Stream control transmission protocol (SCTP): a reference guide
Stream control transmission protocol (SCTP): a reference guide
End-to-end fault tolerance using transport layer multihoming
End-to-end fault tolerance using transport layer multihoming
Concurrent multipath transfer using SCTP multihoming over independent end-to-end paths
IEEE/ACM Transactions on Networking (TON)
Concurrent Multipath Transfer during path failure
Computer Communications
Retransmission policies for multihomed transport protocols
Computer Communications
NETWORKING'08 Proceedings of the 7th international IFIP-TC6 networking conference on AdHoc and sensor networks, wireless networks, next generation internet
Throughput analysis of Non-Renegable Selective Acknowledgments (NR-SACKs) for SCTP
Computer Communications
Concurrent multipath transfer using transport layer multihoming: performance under network failures
MILCOM'06 Proceedings of the 2006 IEEE conference on Military communications
Evaluation of Concurrent Multipath Transfer over Dissimilar Paths
WAINA '11 Proceedings of the 2011 IEEE Workshops of International Conference on Advanced Information Networking and Applications
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Concurrent multipath transport protocols have the potential to improve significantly the throughput performance and resilience of the internet traffic flows. If the data transfer starts to the destined IP, unaware of paths condition, that may result in packet loss and delay in data transfer. This is due to bursty conditions of IP traffic or physical damage. To overcome this, status of the network path is determined before transmission. In our new mechanism multipath state aware concurrent multipath transfer using redundant transfer (MSACMT-RT), status of multipath is determined, initially and periodically before transmission. MSACMT-RT begins immediately after determining the path status, for a particular interval of time and later transfers data with CMT only for predefined period. We demonstrate using simulation under assumption that both the sender/receiver have three paths for CMT. By using MSACMT-RT, it is inferred that our algorithm outperforms better than concurrent multipath transfer potentially failed (CMT-PF). MSACMT-RT mechanism in alternate paths increases the throughput. We present and discuss MSACMT-RT performance in asymmetric paths with the constrained receiver buffer (RBUF) value of 128 KB. We also discuss this scenario with no path failures, frequent and on more frequent path failures with regular and irregular intervals.