Techniques are provided for recommending hardware configuration changes using a user satisfaction rating. One method comprises obtaining usage data indicating user activity for users on computing devices; generating a user profile for each user; clustering the users into user clusters based on the user profiles; determining, for a given user cluster, a satisfaction score for each user in the given user cluster based on the obtained usage data for each user on the computing device; providing suggested hardware upgrades for the computing device of a given user in the given user cluster, wherein the given user is selected based on a lower corresponding satisfaction score relative to the satisfaction scores of other users in the given cluster, and wherein the one or more suggested hardware upgrades are based on hardware configurations of other users in the given cluster having a higher corresponding satisfaction score.

A system and method for extensible, protective, and verifiable automated issue remediation for information technology infrastructure comprises invoking an application programming interface to obtain at least one issue object corresponding to an alert generated by a monitoring system; matching the issue object to at least one diagnosis plugin of a plurality of diagnosis plugins; obtaining a prescription object from the diagnosis plugin, the prescription object comprising a remedy; and invoking the remedy after verifying the remedy is authorized to proceed.

Some embodiments provide a managed network for implementing a logical network for a tenant. The managed network includes a first set of host machines and a second set of host machines. The first set of host machines is for hosting virtual machines (VMs) for the logical network. Each of the first set of host machines operates a managed forwarding element that implements a first logical router for the tenant logical network and a second logical router to which the first logical router connects. The implementation of the second logical router is for processing packets entering and exiting the tenant logical network. The second set of host machines is for hosting L3 gateways for the second logical router. The L3 gateways connect the tenant logical network to at least one external network.

A setup control unit is configured to get activated via a first computer that is to become a node in the process control system and which activation is initiated by a setup tool being brought to the first computer. The setup control unit contacts a configuration control computer, supplies a setup tool identifier to the configuration control computer, accesses system information elements in the configuration control computer, presents system nodes to an operator using the system information elements, receives an operator selection of a system node, sends the node selection to the configuration control computer for registering, based on a setup tool identifier investigation, receives node parameter data associated with the selected system node from the configuration control computer and supplies the first computer with the node parameter data for making it into the selected system node.

The application is at least directed to a core network including a non-transitory memory having instructions stored thereon for registering a network function or network function template in the core network. The network includes a processor, operably coupled to the non-transitory memory. The processor is configured to perform the instruction of determining that registration of the network function or network function template is acceptable. The processor is also configured to perform the instruction of transmitting a message including the network function or network function template to a repository in the core network. The processor is also configured to perform the instruction of verifying the network function or network function template against existing policies in the core network. The processor is also configured to perform the instruction of registering the network function or network function template in the repository after verification. The application is also directed to a core network that discovers a network function or network function template therein. The application is also directed to a core network that instantiates a network function.

A system includes a runbook manager configured to generate a runbook governing future server provisioning jobs, based on analyzed job history. The runbook manager includes a history analyzer configured to analyze a job history for a plurality of provisioning jobs performed to provision a plurality of servers, to thereby obtain the analyzed job history.

A data configuration method includes receiving a control packet sent by a control device, where the control packet is generated by the control device based on a yet another next generation (YANG) model and includes a configuration fragment, parsing the control packet to obtain the configuration fragment, and parsing the configuration fragment based on the general module to obtain a configuration command line, and executing the configuration command line.

A communications terminal (10) is to be configured for operation of a new service or application by connection to a service provision platform (12) over a connection (11). In order to do this, an installation server (15) generates instructions to a user terminal (13) over a seperate link (14). These instructions are used to configure the communications terminal (10) to operate the service required. The terminal (13), separate link (14) and installation server (15) are then used to monitor, over a connection (19) independent of the newly-installed connection (11), the response of the service provision platform (12) to the test transmissions sent to it from the terminal (10) over the new connection (11), and to initiate test messages from the service provision platform (12) to the communications terminal. By providing a connection (14, 15, 19) between an installation technician (13) and the service provision platform (12) independent of the newly-installed connection (11) and newly-configured terminal (10), the behaviour of the service provision platform can be more readily understood.

An infrastructure management subsystem receives a selection of a planned configuration of the computing infrastructure and a baseline demand that includes a current usage of computing resources of the computing infrastructure. The infrastructure management subsystem determines an anticipated turbulence. The anticipated turbulence includes a quantitative indication of anticipated fluctuations in future infrastructure demand as a function of time. The infrastructure management subsystem determines an effective turbulence for the planned infrastructure configuration. The effective turbulence includes a quantitative indication of anticipated fluctuations in future infrastructure availability. The infrastructure management subsystem determines a configuration score corresponding to an extent to which the anticipated fluctuations in the effective turbulence destructively interfere with the anticipated fluctuations in the anticipated turbulence.

A Heating, Ventilation, and/or Air Conditioning (HVAC) controller configured to control at least part of an HVAC system of a building. The HVAC controller may include a user interface and a controller. In response to a selection by a user at the user interface, the controller may assemble and present via the user interface an output that encodes settings in a machine readable form. The controller may display the encoded settings on the display with fixed segments of a fixed segment display. An application program code on a remote device may be utilized to capture the displayed fixed segments that encode the settings in an image. The captured image of fixed segments may be decoded at the remote device or may be sent to a remote computing device for processing and/or decoding.