Abstract: In a method of cleaning a lithography system, during idle mode, a stream of air is directed, through a first opening, into a chamber of a wafer table of an EUV lithography system. One or more particles is extracted by the directed stream of air from surfaces of one or more wafer chucks in the chamber of the wafer table. The stream of air and the extracted one or more particle are drawn, through a second opening, out of the chamber of the wafer table.

Abstract: Disclosed is an electronic device including a device body and an antenna module. The antenna module includes a conductive element and at least one antenna element. The conductive element includes a main body portion and at least one assembly portion connected with each other. The at least one assembly portion is assembled on the device body. The at least one antenna element is disposed on the device body and coupled with the conductive element to excite a first resonance mode. The at least one assembly portion overlaps the at least one antenna element in the length direction of the main body portion.

Abstract: A backlight module and a display device are provided, and the backlight module includes a light guide plate, a plurality of light-emitting components, and a frame. The light guide plate includes a first side, a second side, and two third sides. The light-emitting components are disposed on the first side, and light generated from the light-emitting components enters the light guide plate from the first side. The frame covers the second side and the third sides and includes an opening and at least one buffer portion. The light-emitting components are disposed in the opening, and the buffer portion is disposed on a side of the opening and contacts the light guide plate.

Abstract: An electronic device includes a device body and an antenna module disposed in the device body and including a conductive structure and a coaxial cable including a core wire, a shielding layer wrapping the core wire, and an outer jacket wrapping the shielding layer. The conductive structure includes a structure body and a slot formed on the structure body and penetrating the structure body in a thickness direction of the structure body. A section of the shielding layer extends from the outer jacket and is connected to the structure body. A physical portion of the structure body and the section of the shielding layer are respectively located on two opposite sides of the slot in a width direction of the slot. A section of the core wire extends from the section of the shielding layer and overlaps the slot and the physical portion in the thickness direction.

Abstract: A semiconductor structure includes a substrate with a first surface and a second surface opposite to the first surface, a first and a second shallow trench isolations disposed in the substrate and on the second surface, a deep trench isolation structure in the substrate and coupled to the first shallow trench isolation, a first dielectric layer disposed on the first surface and coupled to the deep trench isolation structure, a second dielectric layer disposed over the first dielectric layer and coupled to the deep trench isolation structure, a third dielectric layer comprising a horizontal portion disposed over the second dielectric layer and a vertical portion coupled to the horizontal portion, and a through substrate via structure penetrating the substrate from the first surface to the second surface and penetrating the second shallow trench isolation.

Abstract: A semiconductor device and method for forming the semiconductor device are provided. In some embodiments, a semiconductor substrate comprises a device region. An isolation structure extends laterally in a closed path to demarcate the device region. A first source/drain region and a second source/drain region are in the device region and laterally spaced. A sidewall of the first source/drain region directly contacts the isolation structure at a first isolation structure sidewall, and remaining sidewalls of the first source/drain region are spaced from the isolation structure. A selectively-conductive channel is in the device region, and extends laterally from the first source/drain region to the second source/drain region. A plate comprises a central portion and a first peripheral portion. The central portion overlies the selectively-conductive channel, and the first peripheral portion protrudes from the central portion towards the first isolation structure sidewall.

Abstract: A method for sharing a console variable setting of an application and the electronic device and system is provided. The sharing method includes: capturing a display frame of a first electronic device to obtain a set coding image by a second electronic device; transforming the set coding image into a meta file by the second electronic device, wherein the meta file comprises a set of setting parameters for a plurality of first setting options of a first application of the first electronic device; and setting a plurality of second setting options of a second application of the second electronic device as the set of setting parameters for the plurality of first setting options according to the meta file, wherein the second application is the same as the first application.

Abstract: A multi-media processing system for live stream includes a first processing module, a control module, and a second processing module. The first processing module is communicatively connected with a stream-display device. The first processing module receives a source video. The control module is connected with the first processing module, and the control module is configured to receive an effect-previewing command. The second processing module is connected with the control module and a previewing display device. The control module sends the effect-previewing command to the second processing module. The second processing module is configured to attach a video effect corresponding to the effect-previewing command to the source video. The stream-display device shows the source video, and the previewing display device shows a previewing video, wherein the previewing video includes the video effect which is attached on the source video and which is corresponding to the effect-previewing command.

Abstract: According to one exemplary embodiment, a parallel scheduling method for network data transmission is provided. This method generates a corresponding modulus condition set for each weight in a weight set, with each modulus condition of the modulus condition set having a modulus operation, and a divisor and a remainder for the modulus operation, uses a network node to transmit the modulus condition set corresponding to said each weight to a transmitting node corresponding to the weigh. Based on the modulus condition set, the transmitting node transmits a plurality of data chunks, and at least one receiving node receives the plurality of data chunks, wherein each data chunk corresponding to a sequence number, and the sequence number matches a corresponding modulus condition in the modulus condition set.

Abstract: The present disclosure provides a monitoring method, an electronic device and a non-transient computer readable recording medium. The monitoring method includes the following steps: obtaining an instant sensing signal via an acceleration sensor; converting the instant sensing signal into at least one sensing parameter; and when the at least one sensing parameter satisfies one of the parameter determining rules, determining that the electronic device is in the current state defined correspondingly by the satisfied one of the parameter determining rules.

Abstract: According to one exemplary embodiment, a parallel scheduling method for network data transmission is provided. This method generates a corresponding modulus condition set for each weight in a weight set, with each modulus condition of the modulus condition set having a modulus operation, and a divisor and a remainder for the modulus operation, uses a network node to transmit the modulus condition set corresponding to said each weight to a transmitting node corresponding to the weigh. Based on the modulus condition set, the transmitting node transmits a plurality of data chunks, and at least one receiving node receives the plurality of data chunks, wherein each data chunk corresponding to a sequence number, and the sequence number matches a corresponding modulus condition in the modulus condition set.