Plesiochronous digital hierarchy

The plesiochronous digital hierarchy (PDH) is a technology used in telecommunications networks to transport large quantities of data over digital transport equipment such as fibre optic and microwave radio systems.[1] The term plesiochronous is derived from Greek plēsios, meaning near, and chronos, time, and refers to the fact that PDH networks run in a state where different parts of the network are nearly, but not quite perfectly, synchronized.

Backbone transport networks replaced PDH networks with synchronous digital hierarchy (SDH) or synchronous optical networking (SONET) equipment over the ten years ending around the turn of the millennium (2000),[2] whose floating payloads relaxed the more stringent timing requirements of PDH network technology. The cost in North America was $4.5 billion in 1998 alone,[3] p. 171.

PDH allows transmission of data streams that are nominally running at the same rate, but allowing some variation on the speed around a nominal rate. By analogy, any two watches are nominally running at the same rate, clocking up 60 seconds every minute. However, there is no link between watches to guarantee that they run at exactly the same rate, and it is highly likely that one is running slightly faster than the other.


The data rate is controlled by a clock in the equipment generating the data. The rate is allowed to vary by ±50 ppm of 2.048 kbit/s (according to ITU-T recommendation[4]). This means that different data streams can (and probably do) run at slightly different rates from one another.

In order to move multiple data streams from one place to another, they are multiplexed in groups of four. This is done by taking 1 bit from stream #1, followed by 1 bit from stream #2, then #3, then #4. The transmitting multiplexer also adds additional bits in order to allow the far end receiving multiplexer to decode which bits belong to which data stream, and so correctly reconstitute the original data streams. These additional bits are called "justification" or "stuffing" bits.

Because each of the four data streams is not necessarily running at the same rate, some compensation has to be introduced. The transmitting multiplexer combines the four data streams assuming that they are running at their maximum allowed rate. This means that occasionally, (unless the 2 Mbit/s really is running at the maximum rate) the multiplexer will look for the next bit but it will not have arrived. In this case, the multiplexer signals to the receiving multiplexer that a bit is "missing". This allows the receiving multiplexer to correctly reconstruct the original data for each of the four 2 Mbit/s data streams, and at the correct, different, plesiochronous rates.

The resulting data stream from the above process runs at 8.448 Mbit/s (about 8 Mbit/s). Similar techniques are used to combine four × 8 Mbit/s together, plus bit stuffing, giving 34 Mbit/s. Four × 34 Mbit/s, gives 140. Four × 140 gives 565.

See also


  1. Valdar, Andy (2006). Understanding Telecommunications Networks. IET. p. 78. ISBN 9780863413629.
  2. Cavendish, Dirceu (June 2000). "Evolution of Optical Transport Technologies: From SONET/SDH to WDM". IEEE Communications Magazine. 38: 164–172. doi:10.1109/35.846090.
  3. Cavendish, Dirceu (June 2000). "Evolution of Optical Transport Technologies: From SONET/SDH to WDM". IEEE Communications Magazine. 38: 164–172. doi:10.1109/35.846090.
  4. tsbmail. "G.703 : Physical/electrical characteristics of hierarchical digital interfaces". Retrieved 2016-03-06.
This article is issued from Wikipedia - version of the 10/12/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.