a pattern, referencing a pattern library using the pattern, generating a control signal to a media application, the control signal being determined based on whether the pattern matches another pattern in the pattern library, and selecting a media file configured to be presented, the media file being selected using the control signal.

Abstract: Techniques associated with a combination speaker and light source (“speaker-light device”) responsive to states of an organism based on sensor data are described, including generating chemical sensor data in response to one or more chemicals sensed by one or more chemical sensors in the same or different speaker-light devices. A scent generator may be activated to counter an odor caused by a chemical detected by the chemical sensor(s). The speaker-light device may activate an air mover operative to circulate ambient air over the chemical sensor. The speaker-light device may take an appropriate action in response to detected chemicals that affect states of the organism. Some or all of the actions taken may be taken by other devices in communication with the speaker-light device(s). An action may include generating and presenting a path or route to be taken by a user to an area of safety or reduced chemical concentration.

Abstract: Methods and systems for automatic configuration of wireless speakers are disclosed. A system is described whereby a wireless speaker is configured to use an audio tone to generate a sound wave. The sound wave is received by an audio input/output device, which uses the received sound wave to generate audio information. A processor is configured to use the audio information to determine a distance between the wireless speaker and the audio input/output device, and to configure an audio parameter of the wireless speaker as a function of the distance.

Abstract: Systems and methods are described by which microphones are calibrated. Disclosed are techniques for generating a first output signal from a first input signal at a first microphone, generating a second output signal from a second input signal at a second microphone, forming a first filter as a function of the first output signal and the second output signal, the first filter being configured to substantially model the first microphone, and forming a second filter as a function of the first output signal and the second output signal, the second filter being configured to substantially model the second microphone. The second filter may be used to output a third output signal from the first output signal, and the first filter may be used to output a fourth output signal from the second output signal. The fourth output signal may be substantially similar to the third output signal.

Abstract: Systems and methods are described by which microphones are calibrated. Disclosed are techniques for generating a first output signal from a first input signal at a first microphone, generating a second output signal from a second input signal at a second microphone, forming a first filter as a function of the first output signal and the second output signal, the first filter being configured to substantially model the first microphone, and forming a second filter as a function of the first output signal and the second output signal, the second filter being configured to substantially model the second microphone. The second filter may be used to output a third output signal from the first output signal, and the first filter may be used to output a fourth output signal from the second output signal. A first virtual microphone and a second virtual microphone may be formed using the third output signal and the fourth output signal.

Abstract: Techniques for determining a state of a user using wearable devices are described, including receiving motion-related data from a first sensor and user-related data from a second sensor, determining a state of a user as a function of the motion-related data and the user-related data, and displaying a graphic associated with the state of the user at a graphical user interface. The first sensor and the second sensor may be coupled to a wearable device. The user-related data may include galvanic skin response data. The graphic associated with the state of the user may be displayed at a web browser.

Abstract: Techniques for determining a state of a user using wearable devices are described, including receiving motion-related data from a first sensor and user-related data from a second sensor over a time period, determining a plurality of states of a user over the time period as a function of the motion-related data and the user-related data, determining a trend as a function of the plurality of states of the user, and displaying information associated with the trend at a user interface. The first sensor and the second sensor may be coupled to a wearable device. The user-related data may include galvanic skin response data. The information associated with the trend may be displayed at a web browser.

Abstract: Techniques for component protective overmolding include selectively applying a securing coating substantially over one or more elements coupled to a framework, molding a first protective layer over the framework, the one or more elements, and the securing coating, after the securing coating has been selectively applied, and molding a second protective layer over the first protective layer. In one embodiment, the second protective layer is configured to provide a surface configured to receive a pattern and is removable if a defect is yielded during inspection. Further, the securing coating may be a curable material, such as an ultra violet curable material.

Abstract: A light-based skin contact detector is described, including a boot having an index of refraction less than or equal to another index of refraction associated with skin at a frequency of light, a light emitter and detector coupled to the boot and configured to measure an amount of light energy reflected by an interface of the boot, and a digital signal processor configured to detect a change in the amount of light energy reflected by the interface.

Abstract: Techniques associated with a combination speaker and light source powered using a light socket are described, including a housing comprising a plate coupled to a substantially hemispherical enclosure, a platform configured to couple a light source to a terminal configured to receive a light control signal, the light control signal configured to modify a light characteristic, a speaker coupled to the housing and configured to project audio in a direction, a light socket connector coupled to the housing and configured to provide power to the speaker and the light source when the light socket connector is coupled with a light socket, an acoustic sensor disposed on a surface of the housing, and a light sensor located within the housing, the light sensor facing away from the light source.

Abstract: Various embodiments relate generally to electrical and electronic hardware, computer software, wired and wireless network communications, and wearable computing and audio devices for monitoring health and wellness. More specifically, disclosed are an apparatus and a method for processing signals representing physiological characteristics sensed from tissue at or adjacent an ear of an organism. In one or more embodiments, a wearable device includes a sensor terminal and a physiological sensor coupled to the sensor terminal to sense one or more signals originating at the sensor terminal. The wearable device may also include a radio frequency (“RF”) communications interface. Also, the wearable device can include a processor configured to cause generation of data representing a physiological characteristic of the organism.

Abstract: Techniques associated with a combination speaker and light source powered using a light socket are described, including an acoustically sealed housing, a light socket connector coupled to the housing and configured to provide power to elements within the speaker and light source system when the light socket connector is coupled with a light socket, a light source housed within the housing and configured to be powered using the light socket connector, an optical diffuser on a front end of the housing, a parabolic reflector housed within the housing, the parabolic reflector configured to reflect light from the light source toward the optical diffuser, and a speaker coupled to the housing and configured to output audio.

Abstract: Various embodiments relate generally to electrical and electronic hardware, computer software, wired and wireless network communications, and wearable computing and audio devices for monitoring health and wellness. More specifically, disclosed are an apparatus and a method for processing signals representing physiological characteristics sensed from tissue at or adjacent an ear of an organism. In one or more embodiments, a wearable device includes one or more sensor terminals, one or more physiological sensors configured to sense one or more signals originating at the one or more sensor terminals. At least one sensor terminal includes a pressure-sensitive terminal configured to detect a pressure exerted by a portion of tissue of an organism and generate a pressure signal representing a value of the pressure. Further, the wearable device can include a processor configured to cause generation of data representing a physiological characteristic of the organism based on the pressure signal.

Abstract: Microphone arrays (MAs) are described that position and vent microphones so that performance of a noise suppression system coupled to the microphone array is enhanced. The MA includes at least two physical microphones to receive acoustic signals. The physical microphones make use of a common rear vent (actual or virtual) that samples a common pressure source. The MA includes a physical directional microphone configuration and a virtual directional microphone configuration. By making the input to the rear vents of the microphones (actual or virtual) as similar as possible, the real-world filter to be modeled becomes much simpler to model using an adaptive filter.

Abstract: Embodiments of the relate generally to electrical and electronic hardware, computer software, wired and wireless network communications, and wearable computing devices for facilitating health and wellness-related information. More specifically, disclosed are systems, methods, devices, computer readable medium, and apparatuses configured to determine activity and activity types, including gestures, from sensed motion signals using, for example, a wearable device (or carried device) and one or more motion sensors. In one embodiment, an apparatus can include a wearable housing and a motion sensor. The apparatus can also include a signal preprocessor, which may include a sample rate controller configured to modify a sample rate of a motion sensor signal to form an adjusted sample rate with which to sample the motion sensor signal. Further, the apparatus can include an intermediate motion signal generator and an activity processor configured to identify an activity based on the intermediate motion signals.

Abstract: Embodiments of the invention relate generally to electrical and electronic hardware, computer software, wired and wireless network communications, and wearable computing devices for facilitating health and wellness-related information. More specifically, disclosed are systems, methods, devices, computer readable medium, and apparatuses configured to determine activity and activity types, including gestures, from sensed motion signals using, for example, a wearable device (or carried device) and one or more motion sensors. In at least one embodiment, a method includes receiving data representing a motion sensor signal and determining whether the wearable device is in a still state. The method also can include calibrating the motion sensor signal in-situ to form a calibrated motion signal, generating intermediate motion signals based on the calibrated motion sensor signal, and identifying an activity based on the intermediate motion signals.

Abstract: Techniques associated with a social data-aware wearable display system are described, including a frame configured to be worn, a display coupled to the frame, the display configured to provide an image in a field of vision, a sensor configured to capture sensor data, a secondary sensor configured to capture environmental data, a sensor analytics module configured to process the sensor data and the environmental data to generate sensor analytics data, and a communication facility configured to send sensor analytics data to another device and to receive remote data. Some embodiments also include an adaptive optics module configured to determine an optical distortion to be applied to the image.

Abstract: Techniques associated with a combination speaker and light source (“speaker-light device”) responsive to states of an organism based on sensor data are described, including generating motion sensor data in response to a movement captured using a motion sensor, deriving movement data using a motion analysis module configured to determine the movement to be associated with one or more of a gesture, an identity, and an activity, using the motion sensor data, generating acoustic sensor data in response to sound captured using an acoustic sensor, deriving audio data using a noise removal module configured to subtract a noise signal from the acoustic sensor data, detecting a radio frequency signal using a communication facility, the radio frequency being associated with a personal device, obtaining state data from the personal device, and determining a desired light characteristic using the state data and one or both of the movement data and the audio data.