Abstract: Display panels capable of eliminating reliability issues due to high switching frequency. The display panel comprises a data driver outputting first, second, third and fourth data signals in sequence through a data line, a scan driver outputting first and second scan signals in sequence through first and second scan lines and an auxiliary driver generates first and second auxiliary signals in sequence, and first and second display cells commonly receives the first scan signal through the first scan line and receives the first and the second data signal through the data line, and a first switch is coupled to the data line and the second display cell, turning on and off in sequence according to the first auxiliary signal when the first scan signal is applied thereto such that the second and the first display cells receive the first and the second data signals in sequence.

Abstract: The digital-to-analog converter in accordance with the present invention comprises an R-2R transistor-only ladder converter and a digital controller. The controller connects to the R-2R transistor-only ladder converter and comprises at least one regulating transistor and at least one shifting transistor. The at least one regulating transistor has an aspect ratio of kR(W/L). The at least one shifting transistor has an aspect ratio of kS(W/L). Setting the aspect ratios kR(W/L) and kS(W/L) of the shifting and regulating transistors adjusts a linear output current waveform to a non-linear waveform. The method to output a non-linear current comprises acts of determining an optimum non-linear output current, dividing a linear output current into multiple sections, determining slopes of the waveform of the output current, adding a controller corresponding to an R-2R transistor-only ladder converter, setting aspect ratios kR(W/L) of regulating transistors and setting an aspect ratios kS(W/L) of shifting transistors.

Abstract: Display panels capable of eliminating reliability issues due to high switching frequency. The display panel comprises a data driver outputting first, second, third and fourth data signals in sequence through a data line, a scan driver outputting first and second scan signals in sequence through first and second scan lines and an auxiliary driver generates first and second auxiliary signals in sequence, and first and second display cells commonly receives the first scan signal through the first scan line and receives the first and the second data signal through the data line, and a first switch is coupled to the data line and the second display cell, turning on and off in sequence according to the first auxiliary signal when the first scan signal is applied thereto such that the second and the first display cells receive the first and the second data signals in sequence.

Abstract: A uniform composite nanofiber includes a tubular first nanofiber, and a second nanofiber formed inside or outside the first nanofiber. The first nanofiber is first formed within a plurality of nano-scale pores of a template placed on a current collector, and then the second nanofiber is formed on inner or outer surface of the first nanofiber, and the template is removed afterwards for obtaining the composite nanofiber.

Abstract: A power cell and charger assembly for an electrical tool has a power cell with two locking devices and a charger base with a sliding cover. The power cell and the charger base slidably engage each other. By setting the locking devices composed of push buttons and biasing members, the power cell and the charger base can be firmly engaged and conveniently detached. Additionally, the sliding cover protects the electrodes from corroding or becoming dusty when power cell is not attached to the charger base. Therefore, the power cell is conveniently attached to or disengaged from the charger base, and the power cell and charger assembly has long life span when the electrodes are kept clean by the sliding cover.

Abstract: Methods of fabricating one-dimensional composite nanofiber on a template membrane with porous array by chemical or physical process are disclosed. The whole procedures are established under a base concept of “secondary template”. First of all, tubular first nanofibers are grown up in the pores of the template membrane. Next, by using the hollow first nanofibers as the secondary templates, second nanofibers are produced therein. Finally, the template membrane is removed to obtain composite nanofibers. Showing superior performance in weight energy density, current discharge efficiency and irreversible capacity, the composite nanofibers are applied to extensive scopes like thin-film battery, hydrogen storage, molecular sieving, biosensor and catalyst support in addition to applications in lithium batteries.

Abstract: A memory structure, a memory device and a manufacturing method thereof are provided. First, a substrate is provided and a dielectric layer is formed over the substrate. Then, a pattern is formed in the dielectric layer. An amorphous silicon layer is formed in the pattern and over the dielectric layer. The amorphous silicon layer is patterned to form an electrode over the pattern. Then, a spacer is formed on the sidewall of the electrode. A selective hemispherical grains (HSGS) layer is formed over the surface of the electrode and the surface of the spacer.

Abstract: A memory structure, a memory device and a manufacturing method thereof are provided. First, a substrate is provided and a dielectric layer is formed over the substrate. Then, a pattern is formed in the dielectric layer. An amorphous silicon layer is formed in the pattern and over the dielectric layer. The amorphous silicon layer is patterned to form an electrode over the pattern. Then, a spacer is formed on the sidewall of the electrode. A selective hemispherical grains (HSGS) layer is formed over the surface of the electrode and the surface of the spacer.

Abstract: Display panels capable of eliminating reliability issues due to high switching frequency. The display panel comprises a data driver outputting first, second, third and fourth data signals in sequence through a data line, a scan driver outputting first and second scan signals in sequence through first and second scan lines and an auxiliary driver generates first and second auxiliary signals in sequence, and first and second display cells commonly receives the first scan signal through the first scan line and receives the first and the second data signal through the data line, and a first switch is coupled to the data line and the second display cell, turning on and off in sequence according to the first auxiliary signal when the first scan signal is applied thereto such that the second and the first display cells receive the first and the second data signals in sequence.

Abstract: An electroplating system is provided. The system comprises a reaction tank, a tube, and a video bubble detector. The reaction tank, having a first diameter, contains a plating solution. The tube, connecting to the reaction tank, comprises an inflow tube and a branch, wherein the inflow tube inputs the plating solution into the reaction tank, and the branch has an enlarged part having the first diameter. The video bubble detector, mounted on the enlarged part of the branch, detects the presence of a bubble in the plating solution flowing through the branch.

Abstract: The present invention provides a system for recording an image onto a label layer of an optical disc. The optical disc also includes a data layer on which a plurality of predetermined address codes is marked. The system essentially includes a multi-focal lens module for dividing a laser beam emitted by an optical pick-up unit into a first beam portion and a second beam portion. The first beam portion is focused on the data layer to locate a first position by retrieving the predetermined address codes. The second beam portion is focused on the label layer to record the image at a second position opposite to the first position.

Abstract: An insulated structure of a chip array component and fabrication method of the same, the element is fabricated by enclosing its main body with a dense layer of high surface insulation resistance material, and then exposing the portions of the main body where terminal electrodes are to be formed by removing the dense layer of high surface insulation resistance material by employing sand blasting, laser trimming, grinding, or etching process.

Abstract: A power cell and charger assembly for an electrical tool has a power cell with two locking devices and a charger base with a sliding cover. The power cell and the charger base slidably engage each other. By setting the locking devices composed of push buttons and biasing members, the power cell and the charger base can be firmly engaged and conveniently detached. Additionally, the sliding cover protects the electrodes from corroding or becoming dusty when power cell is not attached to the charger base. Therefore, the power cell is conveniently attached to or disengaged from the charger base, and the power cell and charger assembly has long life span when the electrodes are kept clean by the sliding cover.

Abstract: An insulated structure of a chip array component and fabrication method of the same, the element is fabricated by enclosing its main body with a dense layer of high surface insulation resistance material, and then exposing the portions of the main body where terminal electrodes are to be formed by removing the dense layer of high surface insulation resistance material by employing sand blasting, laser trimming, grinding, or etching process.

Abstract: Methods of fabricating one-dimensional composite nanofiber on a template membrane with porous array by chemical or physical process are disclosed. The whole procedures are established under a base concept of “secondary template”. First of all, tubular first nanofibers are grown up in the pores of the template membrane. Next, by using the hollow first nanofibers as the secondary templates, second nanofibers are produced therein. Finally, the template membrane is removed to obtain composite nanofibers. Showing superior performance in weight energy density, current discharge efficiency and irreversible capacity, the composite nanofibers are applied to extensive scopes like thin-film battery, hydrogen storage, molecular sieving, biosensor and catalyst support except applications in lithium batteries.

Abstract: A low-cost, simple method for manufacturing highly-ordered nanofibers is provided. The feature of the procedure is using a self-catalytic mechanism. First of all, a porous membrane template is used as a filter to spread metal nanoparticles, which have a self-catalytic characteristic, onto a current collector. After removing, the membrane template, the nanoparticles grow and become highly-ordered nanofibers by heat treatment in an oxygen atmosphere. The nanofibers show superior field emission effects and are therefore ideal field emission sources.

Abstract: The present invention discloses a method to manufacture a self-aligned silicide layer on a substrate. A metal oxide semiconductor (MOS) device and a shallow trench are fabricated in the substrate. The device has a gate structure, spacers of the gate structured and doping regions. The shallow trench is refilled with silicon oxide material for isolation. A silicon layer is nonconformally deposited on the top surface of the gate structure, the spacers and the doping regions by using a physical vapor deposition (PVD) process, such as ion metal plasma (IMP) process. The IMP process, like a sputtering process, is to ionize a silicon material or a refractory-metal material to silicon ions or metal ions and the ions are biased to anisotropically deposit on the top surface of the substrate. A refractory metal layer is defined on the top surface of the silicon layer by the IMP technology.