New bounds on the cardinality of Hausdorff spaces and regular spaces

Abstract: Using weaker versions of the cardinal function $\psi_c(X)$, we derive a series of new bounds for the cardinality of Hausdorff spaces and regular spaces that do not involve $\psi_c(X)$ nor its variants at all. For example, we show if $X$ is regular then $|X|\leq 2^{c(X)^{\pi\chi(X)}}$ and $|X|\leq 2^{c(X)\pi\chi(X)^{ot(X)}}$, where the cardinal function $ot(X)$, introduced by Tkachenko, has the property $ot(X)\leq\min{t(X),c(X)}$. It follows from the latter that a regular space with cellularity at most $\mathfrak{c}$ and countable $\pi$-character has cardinality at most $2^\mathfrak{c}$. For a Hausdorff space $X$ we show $|X|\leq 2^{d(X)^{\pi\chi(X)}}$, $|X|\leq d(X)^{\pi\chi(X)^{ot(X)}}$, and $|X|\leq 2^{\pi w(X)^{dot(X)}}$, where $dot(X)\leq\min{ot(X),\pi\chi(X)}$. None of these bounds involve $\psi_c(X)$ or $\psi(X)$. By introducing the cardinal functions $w\psi_c(X)$ and $d\psi_c(X)$ with the property $w\psi_c(X)d\psi_c(X)\leq\psi_c(X)$ for a Hausdorff space $X$, we show $|X|\leq\pi\chi(X)^{c(X)w\psi_c(X)}$ if $X$ is regular and $|X|\leq\pi\chi(X)^{c(X)d\psi_c(X)w\psi_c(X)}$ if $X$ is Hausdorff. This improves results of Sapirovskii and Sun. It is also shown that if $X$ is Hausdorff then $|X|\leq 2^{d(X)w\psi_c(X)}$, which appears to be new even in the case where $w\psi_c(X)$ is replaced with $\psi_c(X)$. Compact examples show that $\psi(X)$ cannot be replaced with $d\psi_c(X)w\psi_c(X)$ in the bound $2^{\psi(X)}$ for the cardinality of a compact Hausdorff space $X$. Likewise, $\psi(X)$ cannot be replaced with $d\psi_c(X)w\psi_c(X)$ in the Arhangel'skii-Sapirovskii bound $2^{L(X)t(X)\psi(X)}$ for the cardinality of a Hausdorff space $X$. Finally, we make several observations concerning homogeneous spaces in this connection.