An Evaluation of Traffic Matrix Estimation Techniques for Large-Scale IP Networks

Adelani, Titus Olufemi

09 February 2010

The information on the volume of traffic flowing between all possible origin and destination pairs in an IP network during a given period of time is generally referred to as traffic matrix (TM). This information, which is very important for various traffic engineering tasks, is very costly and difficult to obtain on large operational IP network, consequently it is often inferred from readily available link load measurements. In this thesis, we evaluated 5 TM estimation techniques, namely Tomogravity (TG), Entropy Maximization (EM), Quadratic Programming (QP), Linear Programming (LP) and Neural Network (NN) with gravity and worst-case bound (WCB) initial estimates. We found that the EM technique performed best, consistently, in most of our simulations and that the gravity model yielded better initial estimates than the WCB model. A hybrid of these techniques did not result in considerable decrease in estimation errors. We, however, achieved most significant reduction in errors by combining iterative proportionally-fitted estimates with the EM technique. Therefore, we propose this technique as a viable approach for estimating the traffic matrix of large-scale IP networks.

traffic matrix estimation

iterative proportional fitting

IP networks

Entropy Maximization

Tomogravity

An Evaluation of Traffic Matrix Estimation Techniques for Large-Scale IP Networks

Adelani, Titus Olufemi

09 February 2010

The information on the volume of traffic flowing between all possible origin and destination pairs in an IP network during a given period of time is generally referred to as traffic matrix (TM). This information, which is very important for various traffic engineering tasks, is very costly and difficult to obtain on large operational IP network, consequently it is often inferred from readily available link load measurements. In this thesis, we evaluated 5 TM estimation techniques, namely Tomogravity (TG), Entropy Maximization (EM), Quadratic Programming (QP), Linear Programming (LP) and Neural Network (NN) with gravity and worst-case bound (WCB) initial estimates. We found that the EM technique performed best, consistently, in most of our simulations and that the gravity model yielded better initial estimates than the WCB model. A hybrid of these techniques did not result in considerable decrease in estimation errors. We, however, achieved most significant reduction in errors by combining iterative proportionally-fitted estimates with the EM technique. Therefore, we propose this technique as a viable approach for estimating the traffic matrix of large-scale IP networks.

traffic matrix estimation

iterative proportional fitting

IP networks

Entropy Maximization

Tomogravity

Empirical Assessment of the Iterative Proportional Fitting Method for Estimating Bus Route Passenger Origin-Destination Flows

Strohl, Brandon A.

15 January 2010

No description available.

Civil Engineering

Iterative proportional fitting

IPF

origin destination matrix estimation

OD matrix estimation

bus transit passenger OD flows

Combining Small Samples of Direct Observations of Passenger Flows with Large Quantities of Automatic Passenger Count Data for Estimating Bus Transit Route Origin-Destination Flows

Roy, Raj

January 2021

No description available.

Civil Engineering

Transportation

Transportation Planning

Engineering

origin-destination

bus transit

Automatic Passenger Count

Iterative Proportional Fitting

Seed Matrix

Empirical OD estimation

Monte-Carlo Simulation

onboard survey

Bus Transit Passenger Origin-Destination Flow Estimation: Capturing Terminal Carry-Over Movements Using the Iterative Proportional Fitting Method

Chen, Aijing

January 2020

No description available.

Civil Engineering

Transportation

Transportation Planning

transit

bus

origin-destination

OD flow

carry-over

iterative proportional fitting

estimating OD flow

terminal

IPF