The present disclosure is directed to a multi-level resource reservation system that obviates one or more of the problems due to limitations and disadvantages of the related art. The multi-level resource reservation system creates, or modifies existing, peer-to-peer protocol(s) to complete a continuous chain of configured ports to support QoS feature(s), e.g., bound latency and guaranteed jitter, for a data flow that traverses an arbitrary sequence of bridges, routers, and virtual links.

Presented herein are methodologies for implementing a system and apparatus to estimate a network disruption index and undertake a mitigation action accordingly. A method includes calculating a network disruption index based on at least a disruption score associated with a service request measure, an end-of-life measure, a security incident response measure and a return material authorization measure for respective hardware devices in a network, comparing the network disruption index to a predetermined threshold, and when the network disruption index is above the predetermined threshold, identifying one or more of the hardware devices in the network for a mitigation action and implementing the mitigation action.

A customer having a deployment of resources in a resource provider environment can utilize a mechanism such as an application programming interface (API) to obtain fault, risk, and/or distribution information for the deployment. A risk score can be generated, by the customer or a component of the resource provider environment, that gives the customer a measure of the risk of the current deployment, whereby the customer can request one or more changes to the customer deployment. In some embodiments the customer can provide one or more risk criteria, such as a maximum risk score or minimum fault tolerance, that the resource provider environment can attempt to satisfy over the duration of the customer deployment, automatically making adjustments to the deployment as appropriate. The risk score can include information about the customer workload as well as the physical deployment in order to provide more accurate data.

In embodiments, a communication node of a multi-node communication network includes a communication interface and a controller communicatively coupled to the communication interface. In embodiments, the controller is configured to receive a first data packet transmitted from a source communication node to a destination communication node; transmit the first data packet via a packet flooding procedure; receive a first route response transmitted from the destination communication node along a discovered route; relay an additional data packet transmitted from the source communication node to the destination communication node along the discovered route; determine a route failure of the additional data packet; re-transmit the additional data packet to the destination communication node via a packet flooding procedure; receive an additional route response transmitted from the destination communication node along a recovered route; and relay a second additional data packet transmitted from the source communication node along the recovered route.

Techniques are provided for a high availability solution (e.g., a network attached storage (NAS) solution) with address preservation during switchover. A first virtual machine is deployed into a first domain and a second virtual machine is deployed into a second domain of a computing environment. The first and second virtual machines are configured as a node pair for providing clients with access to data stored within an aggregate comprising one or more storage structures within shared storage of the computing environment. A load balancer is utilized to manage logical interfaces used by clients to access the virtual machines. During switchover, the load balancer preserves an IP address used to mount and access a data share of the aggregate used by a client.

The disclosure provides methods, systems, and computer readable media for calibrating user responses to questions. The method may comprise presenting, with the aid of a computer system and an interactive display operatively coupled to the computer system, a query to a user. The query may relate to the user's dietary consumption, exercise, health condition or mental condition. The system may receive from the user a response to the query. The system may interpret a user's response to a query based on a set of reference information. The set of reference information may comprise a pictorial depiction of portion size of the dietary consumption, exertion level of the exercise, existing state of the health condition or existing state of the mental condition.

Systems and techniques for intelligent data forwarding in edge networks are described herein. A request may be received from an edge user device for a service via a first endpoint. A time value may be calculated using a timestamp of the request. Motion characteristics may be determined for the edge user device using the time value. A response to the request may be transmitted to a second endpoint based on the motion characteristics.

A communication method and system for converging a 5.sup.th generation (5G) communication system for supporting higher data rates beyond a 4.sup.th generation (4G) system with a technology for Internet of things (IoT) are provided. The communication method and system may be applied to intelligent services based on the 5G communication technology and the IoT-related technology. A method performed by a terminal for beam failure recovery (BFR) on a secondary cell (SCell) in a wireless communication system comprises receiving information for BFR on an SCell including a scheduling request configuration for the BFR on the SCell; detecting beam failure on the SCell based on whether a number of beam failure instances within a preconfigured time duration exceeds a preconfigured number; and, as a response to detecting the beam failure on the SCell, transmitting a scheduling request for the BFR on the SCell based on the scheduling request configuration.

A failure recovery method for a virtual network, includes determining, by a network device, that a physical link in a physical network fails, where the failed physical link corresponds to at least one virtual link in the virtual network, and mapping the at least one virtual link corresponding to the failed physical link to a non-failed physical resource in the physical network, where the non-failed physical resource satisfies a transmission bandwidth of each of the at least one virtual link.

Some embodiments described herein provide a combination of a layer 3 (L3) hop with layer 2 (L2) bypass/fail-to-wire in a network device. Specifically, some embodiments place the network device between two routers, thereby becoming a L3 hop between the two routers. The existing route between the two routers is preserved by using L2 bypass through the network device. If the network device fails, then the physical fail-to-wire will be engaged, removing its L3 hop, but preserving the L2 bypass.