A liquid crystal display device comprises a display panel, at least one signal generator, and a plurality of wires. The display panel has a plurality of input ends to receive data signal. The at least one signal generator has a plurality of output ends to supply the data signal to the input ends of the display panel, respectively. The wires connects the output ends of the at least one signal generator to the input ends of the display panel, respectively, the wires having lengths measured between the output ends of the at least one signal generator and the input ends of the display panel, respectively, the length of the wires being different from each other according to location of the output ends of the at least one signal generator.

A computerized watch is described that includes a cover that forms an outer surface of the computerized watch, a screen configured to output graphical information for display, a set of physical watch hands positioned between the cover and the screen and configured to present a time of day. One or more computer processors and a memory comprising instructions. The instructions, when executed, cause the one or more computer processors to responsive to determining that the computerized watch is operating in a time display mode, manipulate the set of physical watch hands such that the set of physical watch hands present the time of day by obscuring a portion of a display region of the screen, and responsive to determining that the computerized watch is not operating in the time display mode, manipulate the set of physical watch hands such that the set of physical hands do not obscure the screen.

The invention discloses a smart watch, which comprises: a dial (10), a first and a second straps (20,24), connected respectively to both sides of the dial (10); wherein a first and a second displays (12,13) are disposed respectively on a front and a back of the shell body (11) of the dial (10), the first and second straps (20,24) are disposed with a plurality of clasps (21) and clasp holes (22) correspondingly, and the first and second displays (12,13) can have the same or different shapes and sizes, depending on whether the watch is worn on front or back, so that when worn on different side, different display is viewed to achieve complex application. Designing different appearances for the front and back of smart watch satisfies various esthetics, and manufacturing the first and second displays (12,13) monolithically simplifies the control circuit to improve smart watch quality.

The invention discloses a smart watch, which comprises: a dial (10), a first and a second strap (20, 24), connected respectively to both sides of the dial (10), a main display (12) disposed on a front of the dial (10), a first secondary display (13) disposed on the end of the first strap (20) connected to the dial (10), and a second secondary display (14) disposed on the end of the second strap (24) and connected to the dial (10) to increase the display area of the smart watch to achieve complex human machine interaction to satisfy various demands for display by the users. By using monolithic manufacturing method, the invention achieves reducing the number of control circuit and cost. The present invention provides a multiple numerical operation method for smart watch is easy to operate and can enhance user experience.

A computerized watch is described that includes a cover that forms an outer surface of the computerized watch, a screen configured to output graphical information for display, a set of physical watch hands positioned between the cover and the screen and configured to present a time of day. One or more computer processors and a memory comprising instructions. The instructions, when executed, cause the one or more computer processors to responsive to determining that the computerized watch is operating in a time display mode, manipulate the set of physical watch hands such that the set of physical watch hands present the time of day by obscuring a portion of a display region of the screen, and responsive to determining that the computerized watch is not operating in the time display mode, manipulate the set of physical watch hands such that the set of physical hands do not obscure the screen.

A multiview 3D wrist watch includes clock circuitry to determine a time, and a plurality of light sources to generate a plurality of input planar lightbeams. A directional backplane having a plurality of directional pixels scatters the plurality of input planar lightbeams into a plurality of directional lightbeams. Each directional lightbeam has a direction and an angular spread controlled by characteristics of a directional pixel in the plurality of directional pixels. A shutter layer receives the time from the clock circuitry and modulates the plurality of directional lightbeams to generate a 3D time view.

A computerized watch is described that includes a cover that forms an outer surface of the computerized watch, a screen configured to output graphical information for display, a set of physical watch hands positioned between the cover and the screen and configured to present a time of day. One or more computer processors and a memory comprising instructions. The instructions, when executed, cause the one or more computer processors to responsive to determining that the computerized watch is operating in a time display mode, manipulate the set of physical watch hands such that the set of physical watch hands present the time of day by obscuring a portion of a display region of the screen, and responsive to determining that the computerized watch is not operating in the time display mode, manipulate the set of physical watch hands such that the set of physical hands do not obscure the screen.

A method for manufacturing a reflective or transflective liquid crystal display device including a liquid crystal cell whose liquid crystal molecules are aligned in a planar or vertical manner, this liquid crystal cell being formed of a transparent front substrate located on the side of an observer, and a rear substrate, also transparent, which extends under the front substrate, parallel to and at a distance from the latter, these two front and rear substrates being joined together with a sealing frame which delimits a sealed enclosure in which a liquid crystal composition is confined, the front and rear substrates being coated on the opposite faces thereof with electrically conductive transparent electrodes and counter-electrodes, the optical properties of the liquid crystal composition being changed by applying an electric field at the crossing point between an electrode and a corresponding counter-electrode.

A liquid crystal display device comprises a display panel, at least one signal generator, and a plurality of wires. The display panel has a plurality of input ends to receive data signal. The at least one signal generator has a plurality of output ends to supply the data signal to the input ends of the display panel, respectively. The wires connects the output ends of the at least one signal generator to the input ends of the display panel, respectively, the wires having lengths measured between the output ends of the at least one signal generator and the input ends of the display panel, respectively, the length of the wires being different from each other according to location of the output ends of the at least one signal generator.

A method for manufacturing a reflective or transflective liquid crystal display device including a liquid crystal cell whose liquid crystal molecules are aligned in a planar or vertical manner, this liquid crystal cell being formed of a transparent front substrate located on the side of an observer, and a rear substrate, also transparent, which extends under the front substrate, parallel to and at a distance from the latter, these two front and rear substrates being joined together with a sealing frame which delimits a sealed enclosure in which a liquid crystal composition is confined, the front and rear substrates being coated on the opposite faces thereof with electrically conductive transparent electrodes and counter-electrodes, the optical properties of the liquid crystal composition being changed by applying an electric field at the crossing point between an electrode and a corresponding counter-electrode.