Abstract: A transient voltage suppression device includes at least one P-type lightly-doped structure and at least one electrostatic discharge structure. The electrostatic discharge structure includes an N-type lightly-doped well, an N-type well, a first P-type heavily-doped area, and a first N-type heavily-doped area. The N-type lightly-doped well is formed in the P-type lightly-doped structure. The N-type well is formed in the N-type lightly-doped well. The doping concentration of the N-type lightly-doped well is less than that of the N-type well. The first P-type heavily-doped area is formed in the N-type well. The first N-type heavily-doped area is formed in the P-type lightly-doped structure.

Abstract: A display device includes a base layer, a touch sensing layer, a light guide module and a display panel. The touch sensing layer is disposed on the base layer. The light guide module is disposed on the touch sensing layer. The touch sensing layer is located between the light guide module and the display panel, and the touch sensing layer and one of the light guide module and the display panel have no adhesive material therebetween.

Abstract: A method of manufacturing a memory device includes providing a substrate and sequentially forming a stack layer and a hard mask layer on the substrate. The method includes forming a first patterned mandrel and a plurality of second patterned mandrels on the hard mask layer, wherein the first patterned mandrel is adjacent to and spaced apart from an end of the second patterned mandrels in the first direction. The method further includes using the first patterned mandrel and the second patterned mandrels as masks, patterning the hard mask layer and the stack layer sequentially to form a dummy structure and a plurality of word lines separated from each other on the substrate. A portion of the stack layer corresponding to the first mandrel is formed into the dummy structure, and a portion of the stack layer corresponding to the second patterned mandrels is formed into the word lines.

Abstract: A lightweight 3D stereoscopic surgical microscope has a body, a robot set, an image set, and an operating set. The body has a wheel seat, a housing mounted on the wheel seat, and a host computer mounted in the housing. The robot set is connected to the body and has a base mounted on the housing, a transversal lever mounted on the base, a lifting arm connected to the transversal lever, and a rotating arm connected to the lifting arm. The image set is connected to the robot set and has an outer casing connected to the rotating arm, at least one objective lens mounted in the outer casing, a main display screen mounted on the outer casing, an auxiliary display screen mounted beside the body. The operating set is connected to the robot set, is connected to the body and the image set and has two operating bars.

Abstract: A 3D stereo image display device for a surgical microscope is provided. The surgical microscope comprises a main body, a mechanical arm, and an operation assembly. The 3D stereo image display device has a shell, at least one objective lens, an image processing circuit and a screen. The at least one objective lens is mounted in the shell. The image processing circuit is mounted in the shell and is electrically connected to the at least one objective lens. The host computer has an image processor for converting images captured by the at least one objective lens into 3D stereo images. The screen is mounted on an outer surface of the shell and is electrically connected to the image processing circuit for displaying the 3D stereo images. Thus, the 3D stereo image display device is provided to prevent tiredness and improve applicability and convenience.

Abstract: An adjustable dual-lens device for 3D stereoscopic surgical microscopes has an outer casing, an image set, and an adjusting set. The image set is mounted in the outer casing and has two lenses. The lenses are pivotally mounted in the outer casing at a spaced interval. The adjusting set is mounted in the outer casing and has two adjusting units. Each adjusting unit has a driving motor, a cam, and a limiting element. The driving motor is mounted in the outer casing adjacent to one of the lenses and has a driving shaft. The cam is eccentrically mounted around the driving shaft and is pressed against the lens that is adjacent to the driving motor. The limiting element is connected to the outer casing and the corresponding lens to enable the corresponding lens to press against the cam.

Abstract: A lightweight 3D stereoscopic surgical microscope has a body, a robot set, an image set, and an operating set. The body has a wheel seat, a housing mounted on the wheel seat, and a host computer mounted in the housing. The robot set is connected to the body and has a base mounted on the housing, a transversal lever mounted on the base, a lifting arm connected to the transversal lever, and a rotating arm connected to the lifting arm. The image set is connected to the robot set and has an outer casing connected to the rotating arm, at least one objective lens mounted in the outer casing, a main display screen mounted on the outer casing, an auxiliary display screen mounted beside the body. The operating set is connected to the robot set, is connected to the body and the image set and has two operating bars.

Abstract: An adjustable dual-lens device for 3D stereoscopic surgical microscopes has an outer casing, an image set, and an adjusting set. The image set is mounted in the outer casing and has two lenses. The lenses are pivotally mounted in the outer casing at a spaced interval. The adjusting set is mounted in the outer casing and has two adjusting units. Each adjusting unit has a driving motor, a cam, and a limiting element. The driving motor is mounted in the outer casing adjacent to one of the lenses and has a driving shaft. The cam is eccentrically mounted around the driving shaft and is pressed against the lens that is adjacent to the driving motor. The limiting element is connected to the outer casing and the corresponding lens to enable the corresponding lens to press against the cam.

Abstract: An adjustable light source device for a stereoscopic surgical microscope has a circuit board and multiple light sources. The circuit board is mounted in an outer casing of the stereoscopic surgical microscope and is electrically connected to a host computer of the stereoscopic surgical microscope. The light sources are electrically mounted on the circuit board at spaced intervals around two objective lenses of the stereoscopic surgical microscope and extend out of the outer casing. Each one of the light sources has a wavelength different from wavelengths of the other light sources and is controlled to emit light by an operating set of the stereoscopic surgical microscope via a program processing interface of the host computer sending signals to the circuit board. The adjustable light source device can emit lights with different wavelengths to enable the stereoscopic surgical microscope to capture clearer images for various surgical divisions.

Abstract: An electronic system and a charging method are provided. The electronic system includes an electronic device and a charger. The charger is coupled to the electronic device. The electronic device senses a first state of the electronic device. The electronic device determines whether a value corresponding to the first state is greater than a first threshold. When the value corresponding to the first state is greater than the first threshold, the electronic device provides a first control signal, and the charger charges the electronic device by using a first mode according to the first control signal. When the value corresponding to the first state is not greater than the first threshold, the electronic device provides a second control signal, and the charger charges the electronic device by using a second mode according to the second control signal.

Abstract: A composite barrier layer including at least one first barrier layer and at least one second barrier layer disposed in a stacking manner is provided. The Si—O—Si linear bond ratio is higher than the Si—O—Si network bond ratio in the first barrier layer. The Si—O—Si network bond ratio is higher than the Si—O—Si linear bond ratio in the second barrier layer.

Abstract: A laminate device is provided. The laminate device includes a substrate having a surface; a luminescent component over the surface of the substrate; a poly(p-xylylene) film over the surface of the substrate and covering the luminescent component; an interposer layer between the luminescent component and the substrate, wherein the interposer layer is bonded to both the substrate and the poly(p-xylylene) film in a covalent manner, wherein a ratio of Si—C bonds and Si—X bonds in the interposer layer is in a range from about 0.3 to about 0.8, wherein X is O or N; and a first barrier layer covering the poly(p-xylylene) film.

Abstract: The invention provides a flexible base material and a flexible electronic device. The flexible base material includes a flexible substrate having a first surface and a second surface opposite to the first surface. A first organic composite barrier layer is deposited on the first surface of the flexible substrate, wherein the first organic composite barrier layer applies a first stress to the flexible substrate. An anti-curved layer is deposited on the second surface of the flexible substrate, wherein the anti-curved layer applies a second stress to the flexible substrate, and wherein the second stress applied by the anti-curved layer cancels off more than 90% of the first stress.

Abstract: An embodiment of the invention provides a compound barrier layer, including: a first barrier layer disposed on a substrate; and a second barrier layer disposed on the first barrier layer, wherein the first barrier layer and second barrier layer both include a plurality of alternately arranged inorganic material regions and organo-silicon material regions and the inorganic material regions and the organo-silicon material regions of the first barrier layer and second barrier layer are alternatively stacked vertically.

Abstract: In an embodiment of the present disclosure, a composite graded refractive index layer structure is provided. The composite graded refractive index layer structure includes a substrate and a composite graded refractive index layer with varying compositions of zinc oxide and silicon oxide formed on the substrate, wherein the composite graded refractive index layer has a first surface where light penetrates thereinto and a second surface where light exits therefrom, and the composite graded refractive index layer has refractive index values which reduce from the first surface to the second surface. The present disclosure also provides an encapsulation structure including the composite graded refractive index layer structure.

Abstract: An embodiment of the present disclosure provides a laminate structure, including a substrate having a surface; a poly(p-xylylene) film over the surface of the substrate; and an interposer layer between the substrate and the poly(p-xylylene) film. The interposer layer is bonded to both the substrate and the poly(p-xylylene) film in a covalent manner, and a ratio of Si—C bonds and Si—X bonds in the interposer layer is in a range from about 0.3 to about 0.8, wherein X is O or N.

Abstract: A plasma apparatus including a chamber, an electrode set and a gas supplying tube set is provided. The chamber has a supporting table. The gas supplying tube set is disposed in the chamber and located between the supporting table and the electrode set. The gas supplying tube set includes at least one outer gas supplying tube and at least one first inner gas supplying tube. The first inner gas supplying tube is telescoped within the outer gas supplying tube. The outer gas supplying tube and the first inner gas supplying tube both have a plurality of gas apertures, and an amount of the gas apertures of the outer gas supplying tube is greater than an amount of the gas apertures of the first inner gas supplying tube.

Abstract: An embodiment of the invention provides a compound barrier layer, including: a first barrier layer disposed on a substrate; and a second barrier layer disposed on the first barrier layer, wherein the first barrier layer and second barrier layer both include a plurality of alternately arranged inorganic material regions and organo-silicon material regions and the inorganic material regions and the organo-silicon material regions of the first barrier layer and second barrier layer are alternatively stacked vertically.

Abstract: The invention relates to a remote controlled positioning system, a control system and a display device thereof. The remote controlled positioning system includes a liquid crystal display (LCD) panel, a backlight source, a plurality of infrared ray (IR) sources and a directional remote controller. The LCD panel includes a plurality of display areas. The plurality of IR sources is disposed behind the LCD panel, wherein the IR sources are correspondingly disposed according to the positions of the display areas to respectively emit infrared rays to pass through the LCD panel. The directional remote control receives the infrared rays emitted by the infrared ray sources to obtain positional information pointed to a position of the LCD panel by the directional remote control.

Abstract: The invention provides a flexible base material and a flexible electronic device. The flexible base material includes a flexible substrate having a first surface and a second surface opposite to the first surface. A first organic composite barrier layer is deposited on the first surface of the flexible substrate, wherein the first organic composite barrier layer applies a first stress to the flexible substrate. An anti-curved layer is deposited on the second surface of the flexible substrate, wherein the anti-curved layer applies a second stress, which is cancelled off more than 90% of the first stress, to the flexible substrate.