A television enclosure system includes a housing including a rear bezel and a front bezel coupled to the rear bezel, a gasket on the front wall of the front bezel, a panel held within the front bezel with the gasket between a front wall of the front bezel and the panel, at least one retaining bracket connected to a side wall of the front bezel, and at least one bezel clip coupled to the at least one retaining bracket and configured to engage the panel to compress the gasket.

A set-top box with self-monitoring and system and method for use of the same are disclosed. In one embodiment of the set-top box, a housing secures a television input, a television output, a processor, memory, and storage therein, which are communicatively interconnected by a busing architecture. The memory is accessible to the processor, and the memory includes processor-executable instructions that, when executed, cause the processor to detect when the television is not being utilized. Responsive thereto, the instructions cause the processor to scan channels received from the television input and generate a composite TV screen image data that may be resolved to a single TV screen image made from an assemblage of TV screen image captures corresponding to the scanned channels.

A set-top box with self-monitoring and system and method for use of the same are disclosed. In one embodiment of the set-top box, a housing secures a television input, a television output, a processor, memory, and storage therein, which are communicatively interconnected by a busing architecture. The memory is accessible to the processor, and the memory includes processor-executable instructions that, when executed, cause the processor to detect when the television is not being utilized. Responsive thereto, the instructions cause the processor to scan channels received from the television input and generate a composite TV screen image data that may be resolved to a single TV screen image made from an assemblage of TV screen image captures corresponding to the scanned channels.

A display apparatus according to an embodiment of the present disclosure includes: a display cell that displays an image and has a thin-plate shape; one or more vibration exciters that are disposed on rear-surface side of the display cell and cause the display cell to vibrate; and an opposing plate opposed to the display cell with an air gap in between. The display apparatus further includes a sound-spreading adjustment member that is disposed between the display cell and the two or more vibration exciters, and controls spreading of a sound generated by vibration caused by the two or more vibration exciters.

According to embodiments, a display apparatus and an operation method thereof are provided. The display apparatus includes: a volatile memory; a nonvolatile memory; and a processor configured to: determine stability of a system for the display apparatus; when a power-off input for the display apparatus is received, if the system is determined to be stable, enter a power-saving mode while maintaining power supply to the volatile memory in which execution data regarding an application currently being executed is stored; and if the system is determined to be unstable, perform power-off processing after storing execution status information of at least one application being executed in the nonvolatile memory, perform booting to execute the application by using application execution status information stored in the nonvolatile memory, and store the execution data regarding the executed application in the volatile memory and then enter the power saving mode while maintaining the power supply to the volatile memory.

Provided are an electronic device and an operating method thereof. The electronic device includes a display, a plurality of optical sensor units arranged to respectively correspond to a plurality of regions divided on the display, a memory storing one or more instructions, and a processor configured to execute the one or more instructions stored in the memory, in which the processor is further configured to, by executing the one or more instructions, determine an intensity and a direction of external light incident to each of the plurality of regions divided on the display, by using the plurality of optical sensor units, determine a shadow region on the display, based on the determined intensity and direction of the external light corresponding to each of the plurality of regions, and control the display to provide a shadow effect on the determined shadow region, overlappingly with an image that is currently displayed on the display.

According to one embodiment, a display device includes a display panel and a wiring board including a flexible base, a terminal electrically connected to the display panel, an IC chip, a wiring line which electrically connects the terminal and the IC chip. The base includes a first surface on which the IC chip and the terminal are provided, a second surface on an opposite side to the first surface, and a concavity in the second surface between the IC chip and the terminal.

A display device includes substrates, pixels, an inter-pixel light blocking portion, a spacer, a spacer non-arranged portion, and a spacer arranged portion. The pixels are arranged in each of a first direction and a second direction perpendicular to each other. The inter-pixel light blocking portion includes at least one first partition portion partitioning the pixels arranged in the first direction and at least one second partition portion partitioning the pixels arranged in the second direction. The spacer is disposed between the substrates. The spacer non-arranged portion in which the spacer is not arranged is included in the first partition portion. The spacer arranged portion in which the spacer is arranged is included in the first partition portion. The spacer arranged portion wider than the spacer non-arranged portion has a formation area straddling the second partition portion with respect to the second direction.

The support device has a mount part 10 for mounting an electronic device, a pair of support leg parts 20, and a pair of cross brace parts 30. The electronic device 600 when mounted on the mount part 10 is supported so as to be slanted rearward. The two support leg parts of the pair of support leg parts 20 are each provided with multiple receiving seats capable of receiving an anchor part of a cross brace part 30 and multiple bowl-shaped hole parts corresponding to the multiple receiving seats. The two cross brace parts of the pair of the cross brace parts 30 are each provided with a biasing stud having a semispherical tip, and when an anchor part is received by any of the receiving seats of the pair of support leg parts 20, the stud enters the bowl-shaped hole part corresponding to the receiving seat. Furthermore, the two cross brace parts of the pair of cross brace parts 30 maintain the angle of the pair of support leg parts 20 with respect to the mount part once the biasing studs have entered the bowl-shaped hole parts as the anchor parts are received by the receiving seats, and the biasing studs in the bowl-shaped hole parts are pulled out as the anchor parts detach from the receiving seats 201 and slide on inner surfaces of the pair of support leg parts 20 when the support leg parts are turned with respect to the pair of cross brace parts 30.

The support device has a mount part 10 for mounting an electronic device, a pair of support leg parts 20, and a pair of cross brace parts 30. The electronic device 600 when mounted on the mount part 10 is supported so as to be slanted rearward. The two support leg parts of the pair of support leg parts 20 are each provided with multiple receiving seats capable of receiving an anchor part of a cross brace part 30 and multiple bowl-shaped hole parts corresponding to the multiple receiving seats. The two cross brace parts of the pair of the cross brace parts 30 are each provided with a biasing stud having a semispherical tip, and when an anchor part is received by any of the receiving seats of the pair of support leg parts 20, the stud enters the bowl-shaped hole part corresponding to the receiving seat. Furthermore, the two cross brace parts of the pair of cross brace parts 30 maintain the angle of the pair of support leg parts 20 with respect to the mount part once the biasing studs have entered the bowl-shaped hole parts as the anchor parts are received by the receiving seats, and the biasing studs in the bowl-shaped hole parts are pulled out as the anchor parts detach from the receiving seats 201 and slide on inner surfaces of the pair of support leg parts 20 when the support leg parts are turned with respect to the pair of cross brace parts 30.