Abstract: Headphones include a pair of cups, each housing a speaker to be positioned over an ear of a user, a processor, a cooling mechanism disposed within each of the cups to regulate environmental conditions inside of the cups to match environmental thresholds provided by a virtual reality device displaying a virtual reality environment to the user, a temperature sensor and at least one additional environmental sensor disposed within each of the cups to monitor the environmental conditions inside the cups, the processor to subsequently analyze data associated with the sensors and compare the data to the environmental thresholds and the processor to selectively activate the cooling mechanism based on the comparison.

Abstract: In one example of the disclosure, a communication apparatus includes a first microphone. The communication apparatus is to be wirelessly and contemporaneously connected to a set of microphones including the first microphone. The communication apparatus is to receive microphone data from each microphone of the set of microphones, wherein the microphone data is indicative of a user spoken phrase captured by the set of microphones. The communication apparatus is to establish based on the received microphone data a selected microphone from among the set of microphones.

Abstract: Headphones includes a pair of cups, each housing a speaker to be positioned over an ear of a user, a microphone, a processor, an actuator to move a member of at least one of the cups to uncover at least a portion of the ear of the user to expose the user to ambient sound, a user control to active a training mode of the headphones in which the processor operates the microphone to record relevant sounds occurring when the training mode is activated, the processor to subsequently analyze ambient sounds external to the headphones that are received by the microphone and compare those ambient sounds to the recorded relevant sounds and the processor to selectively activate the actuator to uncover at least a portion of the ear of the user to expose the user to ambient sound in response to determining that the ambient sounds match the relevant sounds.

Abstract: A wide range, non-focused listening mode of a microphone of an electronic device can be set to be selectively less than a maximal range around the device. The microphone can be operated in the wide range, non-focused listening mode to detect a spoken trigger phrase. The microphone can then be operated in a narrow range, focused listening mode directed towards a location from which the spoken trigger phrase was detected in the wide range, non-focused listening mode.

Abstract: In an example implementation, a self-cooling headset includes an ear cup to form an ear enclosure when placed over a user's ear, a first valve to open and release air from the ear enclosure, and a second valve to open and admit air into the ear enclosure. The headset also includes a first speaker cone to translate an audio frequency signal into audible sound, and a second speaker cone to translate a subsonic frequency signal into air movement that produces positive and negative air pressures within the ear enclosure to open and close the first and second valves.

Abstract: In one example of the disclosure, microphone data indicative of a user spoken phrase is captured utilizing the microphone at a communication apparatus. At least a portion of the microphone data is sent to a set of computing devices. A response phrase determined at a virtual assistant service is received from each of the computing devices. A preferred response phrase is identified among the set of received response phrases according to a preference rule. The preferred response phrase is caused to be output via a speaker at the communication apparatus.

Abstract: In an example implementation, a self-cooling headset includes an ear cup to form an ear enclosure when placed over a user's ear. A first valve is to open and release air from the ear enclosure, and a second valve is to open and admit air into the ear enclosure. A speaker cone is to translate an audio signal into audible sound, and a signal modifier is to modify the audio signal with a subsonic frequency signal to cause the speaker cone to generate air movement that produces sufficient positive pressure to open the first valve and sufficient negative pressure to open the second valve.

Abstract: A system is disclosed in which an eye-tracking sensor signal is received and a moving image is generated to be rendered on one or more displays based on the eye-tracking sensor signal. Responsive to an input control signal from a user-operable control device or based on a determination that the user's gaze direction is tracking the moving image, the system adjusts the moving image.

Abstract: In an example implementation, a self-cooling headset includes an ear cup to form an ear enclosure when placed over a user's ear. A first check valve on the ear cup is to open and release a volume of air from the ear enclosure when a positive pressure within the ear enclosure overcomes a cracking pressure of the first check valve. A second check valve on the ear cup is to open and admit a volume of air into the ear enclosure when a partial vacuum within the ear enclosure causes an external pressure to overcome a cracking pressure of the second check valve.

Abstract: In one example of the disclosure, volume level information is obtained for each of a set of connected communication devices that include a microphone and a speaker. The obtained volume level information is analyzed to determine the volume level information is indicative of a spoken trigger phrase. A preferred communication device among the set of communication devices is identified according to an audio preference rule.

Abstract: A wide range, non-focused listening mode of a microphone of an electronic device can be set to be selectively less than a maximal range around the device. The microphone can be operated in the wide range, non-focused listening mode to detect a spoken trigger phrase. The microphone can then be operated in a narrow range, focused listening mode directed towards a location from which the spoken trigger phrase was detected in the wide range, non-focused listening mode.

Abstract: A first device in accordance with an example is placed in a predefined mode in response to removing a near field communication (NFC) tag from an NFC component of the first device. A request is received from a second device to establish a connection with the first device based on data stored on the NFC tag. The first device establishes the connection with the second device and executes the predefined mode.

Abstract: A first device in accordance with an example is placed in a predefined mode in response to removing a near field communication (NFC) tag from an NFC component of the first device. A request is received from a second device to establish a connection with the first device based on data stored on the NFC tag. The first device establishes the connection with the second device and executes the predefined mode.

Abstract: A first device in accordance with an example is placed in a predefined mode in response to removing a near field communication (NFC) tag from an NFC component of the first device. A request is received from a second device to establish a connection with the first device based on data stored on the NFC tag. The first device establishes the connection with the second device and executes the predefined mode.

Abstract: A first device in accordance with an example is placed in a predefined mode in response to removing a near field communication (NFC) tag from an NFC component of the first device. A request is received from a second device to establish a connection with the first device based on data stored on the NFC tag. The first device establishes the connection with the second device and executes the predefined mode.

Abstract: Examples disclose a method of transmitting audio data to a wireless device and receiving frequency coefficients associated with the audio data from the device. Further, examples disclose analyzing the frequency coefficients to identify a change between the transmitted audio data and the received frequency coefficients. Additionally, examples also disclose adjusting a second audio data based on the identified change.

Abstract: Examples disclose a method of transmitting audio data to a wireless device and receiving frequency coefficients associated with the audio data from the device. Further, examples disclose analyzing the frequency coefficients to identify a change between the transmitted audio data and the received frequency coefficients. Additionally, examples also disclose adjusting a second audio data based on the identified change.

Abstract: The apparatus discloses a first connector; a wireless interface, coupled to pass wireless signals through the first connector; and a second connector, coupled to pass hardwire signals through the first connector; wherein the apparatus is powered through, either the first connecter or the second connector.

Abstract: An embodiment of a headset has first and second audio output devices, an audio input device, a boom for positioning the audio input device movable to first and second locations, and a switch assembly responsive to movement of the boom. When the boom is located at the first location, the switch assembly is configured to couple the first audio output device to receive a first signal and the second audio output device to receive a second signal. When the boom is located at the second location, the switch assembly is configured to couple the first audio output device to receive the second signal and the second audio output device to receive the first signal.

Abstract: The data storage cartridge drive is designed to securely accommodate and align more than one size cartridge. Reference surfaces are provided for cartridge to drive alignment in a manner so as to enhance stability, particularly during periods when the drive may experience shock or vibration. An additional reference surface is provided to supply added resistance to shock and vibration.