Strong Connectivity in Directed Graphs under Failures, with Applications

Abstract: In this paper, we investigate some basic connectivity problems in directed graphs (digraphs). Let G be a digraph with m edges and n vertices, and let G \ e (resp., G \ v) be the digraph obtained after deleting edge e (resp., vertex v) from G. As a first result, we show how to compute in O(m + n) worst-case time: • The total number of strongly connected components in G \ e (resp., G \ v), for all edges e (resp., for all vertices v) in G. • The size of the largest and of the smallest strongly connected component… Show more

“…a complete algorithm) in an idealised setting [Cai+19; Cai+21; Cai+20]. However, the omnitig algorithm requires complex data structures [Cai+21; GIP20] and omnitigs themselves are not safe in the presence of sequencing errors, missing coverage, or linear chromosomes [TM17]; as a result, omnitigs have not been applied in practice. Instead, most assembly software use the much simpler and more accurate unitig algorithm.…”

The omnitig framework can improve genome assembly contiguity in practice

“…a complete algorithm) in an idealised setting [Cai+19; Cai+21; Cai+20]. However, the omnitig algorithm requires complex data structures [Cai+21; GIP20] and omnitigs themselves are not safe in the presence of sequencing errors, missing coverage, or linear chromosomes [TM17]; as a result, omnitigs have not been applied in practice. Instead, most assembly software use the much simpler and more accurate unitig algorithm.…”

The omnitig framework can improve genome assembly contiguity in practice

On 2-Strong Connectivity Orientations of Mixed Graphs and Related Problems

Petri Nets with Special Structures