Embodiments of the present invention provide a method, system and computer program product for collaborative route reservation in an HPC fabric. A method for collaborative route reservation in an HPC fabric includes selecting a target node in a cluster of nodes to receive a payload from a source node of the cluster over an HPC fabric and computing a route over the HPC fabric for transferring the payload from the source node to the target node, and also a duration of time requisite to transferring the payload. The method also includes notifying other nodes in the cluster of a reservation of the computed route for the duration of time and utilizing the computed route during the duration of time to transfer the payload. Finally, the method includes responding to completing transfer of the payload by notifying the other nodes that the computed path is no longer reserved.

Avoiding jitter in a communication network. A method for avoiding jitter includes receiving, an ingress point of the communication network, a packet, wherein the packet is received at the ingress point at a time within a particular time slot. The method also includes the ingress point creating a modified packet that includes the received packet and a slot identifier indicating the particular time slot in which the packet was received, the ingress point transmitting (s406) the modified packet towards an egress point of the communication network.

This disclosure describes systems, devices, and techniques for detecting and diagnosing anomalies in utilization levels of network-based resources. In an example method, at least one utilization level of one or more computer resources by an account during a time interval may be received. A possible anomaly can be detected if the at least one utilization level is determined to be outside of a predetermined range. The anomaly can be confirmed determining that at least a threshold number of multiple discrimination layers identify an anomaly in the at least one utilization level. An action can be performed in response to confirming the anomaly.

This disclosure involves applying rate limits to violating tenant computing devices causing resource consumption violations at system components identified via violation evaluation processes. A system identifies a resource consumption violation with respect to a computing system hosting an online service. The system retrieves log data identifying tenant systems that accessed the memory resource during a particular time period in which the resource consumption violation impacted performance of the online service. The system determines, from the log data, that a violator tenant system accessing the online service caused the resource consumption violation. The system enforces a rate limit against the violator tenant system rather than other tenant systems identified in the log data.

In one or more embodiments, a cloud operation reservation system is provided through which cloud operations may be scheduled and managed. The cloud operation reservation system includes logic for defining a set of time windows that are available to perform one or more cloud operations on cloud targets and presenting the set of time windows to one or more tenants of a cloud service. Tenants may browse the presented set of time windows and submit reservation requests to update and/or perform other operations on cloud targets. In response to receiving, a request to reserve one or more slots in a particular time window, the cloud operation reservation system schedules one or more cloud operations to be performed on a cloud target that is available to at least one tenant.

Information may be dynamically disseminated to network devices. In some embodiments, a data structure may be populated with first-type values and second-type values, a first delay time may be assigned to a first value of the first-type values based on the first value being associated with a first priority and a second delay time may be assigned to a second value of the first-type values based on the second value being associated with a second priority, and data structure information may be obtained from the data structure. The data structure information may be delivered such that the delivery of the data structure information to a first network device associated with the first value reflects the first delay time and the delivery of the data structure information to a second network device associated with the second value reflects the second delay time.

A method for transmitting channel state information (CSI) by a user equipment in a wireless communication system is discussed. The method includes receiving a transmission burst; measuring the CSI based on the transmission burst; and transmitting the measured CSI, wherein the transmission burst is received in at least a first time resource and a second time resource, wherein the first time resource is configured as a first number of orthogonal frequency divisional multiplexing (OFDM) symbols, wherein the second time resource is configured as a second number of OFDM symbols, wherein the first number is smaller than the second number, and wherein the first time resource is considered to be an invalid time resource for the CSI.

Cloud-native clusters are disclosed and configured to for an edge cloud. The edge cloud includes using private infrastructure to include edge stations that are configured to perform cloud-native applications. The edge stations are geographically closer to end users and end user devices.

Aspects of the disclosure provide an apparatus for wireless communication. The apparatus includes a transceiver and a processing circuit. The transceiver is configured to transmit and receive wireless signals. The processing circuit is configured to detect an error of a previous scheduled transmission of data units from the apparatus to another apparatus. The other apparatus provides scheduled resources for transmission between the two apparatuses. Further, the processing circuit is configured to determine resources that are scheduled by the other apparatus for the apparatus to perform retransmission, and provide one or more of the data units in the previous scheduled transmission to the transceiver for retransmission using the scheduled resources.

A device receives topology data and path data associated with a network that includes network devices. The device determines planned bandwidths for new paths through the network based on the topology data and the path data, and ranks the new paths, based on the planned bandwidths, to generate a ranked list. The device selects information identifying a first new path from the ranked list, wherein the first new path includes a first planned bandwidth. The device determines whether the first new path can be provided via a single route through the network based on the first planned bandwidth, and identifies two or more routes through the network for the first new path when the first new path cannot be provided via the single route. The device causes the first planned bandwidth to be reserved by two or more of the network devices for the two or more routes.