Bounds and extremal graphs for total dominating identifying codes

Abstract

An identifying code C of a graph G is a dominating set of G such that any two distinct vertices of G have distinct closed neighbourhoods within C. The smallest size of an identifying code of G is denoted γID(G). When every vertex of G also has a neighbour in C, it is said to be a total dominating identifying code of G, and the smallest size of a total dominating identifying code of G is denoted by γtID(G). Extending similar characterizations for identifying codes from the literature, we characterize those graphs G of order n with γtID(G)=n (the only such connected graph is P3) and γtID(G)=n-1 (such graphs either satisfy γID(G)=n-1 or are built from certain such graphs by adding a set of universal vertices, to each of which a private leaf is attached). Then, using bounds from the literature, we remark that any (open and closed) twin-free tree of order n has a total dominating identifying code of size at most 3n4. This bound is tight, and we characterize the trees reaching it. Moreover, by a new proof, we show that this bound actually holds for the larger class of all twin-free graphs of girth at least 5. The cycle C8 also attains this bound. We also provide a generalized bound for all graphs of girth at least 5 (possibly with twins). Finally, we relate γtID(G) to the related parameter γID(G) as well as the location-domination number of G and its variants, providing bounds that are either tight or almost tight.