Described is a method for estimating throughput between first and second communication devices, the method comprising: determining maximum bottleneck throughput of a communication link between the first communication device and a third communication device, wherein the communication link between the first and third communication devices applies a common access network as between a communication link between the first and second communication devices; determining Round Trip Time (RTT) between the first and second communication devices; transmitting packet by applying User Datagram Protocol (UDP) from the third communication device to the first communication device; measuring packet loss rate associated with the transmitted packet by monitoring sequence number of the packet; and translating measured packet loss rate to Transmission Control Protocol (TCP) throughput according to maximum bottleneck throughput and RTT.

This disclosure describes techniques for providing information associated with an inter-cluster segment. For instance, system(s) may determine dependencies for first services associated with a first cluster and second dependencies for second services associated with a second cluster. The system(s) may then determine information for interconnections between the first cluster and the second cluster. The information may include at least dependencies for third services included in the inter-cluster segment and/or performance information for the third services. The system(s) may then generate a user interface that includes the first dependencies for the first services, the second dependencies for the second services, and the information for the inter-cluster segment. This way, a user is able to use the user interface to identify both problems occurring within the clusters and/or problems that are caused by the third services in the inter-cluster segment.

One example method occurs at a test system implemented using at least one processor, the method comprising: sending, via an application programming interface (API) and to a first traffic generator, a first instruction for setting a rate of background test packets sent to or via a system under test (SUT) for a test session; sending the background test packets to or via the SUT during the test session; receiving, from at least one feedback entity, feedback indicating at least one traffic metric associated with the background test packets sent to or via the SUT during the test session; generating, using the feedback, a second instruction for adjusting the rate of background test packets sent during the test session; and providing, via the API and to the first traffic generator, the second instruction for adjusting the rate of background test packets sent to or via the SUT during the test session.

In an example, a computer-implemented method includes generating test data that is configured to be identified as data of interest at one or more visibility points in a network having a plurality of network routes. The method also includes injecting the test data into each network route of the plurality of network routes at a location upstream from the one or more visibility points, and determining, for each network route through which the test data travels, whether the test data is identified at the one or more visibility points. The method also includes outputting, for each network route through which the test data travels, data that indicates whether the test data is identified at the one or more visibility points as data of interest.

It is disclosed a method and system for providing performance measurements in a packet-switched communication network, wherein a performance measurement application run by a user communication device monitors the performance of a packet flow which a user application run by the user communication device exchanges with the packet-switched communication network. This monitoring comprising providing values of a performance parameter relating to the packet flow. If, based on the performance parameter values provided by the performance measurement application, a failure condition affecting the packet flow is detected, a further monitoring of the performance of the packet flow is activated, by one or more measurement points located within the packet-switched communication network on the path of the packet flow. This further monitoring comprising providing values of a further performance parameter relating to the packet flow.

A method is disclosed for the collection of performance metrics by establishing service operations administration and maintenance (OAM) sessions between an actuator and a plurality of reflectors in a communication network. Test packets from an actuator simultaneously reach a plurality of reflectors along a test path. Each single test packet results into a plurality of test results, one per reflector, with quasi-synchronous performance metrics to sectionalize a network and more efficiently isolate fault or performance problems without the need for additional test packets to isolate the issue. Another method is disclosed wherein an actuator generates and transmits a plurality of simultaneous test packets, one per NID device, resulting into a plurality of test results, one per reflector, with quasi-synchronous performance metrics to sectionalize a network and more efficiently isolate fault or performance problems without the need for additional test packets to isolate the issue.

A method of determining the bandwidth of a link carrying a plurality of data streams between a plurality of sources and a plurality of destinations in a network, the method including sending data packets from a first data stream over the link from one source to one destination at a first transmission rate, and measuring an associated first packet loss rate; sending further data packets from the first data stream over the link from the one source to the one destination at a second transmission rate, and measuring an associated second packet loss rate; and determining the bandwidth of the link in dependence on the first and second packet loss rates and the first and second transmission rates.

Described is a method for estimating throughput between first and second communication devices, the method comprising: determining maximum bottleneck throughput of a communication link between the first communication device and a third communication device, wherein the communication link between the first and third communication devices applies a common access network as between a communication link between the first and second communication devices; determining Round Trip Time (RTT) between the first and second communication devices; transmitting packet by applying User Datagram Protocol (UDP) from the third communication device to the first communication device; measuring packet loss rate associated with the transmitted packet by monitoring sequence number of the packet; and translating measured packet loss rate to Transmission Control Protocol (TCP) throughput according to maximum bottleneck throughput and RTT.

According to certain embodiments, a method determines a number of transmitted packets that a first node transmitted to a second node via a link and a number of received packets that the second node received from the first node via the link. The number of transmitted packets and the number of received packets are determined for each interval of a plurality of intervals. The method further comprises determining a plurality of packet loss values. Each packet loss value is associated with a respective interval and is determined based on the number of transmitted packets and the number of received packets associated with the respective interval. The method further comprises determining variability based on the plurality of packet loss values and configuring a value associated with reordering detection based on whether the variability exceeds a threshold.

This disclosure describes techniques for providing information associated with an inter-cluster segment. For instance, system(s) may determine dependencies for first services associated with a first cluster and second dependencies for second services associated with a second cluster. The system(s) may then determine information for interconnections between the first cluster and the second cluster. The information may include at least dependencies for third services included in the inter-cluster segment and/or performance information for the third services. The system(s) may then generate a user interface that includes the first dependencies for the first services, the second dependencies for the second services, and the information for the inter-cluster segment. This way, a user is able to use the user interface to identify both problems occurring within the clusters and/or problems that are caused by the third services in the inter-cluster segment.