Abstract: A display device includes: a substrate; two pixel circuits on the substrate spaced apart from each other with a transmission area therebetween, each of the two pixel circuits including a transistor and a storage capacitor; two display elements respectively electrically coupled to the two pixel circuits; a bottom metal layer between the substrate and the two pixel circuits and including a through hole at the transmission area; an encapsulation member on the two display elements; and an optical functional layer on the encapsulation member, wherein the optical functional layer includes: a first layer including a first opening, second openings, and a first slope portion, the first opening at the transmission area, the second openings corresponding to each of the two display elements, and the first slope portion being around the transmission area; and a second layer on the first layer.

Abstract: A coil component includes a body in which a coil portion is disposed, and external electrodes connected to the coil portion. The body includes metal particles formed of an Fe-based nanocrystal grain alloy, and the Fe-based nanocrystal grain alloy has one peak or two peaks in a differential scanning calorimetry (DSC) graph, and when the Fe-based nanocrystal grain alloy has the two peaks, a primary peak is smaller than a secondary peak, where the primary peak is at a lower temperature than the secondary peak.

Abstract: A communication method includes: sending, by a first device, a handover request message to a second device, and receiving a handover acknowledgement message returned by the second device, where the handover acknowledgement message carries common system information of the second device; sending, by the first device, a handover command to a terminal, where the handover command includes the common system information of the second device; sending, by the first device, a second message to the terminal based on a first message, so that the terminal obtains changed communications system information of the second device based on the second message, where the first message is sent by the second device, and the first message is used to indicate a change occurring in the common system information of the second device.

Abstract: Provided is a scroll compressor including a sealed case, a fixed scroll portion fixed at an inside of the sealed case and provided with a fixed scroll vane, an orbiting scroll portion provided with an orbiting scroll vane that is coupled to the fixed scroll vane, and a rotating shaft formed to allow the orbiting scroll portion to orbit. The orbiting scroll portion is provided at a center thereof with a shaft support portion such that the orbiting scrolling portion is coupled to the rotating shaft. The shaft support portion includes a closing portion provided to cover an end portion of the rotating shaft, and slide while in contact with an inner surface of the fixed scroll portion, and a high-pressure space formed in an outer surface of the closing portion that faces the inner surface of the fixed scroll portion, and on which a discharge pressure acts.

Abstract: The present invention relates to a communication system is provided, wherein the communication system comprising: a first communication unit, comprising a first communication processor for providing communication via a first channel, at least one second communication unit separate to the first communication unit, comprising a second communication processor for providing communication via a second channel, a coupling unit for coupling the first communication unit with the at least one second communication unit, wherein the first communication unit further comprises: a communication control unit coupled to the second communication unit via the coupling unit, wherein the communication control unit is configured to enable the mutual utilization of electronic resources between the first and second communication unit, and an encryption unit for providing encrypted communication via as well the first communication channel and the second communication channel.

Abstract: The present disclosure relates to a semiconductor structure. The semiconductor structure comprises a semiconductor layer, a first carbon nanotube, and a second carbon nanotube. The semiconductor layer comprises an N-type semiconductor layer and a P-type semiconductor layer stacked with each other. The first carbon nanotube is on a first surface of the semiconductor layer. The second carbon nanotube is on a second surface of the semiconductor layer. A first extending direction of the first carbon nanotube intersects with a second extending direction of the second carbon nanotube. At an intersection of the first carbon nanotube and the second carbon nanotube, and in a direction perpendicular to the semiconductor layer, a multilayer structure is formed by an overlapping region of the first carbon nanotube, the semiconductor layer, and the second carbon nanotube.

Abstract: The present subject matter refers a method for training image-alignment procedures in a computing environment. The method comprises communicating one or more images of an object to a user and receiving a plurality of user-selected zones within said one or more through a user-interface. An augmented data-set is generated based on said one or more images comprising the user-selected zones, wherein such augmented data set comprises a plurality of additional images defining variants of said one or more communicated images. Thereafter, a machine-learning based image alignment is trained based on at-least one of the augmented data set and the communicated images.

Abstract: The method for correcting brightness of a display panel includes: starting a brightness correction process according to a brightness correction starting instruction; obtaining a first curve representing a relationship between absolute values of input voltages of the transparent display area and light emitting brightness values of the transparent display area in a current state; recording the first curve as a relationship curve showing a relationship between absolute values of input voltages and light emitting brightness values of the transparent display area for correcting brightness; and adjusting an input voltage of the transparent display area according to the first curve, so that a front-side light emitting brightness value of the transparent display area is consistent with a light emitting brightness value of the non-transparent display area.

Abstract: A semiconductor package includes a base substrate, a first semiconductor chip on the base substrate, a dam structure on the base substrate and surrounding the first semiconductor chip, a second semiconductor chip on the first semiconductor chip, a non-conductive film, and a molding member. The non-conductive film may be between the base substrate, the first semiconductor chip, and the second semiconductor chip. The molding member may cover the base substrate, the first semiconductor chip, and the second semiconductor chip. A level of an upper surface of the first semiconductor chip and a level of an upper surface of the dam structure may be at a same level.

Abstract: A battery and a manufacturing method thereof are provided. The battery module includes: a battery cell group, in which a plurality of battery cells is laminated; a pair of end plates, which is arranged on two end portions of the battery cell group; and restraint members, which are disposed over the pair of end plates and restrain the battery cell group between the pair of end plates. The restraint members are coupled by grappling structures to the pair of end plates on two end portions along the lamination direction the battery cells, and the pair of end plates clamps the battery cell group in a state that the battery cell group is compressed and pulling forces toward opposite directions act on the two end portions of the restraint members by a restoration force when the battery cell group restores from the compression state.

Abstract: Embodiments of ferroelectric memory devices and methods for forming the ferroelectric memory devices are disclosed. In an example, a ferroelectric memory cell includes a first electrode, a second electrode, a ferroelectric layer disposed between the first electrode and the second electrode, and a recess between a side surface of at least one of the first electrode or the second electrode and a side surface of the ferroelectric layer.

Abstract: Provided is a method for implementing a theme, which includes: comprising, by the terminal, at least one theme, and at least one application related to the at least one theme; and displaying the at least one application related to the theme on the terminal, when the theme is switched to. The present disclosure further provides a method for implementing a theme applied to a mobile terminal. The present disclosure may provide themes corresponding theme according to the requirements of special groups, greatly enhancing the user experience.

Abstract: A modulated magnetoresistive sensor consists of a substrate located on a substrate in an XY plane, magnetoresistive sensing elements, a modulator, electrical connectors, an electrical insulating layer, and bonding pads. The sensing direction of the magnetoresistive sensing elements is parallel to the X axis. The magnetoresistive sensing elements are connected in series into a magnetoresistive sensing element string. The modulator is comprised of multiple elongated modulating assemblies. The elongated modulating assemblies consist of three layers—FM1 layer, NM layer, and FM2 layer. The ends of the elongated modulating assemblies are electrically connected to form a serpentine current path. The electrical insulating layer is set between the elongated modulating assemblies and the magnetoresistive sensing elements to separate the elongated modulating assemblies from the magnetoresistive sensing elements.

Abstract: An element chip manufacturing method including: preparing a semiconductor substrate including a first layer having a first principal surface, and a second layer having a second principal surface, the first layer provided with element regions, a dicing region, and an alignment mark, wherein the first layer includes a semiconductor layer, and the second layer includes a metal layer adjacent to the semiconductor layer; irradiating a first laser beam absorbed in the metal film and passing through the semiconductor layer, from the second principal surface side to a first region corresponding to the mark; imaging the semiconductor substrate from the second principal surface side with a camera, and then calculating a second region corresponding to the dicing region on the second principal surface; irradiating a second laser beam to the second region from the second principal surface side; and dicing the semiconductor substrate into a plurality of element chips.