Given a connected graph G = (V, E), Let r = 1 be an integer and B-r(v) denote the ball of radius r centered at v is an element of V, i.e., the set of all vertices within distance r from v. A subset of vertices C subset of V is an r-identifying code of G (for a given nonzero constant r is an element of N) if and only if all the sets B-r(v) boolean AND C are nonempty and pairwise distinct. These codes were introduced in [7] to model a fault-detection problem in multiprocessor systems. They are also used to devise location-detection schemes in the framework of wireless sensor networks. These codes enable one to locate a malfunctioning device in these networks, provided one scans all the vertices of the code. We study here an adaptive version of identifying codes, which enables to perform tests dynamically. The main feature of such codes is that they may require significantly fewer tests, compared to usual static identifying codes. In this paper we study adaptive identifying codes in torii in the king lattice. In this framework, adaptive identification can be closely related to a Renyi-type search problem studied by M. Ruszinko [11].

• 出版日期2011-5-23