The present disclosure relates to systems and methods for deploying enterprise systems in cloud environments. In one implementation, a system for deploying an enterprise system in a cloud environment may include at least one processor configured to provide: one or more first containers hosting at least one application with at least one enterprise function; one or more second containers hosting at least one microservice configured to activate the at least one enterprise function; at least one application programming interface (API) between the at least one microservice and at least one client; and at least one gateway configured to manage access to the at least one API.

In one embodiment, a method includes determining a first configuration information for configuring a user plane device of the first network slice associated with the control plane device, generating a first configuration identifier based on the first configuration information, sending, to the user plane device of the first network slice, the first configuration identifier and the first configuration information, receiving, from the user plane device of the first network slice, a second configuration identifier, wherein the second configuration identifier is generated by the user plane device of the first network slice based on the first configuration information received from the control plane device, and verifying, by comparing the first configuration identifier and the second configuration identifier, that the user plane device of the first network slice is configured using the first configuration information.

Devices, systems, and processes for rapid installation of numerous Internet-of-Things (IoT) devices are described. For at least one embodiment, a system for installing multiple Internet-of-Things (IoT) devices may include a multi-device hub communicatively coupled to each of multiple IoT devices. One or more gateways are coupled to the multi-device hub. One or more IoT servers are coupled to at least one of the one or more gateways. The multi-device hub is configured to facilitate a bulk installation of the multiple IoT devices by executing non-transient computer instructions for registering and activating each of the IoT devices with use with one or more IoT servers.

The present embodiments relate to an information processing method, a network node, an authentication method, and a server. In one embodiment, a method includes generating a virtual access node corresponding to a first access node on a central node in response to determining that no virtual access node corresponding to the first access node currently exists on the central node; obtaining, by the virtual access node on the central node, configuration information related to the first access node; and sending, by the virtual access node to the first access node, the configuration information related to the first access node, after the first access node goes online.

Various embodiments of a system and associated method for steering gene regulatory networks, among other network types, to a desired attractor state are disclosed herein. In one embodiment, the method involves identifying duplicative nodes and iteratively simulating effects of duplicated nodes on the network to steer the network to a target attractor state.

A system includes: a holder having a plurality of bays each configured to support a respective one of a plurality of electronic devices, and a notification assembly associated with the plurality of bays; a computing device connected with the holder and having a processor configured to: obtain an operator identifier, obtain status information for each of the plurality of electronic devices, based on the status information, select one of the plurality of electronic devices; and send, to the holder, an identifier of the selected electronic device and a configuration profile corresponding to the operator identifier; wherein the holder is configured, in response to receipt of the identifier of the selected electronic device and the configuration profile, to: deploy the configuration profile to the selected electronic device via a corresponding one of the bays, and activate the notification assembly to indicate the corresponding one of the bays to the operator.

Some embodiments provide a system for implementing a logical network that includes a set of end machines, a first logical middlebox, and a second logical middlebox connected by a set of logical forwarding elements. The system includes a set of nodes. Each of several nodes includes (i) a virtual machine for implementing an end machine of the logical network, (ii) a managed switching element for implementing the set of logical forwarding elements of the logical network, and (iii) a middlebox element for implementing the first logical middlebox of the logical network. The system includes a physical middlebox appliance for implementing the second logical middlebox.

Some embodiments provide a method for a network controller that manages multiple managed forwarding elements (MFEs) that implement multiple logical networks. The method stores (i) a first data structure including an entry for each logical entity in a desired state of the multiple logical networks and (ii) a second data structure including an entry for each logical entity referred to by an update for at least one MFE. Upon receiving updates specifying modifications to the logical entities, the method adds separate updates to separate queues for the MFEs that require the update. The separate updates reference the logical entity entries in the second data structure. When the second data structure reaches a threshold size in comparison to the first data structure, the method compacts the updates in at least one of the queues so that each queue has no more than one update referencing a particular logical entity entry.

The present disclosure relates to systems and methods for deploying enterprise systems in cloud environments. In one implementation, a system for deploying an enterprise system in a cloud environment may include at least one processor configured to provide: one or more first containers hosting at least one application with at least one enterprise function; one or more second containers hosting at least one microservice configured to activate the at least one enterprise function; at least one application programming interface (API) between the at least one microservice and at least one client; and at least one gateway configured to manage access to the at least one API.

Example methods and computer systems for cloud environment configuration based on task parallelization. One example method may comprise: obtaining a task data structure specifying execution dependency information associated with a set of multiple configuration tasks that are executable to perform cloud environment configuration. The method may also comprise: In response to identifying a first configuration task and a second configuration task that are ready for execution based on the task data structure, triggering execution of the first configuration task and the second configuration task. The method may further comprise: in response to determination that the first configuration task has been completed, identifying third configuration task(s) that are ready for execution based on the task data structure; and triggering execution of the third configuration task(s) by respective third compute node(s).