3 research outputs found
Tight Bounds for Black Hole Search with Scattered Agents in Synchronous Rings
We study the problem of locating a particularly dangerous node, the so-called
black hole in a synchronous anonymous ring network with mobile agents. A black
hole is a harmful stationary process residing in a node of the network and
destroying destroys all mobile agents visiting that node without leaving any
trace. We consider the more challenging scenario when the agents are identical
and initially scattered within the network. Moreover, we solve the problem with
agents that have constant-sized memory and carry a constant number of identical
tokens, which can be placed at nodes of the network. In contrast, the only
known solutions for the case of scattered agents searching for a black hole,
use stronger models where the agents have non-constant memory, can write
messages in whiteboards located at nodes or are allowed to mark both the edges
and nodes of the network with tokens. This paper solves the problem for ring
networks containing a single black hole. We are interested in the minimum
resources (number of agents and tokens) necessary for locating all links
incident to the black hole. We present deterministic algorithms for ring
topologies and provide matching lower and upper bounds for the number of agents
and the number of tokens required for deterministic solutions to the black hole
search problem, in oriented or unoriented rings, using movable or unmovable
tokens
Black Hole Search with Finite Automata Scattered in a Synchronous Torus
We consider the problem of locating a black hole in synchronous anonymous
networks using finite state agents. A black hole is a harmful node in the
network that destroys any agent visiting that node without leaving any trace.
The objective is to locate the black hole without destroying too many agents.
This is difficult to achieve when the agents are initially scattered in the
network and are unaware of the location of each other. Previous studies for
black hole search used more powerful models where the agents had non-constant
memory, were labelled with distinct identifiers and could either write messages
on the nodes of the network or mark the edges of the network. In contrast, we
solve the problem using a small team of finite-state agents each carrying a
constant number of identical tokens that could be placed on the nodes of the
network. Thus, all resources used in our algorithms are independent of the
network size. We restrict our attention to oriented torus networks and first
show that no finite team of finite state agents can solve the problem in such
networks, when the tokens are not movable. In case the agents are equipped with
movable tokens, we determine lower bounds on the number of agents and tokens
required for solving the problem in torus networks of arbitrary size. Further,
we present a deterministic solution to the black hole search problem for
oriented torus networks, using the minimum number of agents and tokens
Ping Pong in Dangerous Graphs: Optimal Black Hole Search with Pebbles
International audienceWe prove that, for the black hole search problem in networks of arbitrary but known topology, the pebble model of agent interaction is computationally as powerful as the whiteboard model; furthermore the complexity is exactly the same. More precisely, we prove that a team of two asynchronous agents, each endowed with a single identical pebble (that can be placed only on nodes, and with no more than one pebble per node), can locate the black hole in an arbitrary network of known topology; this can be done with Θ(nlog n) moves, where n is the number of nodes, even when the links are not FIFO. These results are obtained with a novel algorithmic technique, ping-pong, for agents using pebbles