Abstract: Embodiments of this specification disclose payment methods, apparatuses, and devices based on near field communication, and media. The solution includes: sending, by a mobile terminal with a near field communication function, an electromagnetic signal used to trigger an NFC tag; obtaining tag information in the NFC tag in response to the electromagnetic signal, where the tag information includes payment link information; displaying, based on the payment link information, a payment page including user information of a first transaction party; obtaining payment information provided by a second transaction party based on the payment page; and sending a payment processing request including the payment information to a server, where the server is configured to complete payment based on the payment processing request.

Abstract: An apparatus and method for direct drug infusion from a vial to a patient are provided. A movable hanger label is provided to adhere to and support the vial to facilitate direct infusion of a drug, such as one or more pharmaceuticals, biopharmaceuticals, and/or biologics, from the vial to the patient. Additionally, a process is provided in which the drug, contained in the vial with the movable hanger label, may be directly infused through a primed infusion line with a rapid infusion rate. A saline flush is incorporated at the end of the administration to flush the infusion line, resulting in a reduced amount of the drug remaining in the line.

Abstract: An apparatus and method for direct drug infusion from a vial to a patient are provided. A movable hanger label is provided to adhere to and support the vial to facilitate direct infusion of a drug, such as one or more pharmaceuticals, biopharmaceuticals, and/or biologics, from the vial to the patient. Additionally, a process is provided in which the drug, contained in the vial with the movable hanger label, may be directly infused through a primed infusion line with a rapid infusion rate. A saline flush is incorporated at the end of the administration to flush the infusion line, resulting in a reduced amount of the drug remaining in the line.

Abstract: Embodiments of this specification disclose a payment method based on near field communication, apparatus, and device, and a medium. The solution includes: sending, by a mobile terminal with a near field communication function, an electromagnetic signal used to trigger an NFC tag; obtaining tag information in the NFC tag in response to the electromagnetic signal, where the tag information includes payment link information; displaying, based on the payment link information, a payment page including user information of a first transaction party; obtaining payment information provided by a second transaction party based on the payment page; and sending a payment processing request including the payment information to a server, where the server is configured to complete payment based on the payment processing request.

Abstract: This disclosure pertains to methods to prepare coated particles comprising a drug-containing core and a coating of inorganic oxides applied by vapor phase deposition (supercycles). The coated particles have a modified drug release profile comparing to the uncoated drug particles.

Abstract: Disclosed are a micro-column gel card, and a sample adding mechanism and method. The micro-column gel card includes a fixing plate and a plurality of tubular columns (3) arranged and fixed through the fixing plate. The tubular columns (3) are fixed to two sides of the fixing plate respectively, and the tubular columns (3) located on the two sides of the fixing plate are arranged in a staggered manner. Each tubular column (3) includes a sample adding cavity (301), a reaction cavity (302), and a gel column (303). The gel column (303) is configured to load a gel reagent. A central axis of the sample adding cavity (301) and a central axis of the gel column (303) do not coincide. The tubular columns (3) are designed in a double-row staggered manner.

Abstract: A data caching and reading method, and a data access system are provided. A client sends a first request to a data storage system so as to obtain metadata of target data. The client sends a second request to a data caching system, the second request comprising the metadata. The data caching system determines, on the basis of the metadata, whether cache target data consistent with the target data stored in the data storage system is cached. When it is determined cache target data is cached, the client obtains the target data from the data caching system. When no consistent cache target data is cached, the client obtains the target data from the data storage system, and sends the obtained target data to the data caching system, so as to cache the target data.

Abstract: A storage system capable of executing data processing, includes the following elements. A first control unit of a storage device, for cooperating with a sequencer to perform a clustering process on a plurality of original sequences to obtain a plurality of read sequences, generating a plurality of read binary vectors corresponding to the read sequences, and generating a pruned filtering binary vector according to a reference sequence. A first storage module of the storage device, for storing the read binary vectors and the pruned filtering binary vector, and executing an in-memory computing (IMC) according to the read binary vectors and the pruned filtering binary vector, so as to generate a filtered cluster read set. A processing device, for executing an aligning process according to the filtered cluster read set and the reference sequence.

Abstract: Embodiments of this application disclose an application upgrade method. The method includes: obtaining upgrade information of an application, where the upgrade information includes a target operator, an operator identifier of the target operator, and an application identifier of the application; obtaining, based on a virtual address, a physical address allocated to the target operator, where the physical address is an address of storage space on a network interface card device; storing the target operator in the storage space corresponding to the physical address; and constructing a first mapping relationship based on the operator identifier, the application identifier, and the physical address, where the first mapping relationship is used as routing information of the target operator when the application is running.

Abstract: This application discloses a data transmission method and a device. The method includes: A sender endpiont constructes n streams through an interface provided by a QUIC protocol, and sets attribute information of the streams (or sets different attribute information for different data blocks in a same stream). The sender endpiont transfers the attribute information of the streams to a first network node by using a first extended frame (or transfers the attribute information of the different data blocks in the same stream by using a second extended frame). The first or second extended frame is a frame obtained by performing protocol extension on the QUIC protocol. After receiving the first or second extended frame, the first network node determines, according to a sending policy of the first network node, routing, caching, and distribution of a target data stream, and continues to deliver the attribute information.

Abstract: An adaptive sealing device for pipeline porous leakage. The device includes a pressure protection device and an encircling sealing rubber cover. The pressure protection device is used to pressurize and seal the pipeline by the encircling sealing rubber cover. The device further includes a control mechanism connected with the pressure protection device for adjusting the sealing pressure of the pressure protection device on the pipeline. The device further includes an anti-retraction mechanism connected with the pressure protection device and the control mechanism for limiting the pressure protection device and/or the control mechanism.

Abstract: This disclosure provides more effective and/or efficient techniques for detecting faults with physical components using an example of selectively causing output of light into a cover and capturing an image of the cover to determine whether the light is visible in the image. Some techniques are described herein for detecting misalignment of one or more physical components (e.g., a cover or a camera). Other techniques are described herein for detecting contaminants (e.g., substances at or near a surface of a physical component and/or a physical change to the physical component, such as a deformation or a crack of the cover) affecting data captured by a sensor.

Abstract: This disclosure provides more effective and/or efficient techniques for detecting faults with physical components using an example of selectively causing output of light into a cover and capturing an image of the cover to determine whether the light is visible in the image. Some techniques are described herein for detecting misalignment of one or more physical components (e.g., a cover or a camera). Other techniques are described herein for detecting contaminants (e.g., substances at or near a surface of a physical component and/or a physical change to the physical component, such as a deformation or a crack of the cover) affecting data captured by a sensor.

Abstract: This disclosure provides more effective and/or efficient techniques for detecting faults with physical components using an example of selectively causing output of light into a cover and capturing an image of the cover to determine whether the light is visible in the image. Some techniques are described herein for detecting misalignment of one or more physical components (e.g., a cover or a camera). Other techniques are described herein for detecting contaminants (e.g., substances at or near a surface of a physical component and/or a physical change to the physical component, such as a deformation or a crack of the cover) affecting data captured by a sensor.

Abstract: This disclosure provides more effective and/or efficient techniques for detecting faults with physical components using an example of selectively causing output of light into a cover and capturing an image of the cover to determine whether the light is visible in the image. Some techniques are described herein for detecting misalignment of one or more physical components (e.g., a cover or a camera). Other techniques are described herein for detecting contaminants (e.g., substances at or near a surface of a physical component and/or a physical change to the physical component, such as a deformation or a crack of the cover) affecting data captured by a sensor.

Abstract: This disclosure provides more effective and/or efficient techniques for detecting faults with physical components using an example of selectively causing output of light into a cover and capturing an image of the cover to determine whether the light is visible in the image. Some techniques are described herein for detecting misalignment of one or more physical components (e.g., a cover or a camera). Other techniques are described herein for detecting contaminants (e.g., substances at or near a surface of a physical component and/or a physical change to the physical component, such as a deformation or a crack of the cover) affecting data captured by a sensor.

Abstract: This disclosure provides more effective and/or efficient techniques for detecting faults with physical components using an example of selectively causing output of light into a cover and capturing an image of the cover to determine whether the light is visible in the image. Some techniques are described herein for detecting misalignment of one or more physical components (e.g., a cover or a camera). Other techniques are described herein for detecting contaminants (e.g., substances at or near a surface of a physical component and/or a physical change to the physical component, such as a deformation or a crack of the cover) affecting data captured by a sensor.

Abstract: This disclosure provides more effective and/or efficient techniques for detecting faults with physical components using an example of selectively causing output of light into a cover and capturing an image of the cover to determine whether the light is visible in the image. Some techniques are described herein for detecting misalignment of one or more physical components (e.g., a cover or a camera). Other techniques are described herein for detecting contaminants (e.g., substances at or near a surface of a physical component and/or a physical change to the physical component, such as a deformation or a crack of the cover) affecting data captured by a sensor.