# Consistency of circuit lower bounds with bounded theories

**Authors:** Jan Bydzovsky, Jan Krajicek, Igor C. Oliveira

arXiv: 1905.12935 · 2023-06-22

## TL;DR

This paper explores the limitations of formal theories in proving circuit lower bounds for complexity classes like NP and P^NP, showing that certain bounds cannot be established within these theories, even with sophisticated arguments.

## Contribution

It demonstrates that specific logical theories cannot prove infinitely often circuit upper bounds for key complexity classes, extending previous results and highlighting fundamental proof limitations.

## Key findings

- Certain theories cannot prove infinitely often circuit upper bounds for NP and P^NP.
- Consistency of these limitations is unconditional and improves previous results.
- We formalize the interaction between logical proof systems and computational complexity.

## Abstract

Proving that there are problems in $\mathsf{P}^\mathsf{NP}$ that require boolean circuits of super-linear size is a major frontier in complexity theory. While such lower bounds are known for larger complexity classes, existing results only show that the corresponding problems are hard on infinitely many input lengths. For instance, proving almost-everywhere circuit lower bounds is open even for problems in $\mathsf{MAEXP}$. Giving the notorious difficulty of proving lower bounds that hold for all large input lengths, we ask the following question: Can we show that a large set of techniques cannot prove that $\mathsf{NP}$ is easy infinitely often? Motivated by this and related questions about the interaction between mathematical proofs and computations, we investigate circuit complexity from the perspective of logic.   Among other results, we prove that for any parameter $k \geq 1$ it is consistent with theory $T$ that computational class ${\mathcal C} \not \subseteq \textit{i.o.}\mathrm{SIZE}(n^k)$, where $(T, \mathcal{C})$ is one of the pairs: $T = \mathsf{T}^1_2$ and ${\mathcal C} = \mathsf{P}^\mathsf{NP}$, $T = \mathsf{S}^1_2$ and ${\mathcal C} = \mathsf{NP}$, $T = \mathsf{PV}$ and ${\mathcal C} = \mathsf{P}$. In other words, these theories cannot establish infinitely often circuit upper bounds for the corresponding problems. This is of interest because the weaker theory $\mathsf{PV}$ already formalizes sophisticated arguments, such as a proof of the PCP Theorem. These consistency statements are unconditional and improve on earlier theorems of [KO17] and [BM18] on the consistency of lower bounds with $\mathsf{PV}$.

## Full text

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## References

54 references — full list in the complete paper: https://tomesphere.com/paper/1905.12935/full.md

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