Disclosed is a battery management system (BMS) having a data processing unit for classifying data received in real time from a plurality of slave BMS to be first data if the data is determined to be data to be urgently transmitted based on preset criteria and classifying the received data to be second data if the data is determined not to be urgently transmitted, a first data transmission unit for transmitting the first data to a higher-level system using a first communication protocol, a second data storage unit for storing the second data cumulatively, and a second data communication unit for transmitting the second data stored in the second data storage unit to the higher-level system using a second communication protocol different from the first communication protocol.

Non-limiting examples of the present disclosure relate to generation and implementation of a new security protocol that is used to secure common data access transactions across distributed network examples. An exemplary proof of verification protocol is disclosed that implements consensus security mechanisms across a plurality of distributed nodes, which may be utilized to validate owners of data in common data access transactions. Extending principles of blockchain security to common data access transactions and Internet of Things (IoT) networking requires a solution that: improves speed in transactional processing; reduces computational complexity; and presents efficient, secure and repeatable validation for owners of data in distributed networking environments. An exemplary proof of verification protocol provides such technical advantages by validating both user-specific data for a subscriber of an application/service and session data for user activity (past and present) within the application/service.

A unidirectional transfer protocol allows data to be transmitted from a non-secure network into a secure network. A non-secure gateway may receive data and/or information, intended for the secure network, from one or more devices. The gateway may fragment the data and/or information into smaller chunks and transmit the chunks to a secure gateway via a unidirectional communication channel. The secure gateway may verify the chunks using one or more rules and reassemble the chunks when the data is validated. The reassembled data may be sent across a secure network enclave. The unidirectional transfer protocol may provide a hardware-agnostic solution for transmitting data over a unidirectional communication channel.

Systems and methods are provided for enhancing diagnosis of control logic by automatically triggering latent or quiescent diagnostic logic in response to a CAN bus signal and without requiring a software update of the control logic. The diagnostic logic may be triggered to provide an increase in the frequency of CAN messages that are generated. The diagnostic logic may be further triggered to provide a generation of additional CAN messages reporting operation signals beyond those that are normally generated. The diagnostic logic may be further triggered to provide higher priority to selected CAN messages reporting operation signals. The diagnostic logic may be still further triggered to one or more of increase the frequency of selected CAN report messages, generate additional CAN messages reporting operation signals beyond those that are normally generated, and/or provide higher priority to selected CAN messages reporting operation signals, each without requiring a software update.

A method for continuous data transfer is provided. Data blocks are generated from a continuous data stream captured via a physiological monitoring device by segmenting data from the continuous data stream into the data blocks. A time at which the data associated with each data block occurs is determined and a sample number is associated with each data block. The data blocks are transmitted from the physiological monitoring device to a server. The data blocks are ordered on the server based on the time and the sample number associated with each data block.

By analyzing the apps on a portable computing device 500, the communication modes used by the portable computing devices 500 and the communication requirements of the apps at a given time, an ideal communication mode given a certain mix of apps operating on a portable computing device 500 at a given point in time may be determined.

A client application can be configured to render user interface cards, based on card data provided by a remote card engine. An API Response as Card (ARC) engine can intercept a communication between the client application and the card engine, and determine that the communication is associated with another backend system. The ARC engine can request that the backend system perform an account action associated with a user account. The ARC engine can provide information derived from a response from the backend system, reflecting a result of the account action, to the card engine. The card action can generate card data associated with the result of the account action performed by the backend system, and the client application can use the card data to render and display a corresponding card, even if neither the client application nor the card engine are natively configured to interface with the backend system.

An information handling system includes a data handling device and a baseboard management controller (BMC). The data handling device includes a co-processor configured to instantiate a device operating system for the data handling device. The data handling device includes a Management Component Transport Protocol (MCTP) endpoint. The BMC establishes a serial terminal session with the device operating system via the MCTP endpoint.

The present invention relates to an integrated management system for heterogeneous logistics automation equipment, including: an equipment standard protocol server adapted to receive commands from a plurality of warehouse management systems (WMS), to check equipment standard protocol identification (ESP ID) matching the received commands, and to produce work information in the form of telegram: a plurality of warehouse control systems (WCS) adapted to control the logistics automation equipment through the work information produced from the equipment standard protocol server; and a plurality of equipment control systems (ECS) adapted to receive the work information from the plurality of warehouse control systems (WCS) to control the logistics automation equipment.

A network device configured to perform scalable, in-network computations is described. The network device is configured to process pull requests and/or push requests from a plurality of endpoints connected to the network. A collective communication primitive from a particular endpoint can be received at a network device. The collective communication primitive is associated with a multicast region of a shared global address space and is mapped to a plurality of participating endpoints. The network device is configured to perform an in-network computation based on information received from the participating endpoints before forwarding a response to the collective communication primitive back to one or more of the participating endpoints. The endpoints can inject pull requests (e.g., load commands) and/or push requests (e.g., store commands) into the network. A multicast capability enables tasks, such as a reduction operation, to be offloaded to hardware in the network device.