English

Lifting for Arbitrary Gadgets

Computational Complexity 2025-04-01 v1

Abstract

We prove a sensitivity-to-communication lifting theorem for arbitrary gadgets. Given functions f:{0,1}n{0,1}f: \{0,1\}^n\to \{0,1\} and g:X×Y{0,1}g : \mathcal X\times \mathcal Y\to \{0,1\}, denote fg(x,y):=f(g(x1,y1),,g(xn,yn))f\circ g(x,y) := f(g(x_1,y_1),\ldots,g(x_n,y_n)). We show that for any ff with sensitivity ss and any gg, D(fg)s(Ω(D(g))logrk(g)logrk(g)),D(f\circ g) \geq s\cdot \bigg(\frac{\Omega(D(g))}{\log\mathsf{rk}(g)} - \log\mathsf{rk}(g)\bigg), where D()D(\cdot) denotes the deterministic communication complexity and rk(g)\mathsf{rk}(g) is the rank of the matrix associated with gg. As a corollary, we get that if D(g)D(g) is a sufficiently large constant, D(fg)=Ω(min{s,d}D(g))D(f\circ g) = \Omega(\min\{s,d\}\cdot \sqrt{D(g)}), where ss and dd denote the sensitivity and degree of ff. In particular, computing the OR of nn copies of gg requires Ω(nD(g))\Omega(n\cdot\sqrt{D(g)}) bits.

Cite

@article{arxiv.2503.24351,
  title  = {Lifting for Arbitrary Gadgets},
  author = {Siddharth Iyer},
  journal= {arXiv preprint arXiv:2503.24351},
  year   = {2025}
}
R2 v1 2026-06-28T22:40:59.022Z