Abstract: The present invention provides a method for manufacturing a neural probe incorporated with an optical waveguide. The method for manufacturing a neural probe incorporated with an optical waveguide comprises the following steps. A mold-filling step, for providing a base with at least one groove formed therein. A disposing step, for disposing and overlaying a substrate having a plurality of electrode parts on the groove of the base. A combining step, for solidifying the photosensitive adhesive by a solidification process, the solidified photosensitive adhesive forming an optical waveguide and being combined with the substrate. A mold-releasing step, for removing the base from the optical waveguide and the substrate, the substrate and the optical waveguide forming a product.

Abstract: The present invention provides a method for manufacturing a neural probe incorporated with an optical waveguide. The method for manufacturing a neural probe incorporated with an optical waveguide comprises the following steps. A mold-filling step, for providing a base with at least one groove formed therein. A disposing step, for disposing and overlaying a substrate having a plurality of electrode parts on the groove of the base. A combining step, for solidifying the photosensitive adhesive by a solidification process, the solidified photosensitive adhesive forming an optical waveguide and being combined with the substrate. A mold-releasing step, for removing the base from the optical waveguide and the substrate, the substrate and the optical waveguide forming a product.

Abstract: The present invention provides a method for manufacturing a neural probe incorporated with an optical waveguide. The method for manufacturing a neural probe incorporated with an optical waveguide comprises the following steps. A mold-filling step, for providing a base with at least one groove formed therein. A disposing step, for disposing and overlaying a substrate having a plurality of electrode parts on the groove of the base. A combining step, for solidifying the photosensitive adhesive by a solidification process, the solidified photosensitive adhesive forming an optical waveguide and being combined with the substrate. A mold-releasing step, for removing the base from the optical waveguide and the substrate, the substrate and the optical waveguide forming a product.

Abstract: A LGF roll-to-roll manufacturing includes the steps of: preparing a first optical layer with a first surface and a second surface; mechanically extruding a first integrated microstructure on the first surface of the first optical layer; subsequently coating a second optical layer on the first or second surface of the first optical layer; and curing the second optical layer to directly form a second microstructure on the first or second surface of the first optical layer. The first integrated microstructure and the second microstructure are separately formed at a time to provide a light guide film structure. In an embodiment, an additional optical layer is provided on the first optical layer.

Abstract: The present invention provides a verification method for system execution environment. According to the present invention, at least an algorithm is used for operating a basic input/output system (BIOS) and loaded program check information, a first characteristic code and operation system check information, a second characteristic code and file system check information, a third characteristic system library check information, and a fourth characteristic code and application program check information for acquiring the first to fifth characteristic codes. After verifying the first to fourth characteristic codes, unlocking a storage, loading an operational system, loading a file system, and loading a system library are executed. After all characteristic codes have passed verification, the application program is executed. Thereby, whether the execution environment for the system or program is reliable can be confirmed.

Abstract: A LGP plate-to-plate manufacturing includes the steps of: preparing an optical substrate with a first surface and a second surface; mechanically extruding a first integrated microstructure on the first surface of the optical substrate; coating an optical layer on the first or second surface of the optical substrate; and curing the optical layer to directly form a second microstructure on the first or second surface of the optical substrate; wherein the first integrated microstructure and the second microstructure are separately formed at a time to provide a light guide plate structure. In an embodiment, an additional optical layer is provided on the optical substrate.

Abstract: A LGP plate-to-plate manufacturing includes the steps of: preparing an optical substrate with a first surface and a second surface; mechanically extruding a first integrated microstructure on the first surface of the optical substrate; coating an optical layer on the first or second surface of the optical substrate; and curing the optical layer to directly form a second microstructure on the first or second surface of the optical substrate; wherein the first integrated microstructure and the second microstructure are separately formed at a time to provide a light guide plate structure. In an embodiment, an additional optical layer is provided on the optical substrate.

Abstract: A LGF roll-to-roll manufacturing includes the steps of: preparing a first optical layer with a first surface and a second surface; mechanically extruding a first integrated microstructure on the first surface of the first optical layer; subsequently coating a second optical layer on the first or second surface of the first optical layer; and curing the second optical layer to directly form a second microstructure on the first or second surface of the first optical layer; wherein the first integrated microstructure and the second microstructure are separately formed at a time to provide a light guide film structure. In an embodiment, an additional optical layer is provided on the first optical layer.

Abstract: A liquid crystal driving electrode and a liquid crystal display using the same are provided. The liquid crystal driving electrode includes a substrate, a reflecting electrode layer, and a light-transmissible electrode. The substrate includes a plurality of pixels; each pixel has a reflection area and a transmission area adjacent to the reflection area. The reflecting electrode overlaps the reflecting area while the light-transmissible electrode overlaps the transmission area. The reflecting electrode has an effective margin. The light-transmissible electrode electrically connects to the reflecting electrode and extends to overlap the effective margin.

Abstract: An array substrate adopted for a liquid crystal display (LCD) device and the liquid crystal display device are provided. The array substrate includes a substrate, a plurality of scan lines, a plurality of data lines, a plurality of switching devices, and an insulating layer, wherein the insulating layer is deposited above the scan lines and the data lines, and has a plurality of free ends. A pair of the free ends faces each other and defines a broken region, and each free end has a tilt down profile with a decreasing width facing the broken region. The profile can avoid the short circuiting between the two adjacent array pixels, which is caused by the residual reflective electrode during the process.

Abstract: A two-factor authentication system is provided for securing online transactions. In the two-factor authentication system, a transaction server provides online transaction services. A mobile communication device receives short messages. A client computing device applies a first authentication function to communicate with the transaction server, receives, via short messages, a first authentication code used to authenticate the transaction server, and applies a second authentication function to generate a second authentication code. Next, the transaction server authenticates the client computing device with the second authentication function and second authentication code.

Abstract: An array substrate adapted for a liquid crystal display (LCD) device and the liquid crystal display device are provided. The LCD device includes an opposing substrate, an array substrate, and a liquid crystal layer. The array substrate is disposed opposite to the opposing substrate, and the liquid crystal layer is filled therebetween. The array substrate includes a substrate, a plurality of scan lines, a plurality of data lines, a plurality of switching devices, and an insulating layer. The scan lines are substantially perpendicular to the data lines to define a plurality of array pixels. The switching devices are connected to the corresponding scan lines and the data lines. The insulating layer is deposited above the scan lines and the data lines, and has a plurality of free ends. Two of the free ends define a broken region. Each of the free ends has a tilt down profile with a decreasing width facing the broken region.

Abstract: A liquid crystal driving electrode and a liquid crystal display using the same are provided. The liquid crystal driving electrode includes a substrate, a reflecting electrode layer, and a light-transmissible electrode. The substrate includes a plurality of pixels; each pixel has a reflection area and a transmission area adjacent to the reflection area. The reflecting electrode overlaps the reflecting area while the light-transmissible electrode overlaps the transmission area. The reflecting electrode has an effective margin. The light-transmissible electrode electrically connects to the reflecting electrode and extends to overlap the effective margin.

Abstract: A backlight module has a frame, on which a reflective film, lamps and a diffusive plate are provided in sequence. A plurality of positioning devices each have a base and two rings. The base has two channels, two slots and a post on a top thereof. The lamps are fitted to the rings respectively and the rings are mounted in the slots of the base respectively to rest the lamps in the channels. The base of the positioning devices are secured on the bottom plate of the frame and the posts thereof are against the diffusive plate, such that the lamp is suspended and the relative locations of the lamps, the diffusive plate and the reflective film are fixed.

Abstract: A direct-light illuminating unit has a frame on which a plurality of U-shaped lamps and a plurality of light shade devices are mounted. The frame has a window region and a margin region. The lamps each have two straight portions and a connection portion. The lamps have the straight portions and the connection portions arranged in the window region of the frame. The light shade device has a top mask extended over the connection portions of the lamps respectively. The top masks have a predetermined transparency to shade a part of the light provided from the connection portions of the lamps respectively.

Abstract: A backlight module has a frame, on which a reflective film, lamps and a diffusive plate are provided in sequence. A plurality of positioning devices each have a base and two rings. The base has two channels, two slots and a post on a top thereof. The lamps are fitted to the rings respectively and the rings are mounted in the slots of the base respectively to rest the lamps in the channels. The base of the positioning devices are secured on the bottom plate of the frame and the posts thereof are against the diffusive plate, such that the lamp is suspended and the relative locations of the lamps, the diffusive plate and the reflective film are fixed.

Abstract: A direct-light illuminating unit has a frame on which a plurality of U-shaped lamps and a plurality of light shade devices are mounted. The frame has a window region and a margin region. The lamps each have two straight portions and a connection portion. The lamps have the straight portions and the connection portions arranged in the window region of the frame. The light shade device has a top mask extended over the connection portions of the lamps respectively. The top masks have a predetermined transparency to shade a part of the light provided from the connection portions of the lamps respectively.