English

A composition theorem for parity kill number

Computational Complexity 2013-12-10 v1

Abstract

In this work, we study the parity complexity measures Cmin[f]{\mathsf{C}^{\oplus}_{\min}}[f] and DT[f]{\mathsf{DT^{\oplus}}}[f]. Cmin[f]{\mathsf{C}^{\oplus}_{\min}}[f] is the \emph{parity kill number} of ff, the fewest number of parities on the input variables one has to fix in order to "kill" ff, i.e. to make it constant. DT[f]{\mathsf{DT^{\oplus}}}[f] is the depth of the shortest \emph{parity decision tree} which computes ff. These complexity measures have in recent years become increasingly important in the fields of communication complexity \cite{ZS09, MO09, ZS10, TWXZ13} and pseudorandomness \cite{BK12, Sha11, CT13}. Our main result is a composition theorem for Cmin{\mathsf{C}^{\oplus}_{\min}}. The kk-th power of ff, denoted fkf^{\circ k}, is the function which results from composing ff with itself kk times. We prove that if ff is not a parity function, then Cmin[fk]Ω(Cmin[f]k).{\mathsf{C}^{\oplus}_{\min}}[f^{\circ k}] \geq \Omega({\mathsf{C}_{\min}}[f]^{k}). In other words, the parity kill number of ff is essentially supermultiplicative in the \emph{normal} kill number of ff (also known as the minimum certificate complexity). As an application of our composition theorem, we show lower bounds on the parity complexity measures of Sortk\mathsf{Sort}^{\circ k} and HIk\mathsf{HI}^{\circ k}. Here Sort\mathsf{Sort} is the sort function due to Ambainis \cite{Amb06}, and HI\mathsf{HI} is Kushilevitz's hemi-icosahedron function \cite{NW95}. In doing so, we disprove a conjecture of Montanaro and Osborne \cite{MO09} which had applications to communication complexity and computational learning theory. In addition, we give new lower bounds for conjectures of \cite{MO09,ZS10} and \cite{TWXZ13}.

Cite

@article{arxiv.1312.2143,
  title  = {A composition theorem for parity kill number},
  author = {Ryan O'Donnell and Xiaorui Sun and Li-Yang Tan and John Wright and Yu Zhao},
  journal= {arXiv preprint arXiv:1312.2143},
  year   = {2013}
}
R2 v1 2026-06-22T02:23:01.768Z