The crossing number \mboxcr(G) of a graph G=(V,E) is the smallest number of edge crossings over all drawings of G in the plane. For any k≥1, the k-planar crossing number of G, \mboxcrk(G), is defined as the minimum of \mboxcr(G1)+\mboxcr(G2)+…+\mboxcr(Gk) over all graphs G1,G2,…,Gk with ∪i=1kGi=G. Pach et al. [\emph{Computational Geometry: Theory and Applications} {\bf 68} 2--6, (2018)] showed that for every k≥1, we have \mboxcrk(G)≤(k22−k31)\mboxcr(G) and that this bound does not remain true if we replace the constant k22−k31 by any number smaller than k21. We improve the upper bound to k21(1+o(1)) as k→∞. For the class of bipartite graphs, we show that the best constant is exactly k21 for every k. The results extend to the rectilinear variant of the k-planar crossing number.
@article{arxiv.1807.03430,
title = {Using Block Designs in Crossing Number Bounds},
author = {John Asplund and Eva Czabarka and Gregory Clark and Garner Cochran and Arran Hamm and Gwen Spencer and Laszlo Szekely and Libby Taylor and Zhiyu Wang},
journal= {arXiv preprint arXiv:1807.03430},
year = {2018}
}