Abstract: Devices and methods of manufacture for a deep trench layout area-saving semiconductor structure for use with bipolar-CMOS-DMOS (BCD) devices. A semiconductor device may comprise a first BCD device formed within a first perimeter of a first BCD layout area, and a deep trench isolation structure defining the first perimeter of the first BCD layout area, in which the deep trench isolation structure may comprise a first rounded corner that may define a first corner of the first BCD layout area. A semiconductor device may comprise, a substrate, BCD device formed on the substrate, and a deep trench isolation structure laterally surrounding the BCD device. The deep trench isolation structure, with respect to a top-down view, may comprise vertical portions, horizontal portions, a “T”-shaped intersection connecting at least one vertical portion and at least one horizontal portion, and a cross-shaped intersection connecting two vertical portions and two horizontal portions.

Abstract: The invention provides a touch device and a communication method thereof. The touch device includes a display panel and a controller. The controller controls the display panel to perform a display driving operation and a touch sensing operation. The controller may transmit a first wireless signal to another slave communication device via the display panel in a touch sensing period. The controller may receive a second wireless signal sent by another master communication device via the display panel in the touch sensing period. When the touch device serves as one of a master communication device and a slave communication device, a time length of the touch sensing period is a first time length. When the touch device serves as the other of the master communication device and the slave communication device, the time length of the touch sensing period is a second time length greater than the first time length.

Abstract: A semiconductor device includes a gate structure disposed in a first dielectric layer, a conductive segment disposed in the first dielectric layer and separated from the gate structure, a second dielectric layer disposed over the first dielectric layer, a first contact penetrating the second dielectric layer and electrically connected to the gate structure, a second contact penetrating the second dielectric layer and electrically connected to the conductive segment, and a silicon nitride-based layer surrounding at least one of the first and second contacts and connected between the second dielectric layer and the at least one of the first and second contacts. A method for making the semiconductor device is also provided.

Abstract: Implementations of the present disclosure provide coloring methods that sort and pre-color nodes of G0-linked networks in a multiple-patterning technology (MPT)-compliant layout design by coordinate. In one embodiment, a method includes identifying target networks in a circuit layout, each target network having two or more linked nodes representing circuit patterns, and each target network being presented in an imaginary X-Y coordinate plane, assigning a first feature to a first node in each target network, the first node is determined using a coordinate-based method, and assigning the first feature and a second feature to remaining nodes in each target network in an alternating manner so that any two immediately adjacent linked nodes in each target network have different features.

Abstract: Among other things, one or semiconductor arrangements, and techniques for forming such semiconductor arrangements are provided. An etch sequence is performed to form a first etched region over a planar region of a semiconductor arrangement. The first etched region exposes a planar structure, such as an alignment mark used for alignment during semiconductor fabrication. The etch sequence forms a second etched region over a semiconductor fin region of the semiconductor arrangement. In an embodiment, the etch sequence forms a first trench, a first fin nub and a first pillar in the semiconductor fin region, where the first trench is formed in a semiconductor substrate of the semiconductor fin region. A multi-depth STI structure is formed over at least one of the first trench, the first fin nub, or the first pillar.

Abstract: The present disclosure provides a semiconductor device and a method of manufacturing the semiconductor device. The semiconductor device includes a substrate, a word line, a plurality of first impurity regions, a second impurity region, and an isolation film. The word line is W-shaped, is disposed in the substrate, and includes a base and a pair of legs connected to the base. The first impurity regions are disposed in the substrate and on either side of the word line. The second impurity region is disposed between the legs of the word line. The isolation film is disposed in the substrate, wherein the word line is surrounded by the isolation film.

Abstract: The present invention provides improved processes for purifying liraglutide. Liraglutide is purified via two sequential RP-HPLC purifications followed by a salt-exchange step, where a pH is kept constant in the first and second purification steps. In particular, the processes utilize a halogenated solvent in a sample preparation step, which provides better solubility and an environment suitable for decarboxylation for crude liraglutide prior to a RP-HPLC purification.

Abstract: A cell array includes a substrate and a conductive line. The substrate has active areas in the substrate. The conductive line is disposed across the active areas and includes work function nodes and line sections which are horizontally and alternately arranged with work function nodes, in which each work function node is between two of the active areas.

Abstract: A semiconductor structure can include a high voltage region, a first moat trench isolation structure electrically insulating the high voltage region from low voltage regions of the semiconductor structure, and a second moat trench isolation structure electrically insulating the high voltage region from the low voltage regions of the semiconductor structure. The first moat trench isolation structure can include dielectric sidewall spacers and a conductive fill material portion located between the dielectric sidewall spacers. The second moat trench isolation structure can include only at least one dielectric material, and can include a dielectric moat trench fill structure having a same material composition as the dielectric sidewall spacers and having a lateral thickness that is greater than a lateral thickness of the dielectric sidewall spacers and is less than twice the lateral thickness of the dielectric sidewall spacers.

Abstract: The technical problem of reducing power consumption of paired client devices is addressed by using respective location data of paired client devices to determine whether to disable or to resume operation of short range wireless communication component, such as, e.g., a Bluetooth® sensor. In some examples, the location services utilize global positioning system (GPS). Respective location data of paired client devices is communicated between the paired client devices via a messaging server.

Abstract: A semiconductor device includes a substrate, a first semiconductor fin and a gate stack. The first semiconductor fin is over the substrate and includes a first germanium-containing layer and a second germanium-containing layer over the first germanium-containing layer. The first germanium-containing layer has a germanium atomic percentage higher than a germanium atomic percentage of the second germanium-containing layer. The gate stack is across the first semiconductor fin.

Abstract: A standard cell establishment method is disclosed. The standard cell establishment method includes the following operations: setting a first implant split case; obtaining a plurality of characteristic parameters according to the first implant split case; applying the plurality of characteristic parameters to a device delay metric so as to obtain a speed parameter; optimizing a channel parameter if the speed parameter is better than a previous speed parameter; and establishing a standard cell if the channel parameter is optimized successfully.

Abstract: A manufacturing method a semiconductor device includes the following steps. A first mask pattern and a second mask pattern are formed on a first region and a second region of a substrate respectively. The second region is located adjacent to the first region. A top surface of the first mask pattern is lower than a top surface of the second mask pattern in a thickness direction of the substrate. A trench is formed in the substrate. The trench is partly located in the first region and partly located in the second region. A first etching process is performed for reducing a thickness of the second mask pattern and reducing a height difference between the top surface of the first mask pattern and the top surface of the second mask pattern in the thickness direction of the substrate. An isolation structure is formed in the trench after the first etching process.

Abstract: Implementations of the present disclosure provide coloring methods that sort and pre-color nodes of G0-linked networks in a multiple-patterning technology (MPT)-compliant layout design by coordinate. In one embodiment, a method includes identifying target networks in a circuit layout, each target network having two or more linked nodes representing circuit patterns, and each target network being presented in an imaginary X-Y coordinate plane, assigning a first feature to a first node in each target network, the first node is determined using a coordinate-based method, and assigning the first feature and a second feature to remaining nodes in each target network in an alternating manner so that any two immediately adjacent linked nodes in each target network have different features.

Abstract: A semiconductor structure includes a substrate having a first region and a second region around the first region. A first fin structure is disposed within the first region. A second fin structure is disposed within the second region. A first isolation trench is disposed within the first region and situated adjacent to the first fin structure. A first trench isolation layer is disposed in the first isolation trench. A second isolation trench is disposed around the first region and situated between the first fin structure and the second fin structure. The bottom surface of the second isolation trench has a step height. A second isolation layer is disposed in the second isolation trench.

Abstract: A high voltage semiconductor device includes a semiconductor substrate, an isolation structure, a gate oxide layer, and a gate structure. The semiconductor substrate includes a channel region, and at least a part of the isolation structure is disposed in the semiconductor substrate and surrounds the channel region. The gate oxide layer is disposed on the semiconductor substrate, and the gate oxide layer includes a first portion and a second portion. The second portion is disposed at two opposite sides of the first portion in a horizontal direction, and a thickness of the first portion is greater than a thickness of the second portion. The gate structure is disposed on the gate oxide layer and the isolation structure.

Abstract: A semiconductor device package includes a supporting element, a transparent plate disposed on the supporting element, a semiconductor device disposed under the transparent plate, and a lid surrounding the transparent plate. The supporting element and the transparent plate define a channel.