A wireless power system for powering a television includes a source resonator, configured to generate an oscillating magnetic field, and at least one television component attached to at least one device resonator, wherein the at least one device resonator is configured to wirelessly receive power from the source resonator via the oscillating magnetic field when the distance between the source resonator and the at least one device resonator is more than 5 cm, and wherein at least one television component draws at least 10 Watts of power.

Split-type televisions provided in this invention relate to the field of television, and separately configures the master control module and the display in the television, the display is mainly used to play the audio and video data, and the master control module is mainly used to receive and process the audio and video data; the master control module and the display are separately configured in the physical structure, thus it allows users to carry out the operations like repairing, maintenance, upgrading and replacement on them separately; at the same time, since the display (the screen terminal) is provided with the power adapter for the master control module, and as long as the master control module is connected to the display, the power adapter will be able to supply power to the master control module, thus achieving the master control module and the display configured separately share the same power source.

A display apparatus includes a frame mounted on an observer's head, an image display device attached to the frame and a dimming device 700, the image display device includes an image forming device and an optical device 120, 320 having a virtual image forming region 140, 340 where a virtual image is formed on the basis of light emitted from the image forming device, the optical device 120, 320 overlaps with a portion of the dimming device 700, at the time of operation of the dimming device 700, a light blocking ratio of the dimming device 700 is changed over a range of from an upper region 701U to a lower region 701D and/or over a range of from an inner region 701C to an outer region 701S, and a virtual image forming region facing region 701 has a light blocking ratio higher than the light blocking ratio of the lower region 701D or the outer region 701S.

To provide a head-mounted display excellent in portability and operability. A head-mounted display according to the present technology includes a main body and an input operation section. The main body includes a display section configured to present an image to a user and is configured to be mountable on a head of the user. The input operation section includes a first detection element that extends in a first axis direction and is provided in the main body and electrostatically detects an operation position in the first axis direction, and a first guide section that guides an input operation of the user along the first axis direction on the first detection element, and controls the image.

In order to manufacture an input and output device (1) for industrial use as cost-effectively as possible, while also fulfilling the demanding requirements in an industrial environment, it is provided that the frame (2) of the input and output device (1) is assembled from a plurality of individual frame sections (2a, 2b, 2c, 2d) which are connected to one another at the corners (14a, 14b, 14c, 14d) in order to form the frame (2a, 2b, 2c, 2d) and which are firmly bonded at the adjoining connecting surfaces (15) in order to form a fully sealed external front face (6) of the frame (2) and a fully sealed external circumferential surface (13) of the frame (2).

According to principles of the embodiments as disclosed herein, a device that determines its own orientation and selects an appropriately oriented antenna based on the device's orientation is provided. The device may include a housing including an interior having a base and a top and a first sidewall extending from a perimeter of the base to the top. A plurality of antenna may be coupled to the housing one or more orientation sensors may also be coupled to the housing. A controller may be electrically coupled to each of the plurality of antenna and the one or more orientation sensors, and may be configured to receive information from the one or more orientation sensors, determine an orientation of the housing, and select one of the plurality of antenna to transmit and receive data. A transceiver may be located within the housing and at least one of the plurality of antenna may be being electrically coupled to the antenna.

A cable management system comprising at least a first control cable with a respective cable connector that is configured to operably link with a video/audio source device, a control button configured to generate a control signal when pressed thereby causing transfer of control of the one or more pieces of video/audio presentation equipment from a video/audio source device of a previous user upon selection of the button while the previous user is controlling the pieces of video/audio presentation equipment to a video/audio source device of the user that pressed the control button and initiating control of the pieces of video/audio presentation equipment upon selection of the button while no user is controlling the one or more pieces of video/audio presentation equipment and an illuminated indicator configured to illuminate in a manner indicative of a control state of the video/audio presentation equipment.

In a stereoscopic video observation device 200, an optically transmissive HMD 208 presents video observed when a three-dimensional image in a virtual three-dimensional space is projected into a real space. A transmittance changing section changes the transmittance of light that passes through the optically transmissive HMD 208. A shutter control section 220 sets a lower limit value of the light transmittance that can be changed by the transmittance changing section.

In a stereoscopic video observation device 200, an optically transmissive HMD 208 presents video observed when a three-dimensional image in a virtual three-dimensional space is projected into a real space. A transmittance changing section changes the transmittance of light that passes through the optically transmissive HMD 208. A shutter control section 220 sets a lower limit value of the light transmittance that can be changed by the transmittance changing section.

A display device is provided, which includes a display configured to display a user interface (UI) screen, a status display which includes a plurality of light emitting elements arranged on an outline region of the display, and a controller configured to control a light emitting status of the plurality of light emitting elements so as to provide a light interaction in which the plurality of light emitting elements operate in a preset display pattern based on an interaction occurring on the UI screen.