One variation of system includes a set of a brixel units and a primary controller configured to distribute a set of actuation routines to the set of brixel units, each brixel unit including: a chassis including a motor mount and a arm extending outwardly from the motor mount and defining a drive post mount opposite the motor mount; a motor coupled to the motor mount; a drive post arranged on the drive post mount and driven by the motor; a pixel element mounted to and configured to rotate with the drive post and including a first face defining a first visual characteristic and a second face defining a second visual characteristic; and a local controller configured to store an actuation routine and to drive the motor to locate the pixel element over a sequence of angular positions, relative to the arm, defined by the actuation routine.

In certain embodiments, secure data presentation may be facilitated for a tactile system. In some embodiments, the tactile system may include a display having carbon nanotube-based components having a surface that absorbs at least 96% of visible light. The tactile system may obtain tactile data and present the tactile data on the display by adjusting one or more positions of the carbon nanotube-based components based on the tactile data. In some embodiments, the tactile system may obtain environmental data (e.g., lighting data, presence data, etc.) for an environment (in which the display is located) and perform the adjustment of the positions of the carbon nanotube-based components based on (i) the tactile data and (ii) the environmental data.

The purpose of the present invention is to provide a magnetic fluid display in which a magnetic fluid moves in response to a magnetic field and which may display a unique visual image according to the meeting and parting of the magnetic fluid. A magnetic fluid display according to the present invention comprises: a display unit including a transparent liquid into which a magnetic fluid is injected; and a magnetic field generating unit for applying a magnetic field to the magnetic fluid at a rear surface of the display unit. When the magnetic field is applied, the magnetic fluid moves in the transparent liquid in a directional manner, so that an image may be displayed on the display unit.

The purpose of the present invention is to provide a magnetic fluid display in which a magnetic fluid moves in response to a magnetic field and which may display a unique visual image according to the meeting and parting of the magnetic fluid. A magnetic fluid display according to the present invention comprises: a display unit including a transparent liquid into which a magnetic fluid is injected; and a magnetic field generating unit for applying a magnetic field to the magnetic fluid at a rear surface of the display unit. When the magnetic field is applied, the magnetic fluid moves in the transparent liquid in a directional manner, so that an image may be displayed on the display unit.

A display panel, a display device and a method for driving the display panel. The display panel includes: a rotation axis; at least one display area located at one side of the rotation axis; wherein the display area includes a plurality of display sub-areas; and a plurality of driving-control modules corresponding to the plurality of display sub-areas. The plurality of display sub-areas are sequentially arranged along a first direction; the first direction is directed from the rotation axis to the display area; when the display panel rotates around the rotation axis, areas passed by the plurality of display sub-areas form a plurality of imaging sub-areas. The plurality of driving-control modules are configured to control the plurality of display sub-areas to have different display parameters, respectively, thereby enabling imaging brightness of the plurality of imaging sub-areas to be within a preset brightness range.

A display panel, a display device and a method for driving the display panel. The display panel includes: a rotation axis; at least one display area located at one side of the rotation axis; wherein the display area includes a plurality of display sub-areas; and a plurality of driving-control modules corresponding to the plurality of display sub-areas. The plurality of display sub-areas are sequentially arranged along a first direction; the first direction is directed from the rotation axis to the display area; when the display panel rotates around the rotation axis, areas passed by the plurality of display sub-areas form a plurality of imaging sub-areas. The plurality of driving-control modules are configured to control the plurality of display sub-areas to have different display parameters, respectively, thereby enabling imaging brightness of the plurality of imaging sub-areas to be within a preset brightness range.

A 3D flexible display device is disclosed, including: a flexible screen, made of flexible materials, for displaying images; and a height control layer, formed on a back side of the flexible screen, configured to change the height of the raising on the area of the height control layer towards the flexible screen to control the height of the raising on the corresponding display area of the flexible screen. A display method of the 3D flexible display device is also disclosed. The above 3D flexible screen and 3D display method can make use of the deformation feature of the flexible display device, and raise a corresponding display area on the flexible display device with the height control to the area on the height control layer, thus presenting real 3D effects.

A vehicle information display apparatus includes: at least one processor configured to receive a vehicle state of a vehicle, and detect a forward object ahead of the vehicle; a flip-dot display installed in the vehicle and configured to implement a pixel by rotating a flip disk; and an illumination module installed around the flip-dot display, and configured to illuminate a surface of the flip-dot display.

Disclosed are a light emission device including a magnetoactive element, a method of fabricating the same, and an electronic device including the light emission device. The disclosed light emission device may include a light emission layer; a first electrode and a second electrode spaced apart from each other on a first surface side of the light emission layer; and a magnetoactive fluid layer disposed on a second surface side of the light emission layer and having a plurality of nanostructures of which arrangement and distribution is configured to change according to application of a magnetic field. The light emitting properties of the light emission layer may be changed according to the arrangement and distribution of a plurality of nanostructures in the magnetoactive fluid layer. The plurality of nanostructures may include conductive nanowire and magnetic nanoparticle provided on the surfaces of the conductive nanowire.

Structures for representing images comprise a plurality of tile elements which, when illuminated by a light source, each direct an amount of light toward an observer at a viewing location dependent on their orientation angles. The orientation angles of each tile element may be selected based on a characteristic of a corresponding pixel of an image, such that the observer sees a representation of that image created by the varying amount of light directed to the viewing location by the tile elements.