Abstract: Embodiments include a wearable device, such as a head-worn device. The wearable device includes a first microphone to receive a first sound signal from a wearer of the wearable device; a second microphone to receive a second sound signal from the wearer of the wearable device; and a processor to process the first sound signals and the second sound signals to determine that the first and second sound signals originate from the wearer of the wearable device.

Abstract: Processing techniques and device configurations for performing and controlling output effects at a plurality of wearable devices are generally described herein. In an example, a processing technique may include receiving, at a computing device, an indication of a triggering gesture that occurs at a first wearable device, determining an output effect corresponding to the indication of the triggering gesture, and in response to determining the output effect, transmitting commands to computing devices that are respectively associated with a plurality of wearable devices, the commands causing the plurality of wearable devices to generate the output effect at the plurality of wearable devices. In further examples, output effects such as haptic feedback, light output, or sound output, may be performed by the plurality of wearable devices, associated computing devices, or other controllable equipment.

Abstract: A wearable sensor system is disclosed that provides a measurable magnetic field that changes horizontally within the range of motion of human limbs. The wearable sensor system includes a magnetic sensing device, and one or more magnet devices that provide the measurable magnetic field with a strength exceeding the Earth's magnetic field. To this end, the magnetic sensing system provides a “personal” magnetic field about a user, with that magnetic field traveling with the user and overpowering adjacent interfering fields. The wearable sensor system may include a sensor arrangement that measures a strength of the personal magnetic field and field direction to perform horizontal localization, and may send a representation of a same to a remote computing device to cause an action to occur. Some such actions include output of pre-recorded or synthesized musical notes, for example.

Abstract: Systems and methods may provide for monitoring an input audio signal from an onboard microphone of a mobile device while a host processor of the mobile device is in a standby mode. Additionally, a predetermined audio pattern may be identified in the input audio signal and a device location session may be triggered with respect to the mobile device based on the predetermined audio pattern. In one example, an output audio signal is generated during the device location session.

Abstract: Systems and methods may provide for determining a sound vibration condition of an ambient environment of a wearable device and determining a motion condition of the wearable device. In addition, one or more automated voice operations may be performed based at least in part on the sound vibration condition and the motion condition. In one example, two or more signals corresponding to the sound vibration condition and the motion condition may be combined.

Abstract: Systems and methods may provide for monitoring an input audio signal from an onboard microphone of a mobile device while a host processor of the mobile device is in a standby mode. Additionally, a predetermined audio pattern may be identified in the input audio signal and a device location session may be triggered with respect to the mobile device based on the predetermined audio pattern. In one example, an output audio signal is generated during the device location session.

Abstract: In one example a controller comprises logic, at least partially including hardware logic, configured to detect speech activity in an audio signal received in a non-aerial microphone and in response to the voice activity, to apply a noise cancellation algorithm to a speech input received in a aerial microphone. Other examples may be described.

Abstract: In one example a controller comprises logic, at least partially including hardware logic, configured to detect a key phrase in a received audio signal, and in response to the key phrase, to transmit a signal to a personal assistant in a remote electronic device, determine whether an audio input was received, and in response to a determination that additional audio input was received prior to receiving a response from the personal assistant in the remote electronic device, to buffer the audio input in a memory and forward the audio input to the personal assistant in the remote electronic device. Other examples may be described.

Abstract: Particular embodiments described herein provide for an electronic device that includes a plurality of audio acquisition areas. Each of the plurality of audio acquisition areas can include a microphone element to detect audio data, an audio opening that allows the audio data to travel to the microphone element, and a windscreen that covers at least the audio opening. An audio module can be configured to receive the audio data from each of the plurality of audio acquisition areas and enhance the audio data.

Abstract: A wearable device for binaural audio is described. The wearable device includes a feedback mechanism, a microphone, an always on binaural recorder (AOBR), and a processor. The AOBR is to capture ambient noise via the microphone and interpret the ambient noise. An alert is issued by the processor to the feedback mechanism based on a notification detected via the microphone in the ambient noise.

Abstract: Apparatus, computer-readable storage medium, and method associated with speech recognition are described. In embodiments, a mobile phone may include a processor; and a speech recognition module coupled with the processor. The voice recognition module may be configured to recognize one or more voice commands and may include first echo cancellation logic and second echo cancellation logic to be selectively employed during recognition of voice commands. Employment of the first and second echo cancellation logic respectively may cause the mobile phone to variably consume a first and second amount of energy, with the second amount of energy being less than the first amount energy.

Abstract: Wearable electronic device technology is disclosed. In an example, a wearable electronic device can include a handling portion that facilitates donning the wearable electronic device on a user. The wearable electronic device can also include a user authentication sensor associated with the handling portion and configured to sense a biometric characteristic of the user while the user is donning the wearable electronic device. In addition, the wearable electronic device can include a security module to determine whether the sensed biometric characteristic indicates an authorized user of the wearable electronic device.

Abstract: This application discusses among other things apparatus and methods for optimizing speech recognition at a far-end device. In an example, a method can include establishing a link with a far-end communication device using a near-end communication device, identifying a context of the far end communication device, and selecting one audio processing mode of a plurality of audio processing modes at the near-end communication device, the one audio processing mode associated with the identified context of the far-end device, and configured to reduce reception error by the far-end communication device of audio transmitted from the near-end communication device.

Abstract: Various embodiments are generally directed to an apparatus, method and other techniques for detecting, by one or more sensor components, at least one sensor input, and executing, by logic, at least one instruction to cause an event on a wearable wireless device, the event comprising at least one of a change in a physical parameter on the wearable wireless device and a wireless communication with a computing device via a transceiver.

Abstract: In one example a controller comprises logic, at least partially including hardware logic, configured to detect a key phrase in a received audio signal, and in response to the key phrase, to transmit a signal to a personal assistant in a remote electronic device, determine whether an audio input was received, and in response to a determination that additional audio input was received prior to receiving a response from the personal assistant in the remote electronic device, to buffer the audio input in a memory and forward the audio input to the personal assistant in the remote electronic device. Other examples may be described.

Abstract: Systems and methods may provide for determining a sound vibration condition of an ambient environment of a wearable device and determining a motion condition of the wearable device. In addition, one or more automated voice operations may be performed based at least in part on the sound vibration condition and the motion condition. In one example, two or more signals corresponding to the sound vibration condition and the motion condition may be combined.

Abstract: Systems and methods may provide for monitoring an input audio signal from an onboard microphone of a mobile device while a host processor of the mobile device is in a standby mode. Additionally, a predetermined audio pattern may be identified in the input audio signal and a device location session may be triggered with respect to the mobile device based on the predetermined audio pattern. In one example, an output audio signal is generated during the device location session.

Abstract: Apparatus, computer-readable storage medium, and method associated with speech recognition are described. In embodiments, a mobile phone may include a processor; and a speech recognition module coupled with the processor. The voice recognition module may be configured to recognize one or more voice commands and may include first echo cancellation logic and second echo cancellation logic to be selectively employed during recognition of voice commands. Employment of the first and second echo cancellation logic respectively may cause the mobile phone to variably consume a first and second amount of energy, with the second amount of energy being less than the first amount energy.

Abstract: The present invention provides a process for the preparation of semi-conducting polymer film containing beta crystalline phase of polyvinylidene fluoride with application in piezoelectric devices viz. electro-mechanical sensors, tactile sensors for robotics, touch sensitive switches and the like, and which can be easily made at low temperatures and at low electric fields and having low resistivity/semi-conducting range.

Abstract: The present invention provides a process for preparation of conducting/semi-conducting polymer having high piezosensitivity, which have large number of application in electromechanical sensors, tactile sensors for robotics, touch sensitive screens and the like. The present invention provides a process for preparation of conducting/semi-conducting polymer which has very high piezosensitivity and which can be easily made at low temperature and used at low electric fields.