Byzantine self-stabilizing pulse in a bounded-delay model

Pulse Synchronization intends to invoke a recurring distributed event at the different nodes, of a distributed system as simultaneously as possible and with a frequency that matches a predetermined regularity. This paper shows how to achieve that goal when the system is facing both transient and permanent (Byzantine) failures. Byzantine nodes might incessantly try to de-synchronize the correct nodes. Transient failures might throw the system into an arbitrary state in which correct nodes have no common notion what-so-ever, such as time or round numbers, and thus cannot use any aspect of their own local states to infer anything about the states of other correct nodes. The algorithm we present here guarantees that eventually all correct nodes will invoke their pulses within a very short time interval of each other and will do so regularly. The problem of pulse synchronization was recently solved in a system in which there exists an outside beat system that synchronously signals all nodes at once. In this paper we present a solution for a bounded-delay system. When the system in a steady state, a message sent by a correct node arrives and is processed by all correct nodes within a bounded time, say d time units, where at steady state the number of Byzantine nodes, f, should obey the n > 3f inequality, for a network of n nodes.