Abstract: The present application provides an atomicity retaining method and a processor, and an electronic device. The method includes: generating N load/store operations from a vector load/store instruction, where N is a positive integer greater than or equal to 1; detecting whether there is an event during processing of the N load/store operations that renders the vector load/store instruction non-atomic; processing the N load/store operations; in a case that there is the event that renders the vector load/store instruction non-atomic, having none of the processing of the N load/store operations produce any processing effect, or having the N load/store operations all produce processing effects. The present application can realize retaining the atomicity of vector instructions.

Abstract: A reservation station that includes a storage circuit with multiple full and partial entries is disclosed. A given store-data entry of the multiple partial entries may store less data than a given full entry of the multiple full entries. A control circuit may receive a load/store operation and, in response to a determination that the load/store operation includes only a single source, store the load/store operation in a particular partial entry of the multiple partial entries.

Abstract: A storage device is disclosed. The storage device may include at least one controller for a virtual machine (VM) that is on a source host. Storage in the storage device may store data for the VM. A second storage may store a storage state for the VM. A storage device controller may process at least one read request received from the controller for the VM using the first storage and at least one write request received from the controller for the VM using the first storage. A VM migration state monitor and capture module may assist in the migration of the VM from the source host to a destination host.

Abstract: A method for a Matter compute architecture with smart discovery and opportunistic allocation of IoT device resources includes obtaining a device identifier for each of a plurality of devices within an ecosystem of a vehicle, each device identifier including resource capabilities and resource needs of the device. For each device, the method also includes validating the device based on the obtained device identifier, and classifying the device based on the resource capabilities and the resource needs of the device. The method also includes generating a device controller matrix by identifying an ecosystem resource requirement for the plurality of devices, predicting an ecosystem resource availability for the plurality of devices, and prioritizing the resource capabilities and the resource needs of each device based on the ecosystem resource requirement and the ecosystem resource availability.

Abstract: A method including initiating a computing process on a wearable device, the computing process including a plurality of tasks, identifying a first companion device and determining that the first companion device is available to perform at least one task of the plurality of tasks, identifying a second companion device and determining that the second companion device is available to perform at least one task of the plurality of tasks, causing the first companion device to perform a first task of the plurality of tasks including communicating data generated by the wearable device to the first companion device, causing the second companion device to perform a second task of the plurality of tasks, and receiving, by the wearable device from the first companion device, a result associated with a completion of the first task and the second task.

Abstract: The present invention relates to a system and a method implemented by an intelligent module. The system comprises an interface, an artificial intelligence module, and an intelligent flow framework module. The intelligent flow framework module is communicatively coupled to the interface and the artificial intelligence module. The intelligent flow framework module is configured to define at least one task based on an event and contextual data for completing a mission. The system provides the ability to adapt quickly to changing circumstances and make intelligent decisions to ensure the successful completion of missions/objectives.

Abstract: Embodiments of this application provide a chip system and a collective communication method, and relate to the field of chip technologies. A specific solution is: The chip system includes a processor core, a task scheduler, and a first accelerator. The processor core is configured to: orchestrate all tasks of collective communication in an expected execution sequence, to obtain an orchestrated execution sequence of the tasks, and deliver the orchestrated execution sequence of the tasks and a synchronization task to the task scheduler, where the synchronization task is used to control the orchestrated execution sequence of the tasks. The task scheduler is configured to: schedule the tasks to the first accelerator in the orchestrated execution sequence of the tasks, and control the orchestrated execution sequence of the tasks based on the synchronization task. The first accelerator is configured to execute the tasks in the orchestrated execution sequence of the tasks.

Abstract: A configurable logic platform may include a physical interconnect for connecting to a processing system, first and second reconfigurable logic regions, a configuration port for applying configuration data to the first and second reconfigurable logic regions, and a reconfiguration logic function accessible via transactions of the physical interconnect, the reconfiguration logic function providing restricted access to the configuration port from the physical interconnect. The platform may include a first interface function providing an interface to the first reconfigurable logic region and a second interface function providing an interface to the first reconfigurable logic region. The first and second interface functions may allow information to be transmitted over the physical interconnect and prevent the respective reconfigurable logic region from directly accessing the physical interconnect.

Abstract: The present application provides a current collector, a secondary battery and a power consuming device. The current collector is divided into a first region and a second region, wherein the first region is in contact with the second region, and the first region has an elastic modulus greater than that of the second region.

Abstract: A fuel cell system includes: a plurality of fuel cell stacks; an oxidizing gas supply unit including a turbo compressor that supplies an oxidizing gas to each of the fuel cell stacks; a cooling unit that cools each of the fuel cell stacks; and a control device that determines, according to the requested output, a requested number of fuel cell stacks to be operated out of the fuel cell stacks, a target supply pressure of the oxidizing gas and a target supply flow rate of the oxidizing gas that are to be sent as a command to the oxidizing gas supply unit, and a target cooling temperature of the fuel cell stacks that is to be sent as a command to the cooling unit. The control device reduces the target cooling temperature when reducing the requested number of fuel cell stacks to be operated.

Abstract: A lithium secondary battery includes a positive electrode, a separator, and a negative electrode, wherein the negative electrode includes a silicon-based active material and wherein a resistance ratio represented by Equation 1 is 100% to 140%.

Abstract: Disclosed herein are compositions and methods for enhancing the ionic conductivity of a solid polymer electrolyte which comprise incorporating an additive that comprises at least one fluorinated sulfonamide compound selected from the group consisting of formulae (1) to (5) into the polymer matrix: and

Abstract: The present disclosure provides a laminated battery that has both reduced moisture deterioration and improved volumetric energy density. A laminated battery of the disclosure comprises a stack and a sealing material. A laminated battery of the disclosure has at least part of the stack, other than one outermost current collector, encapsulated by one outermost current collector through a sealing material, and has one outermost current collector covering the stack other than at one current collector, so that at least part of the outer perimeter edge of the other outermost current collector is covered by a sealing material. In other words, the other outermost current collector has at least part of a side where the active material is not stacked, which extends from at least part of the outer perimeter edge of the other outermost current collector, covered by one outermost current collector via the sealing material.

Abstract: A solid-state secondary battery according to one embodiment of the present invention includes an electrode laminate that includes a positive electrode layer including a positive electrode active material layer, a solid electrolyte layer, an intermediate layer, and a negative electrode layer, each of the positive electrode layer, the solid electrolyte layer, the intermediate layer, and the negative electrode layer being joined to an adjacent layer, in which a composite modulus of elasticity of each layer of the positive electrode active material layer, the solid electrolyte layer, the intermediate layer, and the negative electrode layer in the electrode laminate satisfies a relationship of intermediate layer<negative electrode layer<solid electrolyte layer<positive electrode active material layer.

Abstract: ECU performs a process including the steps of acquiring a resistance value of an insulation resistance, determining that a resistance value is equal to or less than a threshold value, determining that an electric leakage occurs on the vehicle body side, turning on a SMR when the resistance value is greater than the threshold value, acquiring a resistance value of the insulation resistance, determining that an electric leakage occurs on the battery pack side when the resistance value is equal to or less than the threshold value, and determining that there is no electric leakage when the resistance value is greater than the threshold value.

Abstract: A vehicle control device and a method thereof are provided. The vehicle control device includes a plurality of battery cells, a processor, and a memory. The processor is configured to identify first time constants of each of the battery cells, when a vehicle maintains a no-load state during a specified time, obtains a comparison dataset indicating a difference between an average value for the first time constants and each of the first time constants, and diagnoses a state of each of the battery cells, using the comparison dataset.

Abstract: The embodiments of the present application provide a method, apparatus and system for thermal runaway processing and a storage medium. The method first obtains a battery parameter for each of a plurality of battery modules in a power battery pack, then determines that a thermal runaway is occurred in a first battery module based on the battery parameter for each of the plurality of battery modules; and then obtains a second battery module based on the first battery module, wherein the second battery module corresponds to at least one battery module excluding the first battery module in the power battery pack; and finally supplies power to a chiller system with the second battery module.

Abstract: An immersion cooling system for a battery of an electric vehicle. The immersion cooling system includes an incompatible fluid detection system configured to detect a presence of an incompatible fluid within a fluid circuit of the immersion cooling system. The incompatible fluid can include a non-dielectric fluid that has entered or accumulated within the fluid circuit, as well as a dielectric fluid that has been contaminated or is reaching, if not already attained, an end-of-life for the dielectric fluid. In response to a determination of a presence of the incompatible fluid in the fluid circuit, a notification can be generated to alert an operator of the detection of the incompatible fluid. Additionally, the system can take actions, including closing a valve(s), deactivating a pump, and/or opening a bypass circuit(s), among other actions, to isolate at least the battery from the incompatible fluid.

Abstract: A cooling assembly for a battery system includes an inlet system. The inlet system includes an inlet manifold, an inlet connecting tube, a first inlet connecting member defining a first surface and at least one first inlet fluid port, and a second inlet connecting member defining at least one second inlet fluid port in fluid communication with the at least one first inlet fluid port of the first inlet connecting member. The cooling assembly also includes an outlet system in fluid communication with the inlet system. The outlet system includes an outlet manifold, a first outlet connecting member defining at least one first outlet fluid port, an outlet connecting tube, and a second outlet connecting member defining at least one second outlet fluid port.

Abstract: The disclosure provides a battery core, a case body, a battery module, and a battery pack. The battery core provided by the disclosure includes the following. A case body is provided, and the case body has side surfaces and a bottom surface connected to each other. A composite layer includes a shear resistant layer and a connection layer. The shear resistant layer is connected to the case body through the connection layer. At least one of the shear resistant layer and the connection layer is an insulation layer, and the composite layer covers at least one of at least part of the side surfaces and at least part of the bottom surface. The battery core provided by the disclosure can ensure the shear strength of the composite layer covering the surface of the battery core, thereby the reliability of the battery core during use is improved.