Techniques are described for enabling users of a service provider network to create and configure “application profiles” that include parameters related to execution of user workloads at provider substrate extensions. Once an application profile is created, users can request the deployment of user workloads to provider substrate extensions by requesting instance launches based on a defined application profile. The service provider network can then automate the launch and placement of the user's workload at one or more provider substrate extensions using edge-optimized compute instances (e.g., compute instances tailored for execution within provider substrate extension environments). In some embodiments, once such edge-optimized instances are deployed, the service provider network can manage the auto-resizing of the instances in terms of various types of computing resources devoted to the instances, manage the lifecycle of instances to ensure maximum capacity availability at provider substrate extension locations, and perform other instance management processes.

A durability assessment system may receive a request, from a computing system, for a durability index describing an entity. The durability assessment system may determine the durability index based on information about the resource usage by the entity, such as a resource availability score or a resource allocation score. The durability assessment system may compare the obtained resource availability score and resource allocation score to ranges associated with a set of durability indices. Based on the comparison, the durability assessment system may determine a durability index for the entity. The durability index may indicate an ability of the entity to return accessed resources. In some cases, the durability assessment system may provide the durability index to an allocation computing system that is configured to determine whether to grant access to resources based on the durability index.

A system for determining the servicing needs of a vehicle. In various embodiments, the system includes a remote server and a vehicle control module of the vehicle. The vehicle control module includes a first communication interface to enable communications with at least one vehicle device via a network fabric of the vehicle. The vehicle control module is configured to receive status data, from the vehicle device, relating to a performance status or operational status of the vehicle. The vehicle control module further includes a second communication interface that enables wireless communications with the remote server. The wireless communications include sending status data to the remote server. The remote server is configured to receive and interpret the status data to determine if the vehicle requires service, and send a response to the vehicle. When service is required, the response may cause the vehicle to provide a service indication.

An electrical computer system processing architecture for providing an indication of activity in the electrical computer system, the electrical computer system processing architecture comprising a plurality of client computers connected to at least one server by a computer network. Each of the client computers is configured to provide requests to the at least one server. The or each server comprises a store for storing requests provided by the plurality of client computers. The or each server is configured to match complementary requests from the plurality of client computers stored in the store. Following the matching of complementary requests, the or each server counts unmatched requests corresponding to one or other of the complementary requests in the store, and outputs the counted number of unmatched requests to provide the indication of activity in the computer system.

Methods, systems, and apparatus, including an apparatus for generating clusters of building blocks of compute nodes using an optical network. In one aspect, a method includes receiving request data specifying requested compute nodes for a computing workload. The request data specifies a target n-dimensional arrangement of the compute nodes. A selection is made, from a superpod that includes a set of building blocks that each include an m-dimensional arrangement of compute nodes, a subset of the building blocks that, when combined, match the target n-dimensional arrangement specified by the request data. The set of building blocks are connected to an optical network that includes one or more optical circuit switches. A workload cluster of compute nodes that includes the subset of the building blocks is generated. The generating includes configuring, for each dimension of the workload cluster, respective routing data for the one or more optical circuit switches.

A processing device includes processing circuitry and non-volatile storage configured to store management information that identifies supervisor-subordinate relationships among users. The processing circuitry receives a request from a first user, wherein the request includes a request to alter access rights of a second user to a network resource. The processing circuitry establishes authorization of the first user to request access to the network resource based on information included in a directory services database, and retrieves management information associated with the first user and the second user from the non-volatile storage. The processing circuitry determines whether a supervisor-subordinate relationship exists between the first user and the second user based on the management information associated with the first user and the second user, and alters the access rights of the second user to the network resource, at least partly in response to determining that the supervisor-subordinate relationship between the first user and the second user exists.

A communication method includes that a first network device generates indication information based on service usage of a first network slice and a service usage threshold of the first network slice, and sends the indication information to a second network device. The second network device controls resource pre-emption based on the indication information.

Management of immersive reality devices via a reduced competition core network component is disclosed. The reduced competition core network component can preferentially be reserved for immersive reality device data and can therefore exclude some or all other types of data typically associated with conventional wireless network devices, e.g., phone, tablet/laptop computers, IoT devices, etc. This can result in immersive reality data communication that does not have to compete with more generic data types for network or computing resources. Additionally, the reduced competition core network component can be divided into at least one reduced competition user-plane network component and at least one reduced competition control-plane network component. Use of a reduced competition user-plane network component can avoid generating additional carrier network traffic. Further, a reduced competition user-plane network component can facilitate non-carrier entity authentication, security protocols, etc. Hierarchical network component topology can enable rule-based access to computing and network resources.

Systems and methods for enabling links between various devices is provided. The systems and methods may include a platform that enables different devices to access spatial models of a resource. The platform may enable the different devices to define and/or modify assignment conditions for access rights to resources. Further, the platform may enable definition of assignment conditions before or after the access rights are available for assignment.

Technologies for dynamic allocation of network communication resources includes a resource manager server to allocate a set of network communication resources to a compute device through an expansion bus switch that is coupled to the compute device and to the network communication resources. The resource manager server obtains telemetry data indicative of a present utilization of the allocated set of network communication resources and determines whether the present utilization satisfies a predefined utilization threshold. Additionally, the resource manager server adjusts, through the expansion bus switch and in response to a determination that the present utilization does not satisfy the predefined utilization threshold, an amount of network communication resources in the set to the compute device.