Measurement
TheDirect
OWDs may be measured between two points ''A'' and ''B'' of an IP network through the use of synchronized clocks; ''A'' records a timestamp on the packet and sends it to ''B'', which notes the receiving time and calculates the OWD as their difference. The transmitted packets need to be identified at source and destination in order to avoid packet loss or packet reordering. However, this method suffers several limitations, such as requiring intensive cooperation between both parties, and the accuracy of the measured delay is subject to the synchronization precision. The Minimum-Pairs Protocol is an example by which several cooperating entities, ''A'', ''B'', and ''C'', could measure OWDs between one of them and a fourth less cooperative one (e.g., between ''B'' and ''X'').Estimate
Transmission between two network nodes may be asymmetric, and the forward and reverse delays are not equal. Half the RTT value is the average of the forward and reverse delays and so may be sometimes used as an approximation to the end-to-end delay. The accuracy of such an estimate depends on the nature of delay distribution in both directions. As delays in both directions become more symmetric, the accuracy increases. The probability mass function (PMF) of absolute error, ''E'', between the smaller of the forward and reverse OWDs and their average (i.e., RTT/2) can be expressed as a function of the network delay distribution as follows: :: where ''a'' and ''b'' are the forward and reverse edges, and ''fy(z)'' is the PMF of delay of edge ''z'' (that is, ''fy(z) = Pr).Delay components
End-to-end delay in networks comes from several sources including transmission delay, propagation delay, processing delay and queuing delay.See also
* Age of Information * Minimum-Pairs Protocol * Network delay * Store and forwardReferences
External links