TCP-Peach: A New Congestion Control Scheme for Satellite IP Networks. Akyildiz, I. F., Morabito, G., & Palazzo, S. IEEE/ACM Transactions on Networking, 9(3):307--321, jun, 2001.
Paper bibtex @article{ Akyildiz01a,
author = {I. F. Akyildiz and G. Morabito and S. Palazzo},
title = {{TCP-Peach}: A New Congestion Control Scheme for Satellite IP Networks},
journal = {{IEEE/ACM} Transactions on Networking},
year = {2001},
volume = {9},
number = {3},
pages = {307--321},
month = {jun},
annote = {In this paper, a new congestion control scheme for networks with long propagation delays and high link error rates, e.g., satellite networks, is presented. The new congestion control scheme, TCP-Peach, comprises two new algorithms - Sudden Start and Rapid Recovery. Both algorithms are based on the use of so called dummy segments to probe the availability of bandwidth. The dummy segments are treated as low priority packets and thus should not have any substantial impact on the actual data traffic. Simulation experiments show that TCP-Peach outperforms other TCP schemes for satellite networks in terms of goodput, and that TCP-Peach connections share bandwidth fairly in between each other. However, when TCP Reno and TCP-Peach both run over a satellite link, the bandwidth is not shared evently between the two. For example, with a packet loss of 1E-4 over a geostationary satellite channel, TCP-Peach obtains 80% of the bandwidth.},
url = {papers/Akyildiz01.pdf},
submitter = {Karl-Johan Grinnemo}
}
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