A deformable controller for an electronic device, such as a portable electronic device, is disclosed. A user can interact with the controller to cause it to deform and thereby provide user input to control the electronic device. The controller can be malleable and symmetrical, and user interaction with the controller can be provided with substantially arbitrary orientation. In one embodiment, the controller is an in-line controller with a cable that couples to the electronic device. In one particular implementation, the portable electronic device can be a portable media player and the controller can remotely control media playback functions for the portable media player.

Reference gain values Ga1, Gb1 and Gc1 are set for respective EQ points A, B and C of a plurality of frequency bands in EQ CURVE 1 currently set in an EQ module. In response to an operation of an operator, an intensity parameter value, which is a multiplier for the reference gain values Ga1, Gb1 and Gc1, is changed, so that the reference gain values Ga1, Gb1 and Gc1 are changed in a collective fashion. In EQ CURVE 2 having been changed from EQ CURVE 1, the intensity parameter value exceeds 1 (100%) and actual gain values of the EQ points A, B and C of the frequency bands are Ga2, Gb2 and Gc2, so that EQ CURVE 2 assumes emphasized frequency characteristics.

A deformable controller for an electronic device, such as a portable electronic device, is disclosed. A user can interact with the controller to cause it to deform and thereby provide user input to control the electronic device. The controller can be malleable and symmetrical, and user interaction with the controller can be provided with substantially arbitrary orientation. In one embodiment, the controller is an in-line controller with a cable that couples to the electronic device. In one particular implementation, the portable electronic device can be a portable media player and the controller can remotely control media playback functions for the portable media player.

Wireless-enabled loudspeaker includes a capacitive touch user interface. The loudspeaker may comprise at least one electroacoustic transducer, a processor in communication with the at least one electroacoustic transducer, and an exterior surface comprising a capacitive touch user interface that allows a user to control operation of the loudspeaker. The exterior surface acts a dielectric for the capacitive touch user interface. The loudspeaker may comprise a wireless transceiver circuit for receiving and transmitting wireless communication signals via a wireless network. The wireless transceiver circuit may receive wirelessly audio content from streaming audio content servers that are connected to the Internet. The capacitive touch user interface comprises a plurality of capacitive sense electrodes.

Wireless-enabled loudspeaker includes a capacitive touch user interface. The loudspeaker may comprise at least one electroacoustic transducer, a processor in communication with the at least one electroacoustic transducer, and an exterior surface comprising a capacitive touch user interface that allows a user to control operation of the loudspeaker. The exterior surface acts a dielectric for the capacitive touch user interface. The loudspeaker may comprise a wireless transceiver circuit for receiving and transmitting wireless communication signals via a wireless network. The wireless transceiver circuit may receive wirelessly audio content from streaming audio content servers that are connected to the Internet. The capacitive touch user interface comprises a plurality of capacitive sense electrodes.

A display system includes a head-mounted display unit and a detachable speaker unit. The head-mounted display unit outputs visual content to a user and provides a visual pass-through of a real environment to the user. The detachable speaker unit is detachably coupleable to the head-mounted display unit for providing aural content to the user. At least one of the visual content or the aural content is changed according to a position of the detachable speaker unit relative to the head-mounted display unit.

A device is configured to (i) receive media content from a media source, (ii) generate a first series of frames including first portions of the media content and first playback timing information, (iii) generate a second series of frames including second portions of the media content and second playback timing information, (iv) transmit the first series of frames to a first playback device in a synchrony group for playback of the first portions of the media content in accordance with the first playback timing information, and (v) transmit the second series of frames to a second playback device in the synchrony group for playback of the second portions of the media content in accordance with the second playback timing information such that the media content is played back in synchrony by the synchrony group.

A display system that includes a head-mounted display unit that outputs visual content to a user, an audio output device that outputs aural content to the user and is detachably coupleable to the head-mounted display unit, and a controller that controls the head-mounted display unit to output the visual content and the audio output device to output the aural content. The controller controls the audio output device to output the aural content when the audio output device is in a detached position with respect to the head-mounted display unit.

A playback device, comprising a first wireless network interface for operating according to an IEEE 802.15 standard and a second wireless network interface for operating according to an IEEE 802.11 standard, is configured to (i) operate as a group coordinator for a synchrony group comprising a first set of one or more playback devices and a second set of one or more playback devices, (ii) receive media content for playback by the synchrony group, (iii) transmit the media content to the first set of one or more playback devices via the first wireless network interface over a first wireless data network, (iv) transmit the media content to the second set of one or more playback devices via the second wireless network interface over a second wireless data network different from the first wireless data network, and (v) cause the synchrony group to play back the media content in synchrony.

The present technology relates to a sound processing apparatus and a sound processing system for enabling more stable localization of a sound image. A virtual speaker is assumed to exist on the lower side among the sides of a tetragon having its corners formed with four speakers surrounding a target sound image position on a spherical plane. Three-dimensional VBAP is performed with respect to the virtual speaker and the two speakers located at the upper right and the upper left, to calculate gains of the two speakers at the upper right and the upper left and the virtual speaker, the gains being to be used for fixing a sound image at the target sound image position. Further, two-dimensional VBAP is performed with respect to the lower right and lower left speakers, to calculate gains of the lower right and lower left speakers, the gains being to be used for fixing a sound image at the position of the virtual speaker. The values obtained by multiplying these gains by the gain of the virtual speaker are set as the gains of the lower right and lower left speakers for fixing a sound image at the target sound image position. The present technology can be applied to sound processing apparatuses.