Performance-enhancing proxy

Performance-enhancing proxies (PEPs) are network agents designed to improve the end-to-end performance of some communications protocol. PEP standards are defined in RFC 3135 (PEPs intended to mitigate link-related degradations) and RFC 3449 (TCP performance implications of network path asymmetry).

Classification

Available PEP implementations use different methods to enhance performance.

Types

There are a range of different types of PEPs. Each is used to solve a link related problem. Some common types include:

Split TCP

Split TCP is typically used to solve TCP problems with large RTTs. A typical system uses Split TCP PEPs to improve TCP performance over a satellite link. Split TCP functions by breaking the end-to-end connection into multiple connections and using different parameters to transfer data across the different legs. The end systems use standard TCP with no modifications, and do not need to know of the existence of the PEPs in between. Split TCP intercepts TCP connections from the end systems and terminate them. This allows the end systems to run unmodified and can overcome some problems with TCP window sizes on the end systems being set too low for satellite communications.

Ack filtering/decimation

Ack filtering or decimation is used on highly asymmetric links. In asymmetric links the upstream and downstream rates vary widely. A common example is satellite broadband where the downstream satellite link provides significantly greater bandwidths than the upstream dialup modem link. In this scenario, the speed at which the modem can return TCP acknowledgements can be a limiting factor. As TCP acknowledgements are cumulatively acknowledged some can be decimated or filtered to improve performance.

Snoop

The Snoop proxy[2] is an example of an integrated proxy. It is designed to hide interference or collision based packet loss over a wireless link. Snoop proxies detect losses by monitoring TCP transmissions for duplicate acknowledgements. When duplicate TCP acknowledgements, indicating a packet loss, are received by Snoop, they will be silently dropped and lost data packet will be retransmitted. The TCP sender should have no knowledge of the loss. This should prevent TCP senders from unnecessarily reducing the TCP window.

D-Proxy

D-Proxy[3][4] is also designed to hide interference or collision based packet loss over a wireless link. D-Proxy is a new distributed TCP proxy, requiring a proxy on either side of the lossy link. Like Snoop, it uses TCP sequence numbers to detect lost packets. However, it has a proactive approach, monitoring the TCP sequence numbers on data packets rather than acknowledgements. When packet loss occurs, the TCP stream will be temporarily buffered until the missing packet can be recovered and re-sequenced.

See also

References

  1. : PERFORMANCE ENHANCEMENT PROXY (PEP) : TCP in Wireless Network
  2. Balakrishnan, Hari; Srinivasan Seshan; Randy H. Katz (December 1995). "Improving TCP/IP Performance over Wireless Networks". ACM Wireless Networks 1 (4).
  3. Murray, David; Terry Koziniec; Michael Dixon (2009). "Solving Ack Inefficiencies in 802.11 Networks". IEEE International Conference on Internet Multimedia Systems Architecture and Applications.
  4. Murray, David; Terry Koziniec; Michael Dixon (2010). "D-Proxy: Reliability in Wireless Networks". 16th Asia-Pacific Conference on Communications (APCC).

External links

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