A display control device includes a determination unit and a controller. The determination unit determines whether or not a subject viewed from a passenger falls within a display range of a virtual image based on the position information of the subject acquired from a recognition unit that recognizes the subject in the foreground of a moving object and the estimated value of a depression angle acquired from an estimation unit that estimates the depression angle when the virtual image is viewed from the passenger. In a case where the subject is determined to fall within the display range, the controller controls a display unit to generate an image that represents a first display image showing the information corresponding to the subject.

A display system includes a plurality of light emitting units configured to float in a fluid medium such that each light emitting unit is movable, each light emitting unit including a light emitting element configured to selectively emit light, a communication element operable to receive instruction data to control operation of the light emitting element; and a power element configured to provide power to at least the light emitting element, and an image capture element configured to receive light emitted by at least one light emitting unit and to generate image data based on the light received and a controller configured to generate the instruction data based at least on a comparison of the image data to a desired image and transmit the instruction data to the communication element to control the light emitting element such that the display system provides the desired image.

Head-mounted display systems and methods of operation that allow users to couple and decouple a portable electronic device such as a handheld portable electronic device with a separate head-mounted device (e.g., temporarily integrates the separate devices into a single unit) are disclosed. The portable electronic may be physically coupled to the head-mounted device such that the portable electronic device can be worn on the user's head. The portable electronic device may be operatively coupled to the head-mounted device such that the portable electronic device and head mounted device can communicate and operate with one another. Each device may be allowed to extend its features and/or services to the other device for the purpose of enhancing, increasing and/or eliminating redundant functions between the head-mounted device and the portable electronic device.

A multi-vision device can include a first display set configured to display a first split image of an entire image of content according to a progressive scanning method; a second display set disposed on a lower side of the first display set to display a second split image of the entire image; and a control unit configured to scan the second split image on the second display set according to a reverse-progressive scanning method, invert the scanned second split image vertically and display the inverted second split image on the second display set.

An apparatus may include a protective shell to protect a head of a wearer of the apparatus, where the protective shell may include a void of material positioned to be proximate a face of the wearer of the apparatus when wearing the apparatus. The apparatus may additionally include a visual interface device located proximate a border of the protective shell and the void of material, and a controller to provide display signals to the visual interface device.

A display driving integrated circuit performs an adaptive frame operation. An operation method of the display driving integrated circuit includes outputting current frame data to an external display panel, starting to receive next frame data from an external device after a first time point, the first time point being a time point when a first time period elapses, the first time period immediately following a second time point at which the current frame data are completely output, and generating a vertical synchronization signal at a third time point synchronized with a cycle of an emission control signal, in response to starting to receive the next frame data.

A display system includes: a display control device that inserts prescribed image data for lessening degradation of image quality in a middle of source data; and a display device that displays an image generated based on the source data and an image generated based on the prescribed image data.

A display device includes a plurality of pixels arranged in m rows and n columns, where the pixels receive write scan signals, data voltages and compensation scan signals, a plurality of write scan lines which provides the write scan signals to the pixels, a plurality of data lines which provides the data voltages to the pixels, and a plurality of compensation scan lines which provides the compensation scan signals to the pixels, wherein in h-th to p-th frames, the data voltages are applied to pixels arranged in first to i-th rows, and in h-th to (h+k)-th frames, the data voltages are applied to pixels of a row unit by increasing sequentially the number of the row unit to which the data voltages are applied in at least one row unit from an i-th row to an (i+1)-th row.

A display device includes a display panel including a first image unit and a second image unit, a data driver which applies data voltages to the display panel, a first scan driver which applies write scan signals to the display panel, a second scan driver which applies compensation scan signals and initialization scan signals to the display panel, and a masking part connected to the second scan driver and which selectively applies the initialization scan signals to the second image unit.

A driving method applicable to a display device, in which the display device includes multiple pixel circuits, and the method includes: adjusting multiple control signals according to a first display data such that the pixel circuits generate a first frame; receiving a second display data generated after the display data; and adjusting the control signals according to a time duration of the first frame such that the pixel circuits generate a second frame, where brightness for each of the pixel circuits is proportional to a duty ratio of one of the corresponding control signals, and an increment for the duty ratio of one of the corresponding control signals in the second frame is negatively correlated to a difference between a ratio of a preset time period to the time duration of the first frame and a ratio of the preset time period to the time duration of the second frame.