English

A Tight Composition Theorem for the Randomized Query Complexity of Partial Functions

Computational Complexity 2020-12-08 v2 Quantum Physics

Abstract

We prove two new results about the randomized query complexity of composed functions. First, we show that the randomized composition conjecture is false: there are families of partial Boolean functions ff and gg such that R(fg)R(f)R(g)R(f\circ g)\ll R(f) R(g). In fact, we show that the left hand side can be polynomially smaller than the right hand side (though in our construction, both sides are polylogarithmic in the input size of ff). Second, we show that for all ff and gg, R(fg)=Ω(noisyR(f)R(g))R(f\circ g)=\Omega(\mathop{noisyR}(f)\cdot R(g)), where noisyR(f)\mathop{noisyR}(f) is a measure describing the cost of computing ff on noisy oracle inputs. We show that this composition theorem is the strongest possible of its type: for any measure M()M(\cdot) satisfying R(fg)=Ω(M(f)R(g))R(f\circ g)=\Omega(M(f)R(g)) for all ff and gg, it must hold that noisyR(f)=Ω(M(f))\mathop{noisyR}(f)=\Omega(M(f)) for all ff. We also give a clean characterization of the measure noisyR(f)\mathop{noisyR}(f): it satisfies noisyR(f)=Θ(R(fgapmajn)/R(gapmajn))\mathop{noisyR}(f)=\Theta(R(f\circ gapmaj_n)/R(gapmaj_n)), where nn is the input size of ff and gapmajngapmaj_n is the n\sqrt{n}-gap majority function on nn bits.

Keywords

Cite

@article{arxiv.2002.10809,
  title  = {A Tight Composition Theorem for the Randomized Query Complexity of Partial Functions},
  author = {Shalev Ben-David and Eric Blais},
  journal= {arXiv preprint arXiv:2002.10809},
  year   = {2020}
}

Comments

43 pages

R2 v1 2026-06-23T13:52:57.303Z