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.

The present invention relates to, in a wireless access system supporting an unlicensed band, methods for configuring and scheduling a partial subframe (pSF) and devices for supporting same. A method for receiving data through a cell (U cell) configured in an unlicensed band in a wireless access system for supporting an unlicensed band comprises the steps of: a terminal receiving control information from a base station through a primary cell (P cell) which is configured in a licensed band; and the terminal receiving, on the basis of the control information, downlink data from the base station through an unlicensed band cell (U cell) which is configured in an unlicensed band, wherein, if cross-carrier scheduling is configured in the terminal, the terminal not anticipating, as the subframe for receiving the downlink data, a partial subframe (pSF) which is transmitted in a state of having the first part of symbol emptied, wherein the pSF is configured to be smaller than one subframe.

This disclosure describes methods, devices, and systems related to coordinating channel switch times and specifying device operation (for example, transmitting device operation) to ensure data reception by one or more devices (for example, receiving devices). A device may receive a data path setup request frame from a second device. The device may cause to send a service a data path setup response frame. The device may cause to establish a communication with the second device on a first channel. The device may cause to establish a communication with the second device on a second channel at a first time. The device may cause to wait, by the device, at least for a duration specified by a channel switch time (CST) parameter. The device may cause to send device data to the second device over the first channel or the second channel based at least in part on the CST parameter.

A system for determining an optimal schedule for transmitting data from a source node to a destination node in a telecommunications network. The source node is connected to a plurality of egress links. The system comprises a schedule generator for generating a plurality of candidate schedules. The schedule generator is configured to automatically generate a candidate schedule for each egress link of the source node by selecting a first window of time, determining a highest throughput route starting at the egress link during the first window of time based on predicted link utilisations, and if the throughput of the highest throughput route is not sufficient to transport all the data during the first window of time, selecting one or more subsequent windows of time and, for each subsequent window of time, determining a highest throughput route starting at the egress link during the subsequent window of time based on predicted link utilisations until a candilate schedule for transferring all the data has been defined. The system also comprises a schedule selector for automatically selecting a best candidate schedule from the plurality of candidate schedules based on the time taken to transfer all the data across the network.

The present invention relates to packet-switched networks, such as Ethernet, and more particularly to a method for traffic shaping of data frames to transmit in such a telecommunication network, the frames to transmit being distinguished between: express frames, needing to be sent within predetermined time windows, and normal frames, intended to be sent at times outside said time windows. More particularly, for a current normal frame, the method comprises the steps of: determining whether said normal frame can be fragmented, and if yes: determining whether a remaining time to a next time window opening is enough to transmit one or several fragments of said normal frame, and if yes: transmitting said one or several fragments.

Method for data transmission within an industrial communication network, wherein selected datagrams are transmitted within predetermined time intervals, which are synchronized at all network nodes, where a number of network nodes from the respective source network node to the respective target network node is determined for forwarding the selected datagrams in each case, and where the selected datagrams are transmitted during first periodic time intervals having a first protection interval length in the event of a determined number of network nodes corresponding to at least one predefined threshold value and, in contrast thereto, if a determined number lies below the threshold value, then the selected datagrams are transmitted during second periodic time intervals having a second protection interval length, which is shorter than the first protection interval length.

In general, techniques are described to dynamically adjust a session detection time defined by a timer in accordance with a bidirectional forwarding detection (BFD) protocol. The techniques utilize existing hardware and BFD software infrastructure. An example network device includes a memory, programmable processor(s), and a control unit configured to execute a timer, receive one or more packets provided by the BFD protocol, detect, based on the received one or more packets, a congestion condition associated with a link via which the network device is coupled to a network, adjust, based on the detected congestion condition, a session detection time defined by the timer, and in response to a failure to receive a packet provided by the BFD protocol within the session detection time defined by the timer, detect a failure associated with the link.

A maintenance recommendation for containerized services can find a time to perform maintenance on a particular service based on resource usage patterns such that the maintenance will have a reduced impact on dependent services. The dependent services can be determined for the particular service based on network interactions between the services.

The present disclosure provides methods for releasing a reserved resource in a network. An operation method performed in a first communication node of a vehicle network includes generating a first frame including identification information of a stream transmitted through a reserved resource and a first indicator instructing to release the reserved resource; and transmitting the first frame to a second communication node.

Disclosure method that includes traversing a user instance distribution of user instances of a user on hosts in a cluster to detect whether a trigger condition for user scheduling of adjustment of the user instance distribution is satisfied; migrating the user instance to be migrated out from the one or more hosts from which the user instances are to be migrated out to the one or more second hosts to which the one or more user instances are to be migrated in if the trigger condition for user scheduling is satisfied. The implementations of the present disclosure may schedule resources based on user instance distributions of users on hosts and achieve a balanced distribution of user instances. The implementations further avoid placing user instances of all users into a small number of hosts, increase the ability to prevent risks, and enhance the user experience.