Abstract: A laser device for providing light to a LiDAR system comprises a plurality of seed lasers configured to provide multiple seed light beams, at least two of the seed light beams having different wavelengths. An amplifier is optically coupled to the plurality of seed lasers to receive the multiple seed light beams. A power pump is configured to provide pump power to the amplifier, where the amplifier amplifies the multiple seed light beams using the pump power to obtain amplified light beams. A second light coupling unit is configured to demultiplex the amplified light beams to obtain a plurality of output light beams, at least two of the output light beams having wavelengths corresponding to the wavelengths of the at least two seed light beams.

Abstract: A semiconductor memory device includes a substrate having a memory area and a logic circuit area thereon, a first interlayer dielectric layer on the substrate, and a second interlayer dielectric layer on the substrate. An embedded memory cell structure is disposed within the memory area between the first interlayer dielectric layer and the second interlayer dielectric layer. The second interlayer dielectric layer includes a first portion covering the embedded memory cell structure within the memory area and a second portion covering the logic circuit area. A top surface of the first portion is coplanar with a top surface of the second portion.

Abstract: A method for fabricating semiconductor device includes the steps of forming an inter-metal dielectric (IMD) layer on a substrate, forming a metal interconnection in the IMD layer, forming a magnetic tunneling junction (MTJ) on the metal interconnection, and performing a trimming process to shape the MTJ. Preferably, the MTJ includes a first slope and a second slope and the first slope is less than the second slope.

Abstract: A magnetoresistive random access memory (MRAM) device includes a first array region and a second array region on a substrate, a first magnetic tunneling junction (MTJ) on the first array region, a first top electrode on the first MTJ, a second MTJ on the second array region, and a second top electrode on the second MTJ. Preferably, the first top electrode and the second top electrode include different nitrogen to titanium (N/Ti) ratios.

Abstract: Various embodiments of the present disclosure are directed towards a semiconductor processing system including an overlay (OVL) shift measurement device. The OVL shift measurement device is configured to determine an OVL shift between a first wafer and a second wafer, where the second wafer overlies the first wafer. A photolithography device is configured to perform one or more photolithography processes on the second wafer. A controller is configured to perform an alignment process on the photolithography device according to the determined OVL shift. The photolithography device performs the one or more photolithography processes based on the OVL shift.

Abstract: A magnetoresistive random access memory (MRAM) structure, including a substrate and multiple MRAM cells on the substrate, wherein the MRAM cells are arranged in a memory region adjacent to a logic region. An ultra low-k (ULK) layer covers the MRAM cells, wherein the surface portion of ultra low-k layer is doped with fluorine, and dents are formed on the surface of ultra low-k layer at the boundaries between the memory region and the logic region.

Abstract: A method for generating a tree diagram of a shareholding structure from a capitalization table of a company, includes: generating a plurality of interactive icons that include a root node icon associated with the company, and a plurality of stem node icons each associated with a respective one of a plurality of related-parties recorded in the capitalization table, each of the related-parties being a partial owner or a subsidiary party; arranging the root node icon at an origin of the tree diagram, and arranging the stem node icons in the tree diagram such that the stem node icons associated with partial owners are on one side of the tree diagram and the stem node icons associated with the subsidiary parties are on an opposite side of the tree diagram; and plotting a plurality of investment routes each connecting two interactive icons arranged in the tree diagram.

Abstract: The present disclosure relates to a touch circuit pattern and a manufacturing method thereof. A capacitive touch circuit pattern in the present disclosure comprises a substrate, wherein at least two adjacent transparent first-axis electrode blocks, a transparent first-axis conductive wire, and at least two adjacent transparent second-axis electrode blocks are formed on the substrate. The first-axis conductive wire is formed between the two adjacent first-axis electrode blocks to connect the two adjacent first-axis electrode blocks and the two adjacent second-axis electrode blocks, respectively, at two sides of the first-axis conductive wire. The capacitive touch circuit pattern further comprises of a metal second-axis conductive wire, which stretches across the first-axis conductive wire and connects the two adjacent second-axis electrode blocks.

Abstract: A circuit structure for capacitive touch panel is disclosed herein. The circuit structure for capacitive touch panel includes a plurality of metal leads and a plurality of electrode sensing blocks. Those electrode sensing blocks are isolated to each other and electrically connected to the metal leads. The electrode sensing blocks will output a plurality of capacitive signals in accordance with a plurality of touch positions. According to the electrode pattern structure described above, the impedance of the electrode structure can be decreased and the efficiency of the signal transmission can be improved and the sensibility of the touch panel can be increased.

Abstract: The present invention relates to an embedded touch sensitive display, which includes a liquid crystal display (LCD), a touch sensing layer, a touch signal transfer circuit and a conductive media. The liquid crystal display comprises a top substrate, a bottom substrate, and a liquid crystal layer which is configured between the top substrate and the bottom substrate. The touch sensing layer is disposed below the top substrate of the LCD for generating touch signals after sensing an outside touch action, and the touch signal transfer circuit is disposed above the bottom substrate of the LCD. The conductive media is disposed between the touch sensing layer and the touch signal transfer circuit for transferring the touch signals between the touch sensing layer and the touch signal transfer circuit.

Abstract: A touch screen includes a liquid crystal layer, an upper transparent conductive layer, a lower transparent conductive layer, an upper transparent plate, a lower transparent plate, an upper polarizing plate, a lower polarizing plate and a circuit unit. The upper transparent conductive layer, the upper transparent plate, the circuit unit and the upper polarizing plate are disposed on the liquid crystal layer in the above-mentioned order from one side of the liquid crystal layer. The lower transparent conductive layer, the lower transparent plate and the lower polarizing plate are disposed under the liquid crystal layer in the above-mentioned order from another side of the liquid crystal layer.

Abstract: Disclosed are a capacitive touch control device and a method thereof. A top face of a substrate is provided with first and second electrode groups, which each include a plurality of strip-like electrodes spaced from each other by a preset distance. The electrodes of the first and second electrode groups are respectively connected by first and second group scanning lines to a scanning circuit. When the first group scanning lines drive the electrodes of the first electrode group, the second group scanning lines carry out scanning operation on the electrodes of the second electrode group, and when the second group scanning lines drive the electrodes of the second electrode group, the first group scanning lines carry out scanning operation on the electrodes of the first electrode group. And, a touch location can thus be determined by using a microprocessor.

Abstract: A multiple-angle transmission tool includes a first shell, a transmission stick, a first gear, a second shell, a connecting unit, a second gear, a transmission unit and a screw bolt, wherein each the first shell and the second shell has a connecting surface that has a number of recessed portions arranged in a circular manner, and each recessed portion is spaced with a protruding portion to form a restricted position to engage. Also, the first gear, the second gear and the transmission unit are located in a receiving space formed within the first shell and the second shell. When the first shell and the second shell move along the entire circumference, the momentum can be transmitted and changed when the first shell, the second shell and the transmission unit are engaged.

Abstract: A method of forming double-sided patterns in a touch panel circuit is disclosed. A first conductive layer and a second conductive layer are respectively formed on both sides of a substrate. A blocking layer is formed on a top surface of the first conductive layer for blocking ultraviolet (UV) light. A first photoresist layer is formed on a top surface of the blocking layer, and a second photoresist layer is formed on a bottom surface of the second conductive layer. Accordingly, two sides of the substrate may be exposed, developed and etched at the same time, thereby substantially simplifying the process of manufacturing the touch panel circuit.

Abstract: A multiple-angle transmission tool includes a first shell, a transmission stick, a first gear, a second shell, a connecting unit, a second gear, a transmission unit and a screw bolt, wherein each the first shell and the second shell has a connecting surface that has a number of recessed portions arranged in a circular manner, and each recessed portion is spaced with a protruding portion to form a restricted position to engage. Also, the first gear, the second gear and the transmission unit are located in a receiving space formed within the first shell and the second shell. When the first shell and the second shell move along the entire circumference, the momentum can be transmitted and changed when the first shell, the second shell and the transmission unit are engaged.

Abstract: A method of forming a touch sensing circuit pattern includes steps of: forming a first axial conductive line on a transparent substrate; forming an insulation barrier on the first axial conductive line; forming two separated first axial electrodes, two separated second axial electrodes and the second axial conductive line on the transparent substrate. The first axial electrodes are arranged on two sides of the insulation barrier along a first direction. The second axial electrodes are arranged on two opposite sides of the axial conductive line along a second direction. The second axial conductive line is across on the insulation barrier and connects to the second axial electrodes. The method of the invention can simplify the manufacturing process.

Abstract: The present disclosure relates to a touch circuit pattern and a manufacturing method thereof. A capacitive touch circuit pattern in the present disclosure comprises a substrate, wherein at least two adjacent transparent first-axis electrode blocks, a transparent first-axis conductive wire, and at least two adjacent transparent second-axis electrode blocks are formed on the substrate. The first-axis conductive wire is formed between the two adjacent first-axis electrode blocks to connect the two adjacent first-axis electrode blocks and the two adjacent second-axis electrode blocks, respectively, at two sides of the first-axis conductive wire. The capacitive touch circuit pattern further comprises of a metal second-axis conductive wire, which stretches across the first-axis conductive wire and connects the two adjacent second-axis electrode blocks.

Abstract: A touch device integrated with capacitive and resistive sensing operation includes a first substrate on which a first electrode pattern is formed and a second substrate on which a second electrode pattern is formed. The first and second electrode patterns are respectively connected to a microprocessor via a first scanning circuit and a second scanning circuit. When a user slightly touches a touch operation surface of the touch device, the touch device is set in a capacitive touch position detection mode. When the user forcibly depresses the touch operation surface of the touch device or carries out a hand writing input operation on the touch operation surface of the touch device, the touch device is set in a resistive touch position detection mode.

Abstract: A pressure detectable touch device includes a first substrate, a conductive layer formed on the first substrate, a second substrate, a first electrode pattern, a second electrode pattern, and a microprocessor. When a user touches a touch operation surface of the touch device in such an extent that the conductive layer and the first electrode pattern are not put into physical contact with each other, the touch device is set in a capacitive touch position detection mode. When the user forcibly depresses the touch operation surface of the touch device or carries out a hand writing input operation on the touch operation surface of the touch device, the conductive layer is caused to physically engage the first electrode pattern, setting the touch device in a resistive touch position detection mode.