Robust Header Compression


Robust Header Compression is a standardized method to compress the IP, UDP, UDP-Lite, RTP, and TCP headers of Internet packets.

The need for header compression

In streaming applications, the overhead of IP, UDP, and RTP is 40 bytes for IPv4, or 60 bytes for IPv6. For VoIP, this corresponds to around 60% of the total amount of data sent. Such large overheads may be tolerable in local wired links where capacity is often not an issue, but are excessive for wide area networks and wireless systems where bandwidth is scarce.
ROHC compresses these 40 bytes or 60 bytes of overhead typically into only one or three bytes, by placing a compressor before the link that has limited capacity, and a decompressor after that link. The compressor converts the large overhead to only a few bytes, while the decompressor does the opposite.
The ROHC compression scheme differs from other compression schemes, such as IETF RFC 1144 and RFC 2508, by the fact that it performs well over links where the packet loss rate is high, such as wireless links.

Main ROHC compression principles

The ROHC protocol takes advantage of information redundancy in the headers of the following:
Redundant information is transmitted in the first packets only. The next packets contain variable information, e.g. identifiers or sequence numbers. These fields are transmitted in a compressed form to save more bits.
For better performance, the packets are classified into streams before being compressed. This classification takes advantage of inter-packet redundancy. The classification algorithm is not defined by the ROHC protocol itself but left to the equipment vendor's implementation. Once a stream of packets is classified, it is compressed according to the compression profile that fits best. A compression profile defines the way to compress the different fields in the network headers. Several compression profiles are available, including the following:
According to RFC 3095, the ROHC scheme has three modes of operation, as follows:
Both the compressor and the decompressor start in U-mode. They may then transition to O-mode if a usable return link is available, and the decompressor sends a positive acknowledgement, with O-mode specified, to the compressor. The transition to R-mode is achieved in the same way.

Unidirectional Mode (U-Mode)

In the Unidirectional mode of operation, packets are only sent in one direction: from compressor to decompressor. This mode therefore makes ROHC usable over links where a return path from decompressor to compressor is unavailable or undesirable. In order to handle potential decompression errors, the compressor sends periodic refreshes of the stream context to the decompressor.

Bidirectional Optimistic Mode (O-Mode)

The Bidirectional Optimistic mode is similar to the Unidirectional mode, except that a feedback channel is used to send error recovery requests and acknowledgments of significant context updates from the decompressor to compressor. The O-mode aims to maximize compression efficiency and aims for sparse usage of the feedback channel.

Bidirectional Reliable Mode (R-Mode)

The Bidirectional Reliable mode differs in many ways from the previous two modes. The most important differences are a more intensive usage of the feedback channel, and a stricter logic at both the compressor and the decompressor that prevents loss of context synchronization between compressor and decompressor, except for very high residual bit error rates.

Compressor/decompressor states

The notion of compressor/decompressor states is orthogonal to the operational modes. Whatever the mode is, both the compressor and the decompressor work in one of their three states. They are basically finite state machines. Every incoming packet may cause the compressor/decompressor to change its internal state. Every state refers to a defined behaviour and compression level.
The ROHC algorithm is similar to video compression, in that a base frame and then several difference frames are sent to represent an IP packet flow. This has the advantage of allowing ROHC to survive many packet losses in its highest compression state, as long as the base frames are not lost.

Compressor states

The compressor's state machine defines the following three states:
In Initialization and Refresh state, the compressor has just been created or reset, and full packet headers are sent. In First-Order state, the compressor has detected and stored the static fields on both sides of the connection. The compressor is also sending dynamic packet field differences in FO state. Thus, FO state is essentially static and pseudo-dynamic compression. In Second-Order state, the compressor is suppressing all dynamic fields such as RTP sequence numbers, and sending only a logical sequence number and partial checksum to cause the other side to predictively generate and verify the headers of the next expected packet. In general, FO state compresses all static fields and most dynamic fields. SO state is compressing all dynamic fields predictively using a sequence number and checksum.

Transitions between compressor states

Transitions between the above states occur when the compressor:
A typical ROHC implementation will aim to get the terminal into Second-Order state, where a 1-byte ROHC header can be substituted for the 40-byte IPv4/UDP/RTP or the 60-byte IPv6/UDP/RTP header. In this state, the 8-bit ROHC header contains three fields:
The decompressor's state machine defines the following three states:
Transitions between the above states occur when the decompressor:
The size of the sequence number field governs the number of packets that ROHC can lose before the compressor must be reset to continue. The W-LSB algorithm is used to compress the SN in a robust way. The size of the sequence number in 1 and 2 byte ROHC packets is either 4 bits, or 6 bits, respectively, so ROHC can tolerate at most 62 lost frames with a 1-2 byte header.

Additional compression profiles

The RFC 3095 defines a generic compression mechanism. It may be extended by defining new compression profiles dedicated to specific protocol headers. New RFCs were published to compress new protocols:
There have been two new RFCs published and to address the confusion some have encountered when attempting to interpret and implement ROHC. The first document defines a ROHC framework, while the second defines newer versions of the established ROHC profiles.