Abstract: A peony stamen-dodder composite, which is prepared from 10-18 parts by weight of peony stamen and 5-12 parts by weight of dodder. In the preparation process, the peony stamen is sequentially subjected to desensitization, impregnation with a saline and drying, and the dodder is impregnated with a saline and baked. The pre-treated peony stamen and dodder are crushed, impregnated in warm water, ultrasonicated and filtered, and the filter residue is added with water, ultrasonicated and filtered. The filtrates are combined and concentrated under vacuum to obtain the desired composite. This application further provides an application of the composite in the treatment of nephritis.

Abstract: A peony stamen-dodder composite, which is prepared from 10-18 parts by weight of peony stamen and 5-12 parts by weight of dodder. In the preparation process, the peony stamen is sequentially subjected to desensitization, impregnation with a saline and drying, and the dodder is impregnated with a saline and baked. The pre-treated peony stamen and dodder are crushed, impregnated in warm water, ultrasonicated and filtered, and the filter residue is added with water, ultrasonicated and filtered. The filtrates are combined and concentrated under vacuum to obtain the desired composite. This application further provides an application of the composite in the treatment of nephritis.

Abstract: Provided are a 2-(aryl-2-yl) morpholine and a deuterated derivative thereof, a preparation method therefor and an application thereof. In particular, involved are the use of a compound shown by general formula (V) in the treatment of central nervous system diseases, a deuterated compound thereof, a preparation method of deuterated compound, a pharmaceutical composition containing the deuterated compound, and the use thereof as a TAAR1 agonist in the treatment of central nervous system diseases.

Abstract: The disclosure describes methods and systems for training and deploying a machine learning predictive model for use in a semiconductor manufacturing process. Specifically, the present disclosure provides for training machine learning predictive models for manufacturing components using design data, process parameters, gas flow configurations from a pixelated showerhead, temperature profile across an electrostatic chuck, and measured uniformity profiles of processed wafers. The present disclosure also provides for deploying the machine learning predictive model to effectuate real-time adjustments to a manufacturing process.

Abstract: The present disclosure relates to absorbent articles having elastic laminates in front and/or back waist regions with high-stretch zones and low-stretch zones.

Abstract: Disclosed are a display module and a manufacturing method therefor. The display module comprises: a substrate provided with an LED chip; an encapsulating layer for encapsulating the LED chip, wherein the encapsulating layer covers the substrate and the LED chip, and an ink color layer, which covers the encapsulating layer, wherein the surface roughness of the side of the ink color layer that faces away from the encapsulating layer is Ra<1 micron, and Rz<2 microns.

Abstract: This application provides a wireless charging circuit and system, an electronic device, and a control method, and relates to the field of wireless charging technologies, to alleviate a problem of small charging power of an electronic device having a wireless reverse charging function. In the wireless charging circuit, a first voltage conversion circuit converts a supply voltage into a first battery voltage of a first battery, to charge the first battery. The first voltage conversion circuit further outputs the first battery voltage provided by the first battery. A second voltage conversion circuit boosts the first battery voltage. The second voltage conversion circuit includes a first boost circuit and at least one stage of switched-capacitor direct current converter that are connected in series. A first alternating current/direct current conversion circuit converts a direct current voltage output by the second voltage conversion circuit into an alternating current voltage.

Abstract: This application relates to a roller device. The device comprises: a roller; and a roller axle, the roller axle comprises: an axle portion configured to mount the roller such that the roller is rotatable about the axle portion; and a riveting portion at a mounting end of the roller axle with respect to an axial direction of the roller axle, and extending from the mounting end in a direction away from the axle portion, wherein, when the roller device is pressed against a carrier under force, the riveting portion can pierce the carrier such that the roller axle is riveted with the carrier through the riveting portion.

Abstract: Provided are a display module and a manufacturing method therefor, an LED display panel and an LED display apparatus. The display module includes a board, a pixel unit array, an encapsulation layer and a black ink layer. The board has a front surface and a back surface. The pixel unit array is disposed on the front surface of the board. The encapsulation layer covers the region where the pixel unit array is located. A side surface of the encapsulation layer forms a slope surface at an edge of the front surface of the board. The black ink layer covers the encapsulation layer.

Abstract: This application is directed to intra-panel communication in a touch display device in which a touch-integrated timing controller (TTCON) is coupled to touch-embedded source drivers (TSDs) via a plurality of forward links and a set of backward links. The forward links include a first subset of display forward links and a second subset of touch forward links. The TSDs are electrically coupled to a display panel including a plurality of display pixels and a plurality of touch sensors. The TTCON sends a display drive signal including display content data and display control data over the display forward links, and sends a touch control signal including an instruction to initiate an operation mode over the touch forward links. Upon receiving the touch control signal, the TSDs identify the instruction to initiate the operation mode, generate touch data accordingly, and return the touch data to the TTCON via the backward links.

Abstract: An apparatus for providing fast-settling quadrature detection and correction includes: a quadrature correction circuit that receives four quadrature clock signals; a quadrature detector that selects two clock signals among the four quadrature clock signals; and a phase digitizer that generates a digital code indicating a phase difference between the two clock signals. The quadrature correction circuit adjusts a phase between the two clock signals using the digital code.

Abstract: This application is directed to intra-panel communication in a touch display device in which a touch-integrated timing controller (TTCON) is coupled to touch-embedded source drivers (TSDs) via a plurality of forward links and a set of backward links. The forward links include a first subset of display forward links and a second subset of touch forward links. The TSDs are electrically coupled to a display panel including a plurality of display pixels and a plurality of touch sensors. The TTCON sends a display drive signal including display content data and display control data over the display forward links, and sends a touch control signal including an instruction to initiate an operation mode over the touch forward links. Upon receiving the touch control signal, the TSDs identify the instruction to initiate the operation mode, generate touch data accordingly, and return the touch data to the TTCON via the backward links.

Abstract: A compact gas-gas heat exchange tube. The heat exchange tube includes a heat transfer tube which is configured to separate an in-tube fluid from an out-tube fluid, and achieve, through convection and heat conduction manners, heat transfer between the in-tube fluid and the out-tube fluid; an inner fin set which is configured to expand a heat exchange surface on an inner side of the heat transfer tube, form a micro-channel to separate the in-tube fluid to make the same to axially flow along the heat transfer tube, and produce a turbulence effect and enhance heat convection as well; an outer fin set which is configured to expand a heat exchange surface on an outer side of the heat transfer tube, form a micro-channel to restrict the out-tube fluid from axially and reversely flowing along the heat transfer tube, and produce a turbulence effect and enhance heat convection as well, wherein a hole is provided on each fin of the inner fin set or/and the outer fin set.

Abstract: A finned heat exchanger tube, including a tube, a plurality of fins, and a plurality of outer casings. The tube includes an elongated hollow body having a wall. The plurality of fins is disposed on the wall of the tube along the longitudinal axis of the tube; the plurality of fins each includes a plurality of hollow protrusions, and corresponding hollow protrusions of the plurality of fins form a plurality of microchannels parallel to the longitudinal axis of the tube. The plurality of outer casings encircles the plurality of fins, respectively.

Abstract: A synchronized I/Q detection circuit is provided. A first subset of input signals and, subsequently, a second subset of input signals are provided by a first multiplexer and received by a first phase detector. Outputs of the first phase detector are receiving, by a first reset and sampling circuit. A second set of input signals are provided by a second multiplexer and received by a second phase detector, from a second multiplexer, while the first multiplexer receives the first and second subsets of input signals. The first subset of input signals has a same phase order as the second set of input signals, and the second subset of input signals has a different phase order than the second set of input signals. Outputs of the second phase detector are received by a second reset and sampling circuit. A comparator outputs a detected phase difference based on the outputs of the first and second reset and sampling circuits.