Abstract
The use of chaotic codes in transmission systems presents many advantages, not only in term of security, but also to combat multi-path propagations and to allow multiple access. Nevertheless, the main problem of communication with chaos is the design of an experimental and real-time synchronization decoder between transmitter and receiver. In this paper, we suggest to use the belief propagation algorithm as a new approach for synchronizing quasi-chaotic signals. In this approach, the transmitter contains a digital chaotic oscillator which is perturbed by the information signal. The receiver consists in a dual system augmented with a belief propagation processing, whose aim is to recover the information signal. We suppose that the channel is Gaussian and synchronization is forced in a first step. Once synchronization is achieved, the information signal modulated the chaotic system and is transmitted on the Gaussian channel. An adaptative belief propagation algorithm is processed to recover the signal information.
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Launay, F., Coirault, P. A second-order Markov model to synchronize a quasi-chaotic sequence: application of synchronization and decoding problem with belief propagation. Ann. Telecommun. 69, 147–154 (2014). https://doi.org/10.1007/s12243-013-0406-3
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DOI: https://doi.org/10.1007/s12243-013-0406-3