English

Lower bounds for planar Arithmetic Circuits

Computational Complexity 2025-09-16 v1

Abstract

Arithmetic circuits are a natural well-studied model for computing multivariate polynomials over a field. In this paper, we study planar arithmetic circuits. These are circuits whose underlying graph is planar. In particular, we prove an Ω(nlogn)\Omega(n\log n) lower bound on the size of planar arithmetic circuits computing explicit bilinear forms on 2n2n variables. As a consequence, we get an Ω(nlogn)\Omega(n\log n) lower bound on the size of arithmetic formulas and planar algebraic branching programs computing explicit bilinear forms on 2n2n variables. This is the first such lower bound on the formula complexity of an explicit bilinear form. In the case of read-once planar circuits, we show Ω(n2)\Omega(n^2) size lower bounds for computing explicit bilinear forms on 2n2n variables. Furthermore, we prove fine separations between the various planar models of computations mentioned above. In addition to this, we look at multi-output planar circuits and show Ω(n4/3)\Omega(n^{4/3}) size lower bound for computing an explicit linear transformation on nn-variables. For a suitable definition of multi-output formulas, we extend the above result to get an Ω(n2/logn)\Omega(n^2/\log n) size lower bound. As a consequence, we demonstrate that there exists an nn-variate polynomial computable by an n1+o(1)n^{1 + o(1)}-sized formula such that any multi-output planar circuit (resp., multi-output formula) simultaneously computing all its first-order partial derivatives requires size Ω(n4/3)\Omega(n^{4/3}) (resp., Ω(n2/logn)\Omega(n^2/\log n)). This shows that a statement analogous to that of Baur, Strassen (1983) does not hold in the case of planar circuits and formulas.

Cite

@article{arxiv.2509.11322,
  title  = {Lower bounds for planar Arithmetic Circuits},
  author = {C. Ramya and Pratik Shastri},
  journal= {arXiv preprint arXiv:2509.11322},
  year   = {2025}
}
R2 v1 2026-07-01T05:35:37.567Z