TY - GEN
T1 - TCP congestion avoidance
T2 - IEEE INFOCOM 2005
AU - Chen, Mingyu
AU - Zhang, Jinsong
AU - Murthi, Manohar N.
AU - Premaratne, Kamal
PY - 2005
Y1 - 2005
N2 - TCP congestion avoidance mechanisms determine methods by which a source adjusts its window size according to network conditions. Although network calculus has been utilized to study window flow control, the use of network calculus to determine an optimal window controller and to provide analytical guidance to TCP congestion avoidance has persisted as an open problem. For the first time within a network calculus setting, we determine an optimal window size control method for general flow control problems. We also show that the basic TCP congestion avoidance mechanisms in TCP Vegas, Enhanced TCP Vegas and Fast TCP can be viewed as different approaches to approximating the optimal NC controller, with each TCP variant making different assumptions in terms of parameter estimation and control implementation strategy. Therefore, the network calculus controller reveals the inherent underlying structure in TCP congestion avoidance. Furthermore, we demonstrate through ns-2 simulations that an approximation of a particular NC controller achieves performance gains in terms of link throughput and source node throughput fairness with respect to TCP Vegas, Enhanced TCP Vegas and Fast TCP.
AB - TCP congestion avoidance mechanisms determine methods by which a source adjusts its window size according to network conditions. Although network calculus has been utilized to study window flow control, the use of network calculus to determine an optimal window controller and to provide analytical guidance to TCP congestion avoidance has persisted as an open problem. For the first time within a network calculus setting, we determine an optimal window size control method for general flow control problems. We also show that the basic TCP congestion avoidance mechanisms in TCP Vegas, Enhanced TCP Vegas and Fast TCP can be viewed as different approaches to approximating the optimal NC controller, with each TCP variant making different assumptions in terms of parameter estimation and control implementation strategy. Therefore, the network calculus controller reveals the inherent underlying structure in TCP congestion avoidance. Furthermore, we demonstrate through ns-2 simulations that an approximation of a particular NC controller achieves performance gains in terms of link throughput and source node throughput fairness with respect to TCP Vegas, Enhanced TCP Vegas and Fast TCP.
UR - https://www.scopus.com/pages/publications/25844463719
U2 - 10.1109/INFCOM.2005.1498321
DO - 10.1109/INFCOM.2005.1498321
M3 - Conference contribution
AN - SCOPUS:25844463719
SN - 0780389689
T3 - Proceedings - IEEE INFOCOM
SP - 914
EP - 925
BT - Proceedings - IEEE INFOCOM 2005. The Conference on Computer Communications - 24th Annual Joint Conference of the IEEE Computer and Communications Societies
A2 - Makki, K.
A2 - Knightly, E.
Y2 - 13 March 2005 through 17 March 2005
ER -