What question did this study set out to answer?

The aim is to explore the role of topological methods in understanding polynomial-time computation complexity.

February 6, 2026Open Access

Algorithmic Topological Assembly and the Structural Boundary of Polynomial-Time Computation

Key Points

The aim is to explore the role of topological methods in understanding polynomial-time computation complexity.
Extended the topological approach to computational complexity via compatibility complexes.
Defined a new invariant, AET∗₄,alg, to quantify topological assembly compatible with computation.
Proved findings using relative homology, spectral sequences, and discrete Morse theory.
No polynomial-time algorithm can create or maintain nontrivial fourth homology in the examined filtrations.
Attempts to find counterexamples are structurally unsuccessful, supporting the main conclusions.

Abstract

This paper extends a topological approach to computational complexity by incorporating the structure of polynomial-time algorithms into the analysis of compatibility complexes. Building on earlier results showing that shallow and logarithmic-depth computation enforces low-dimensional topological simplicity, and that NP-complete problems exhibit high assembly complexity, it introduces algorithmic filtrations induced by execution traces. A new invariant, AET∗₄,alg, is defined to measure topological assembly compatible with computation. Using relative homology, spectral sequences, and discrete Morse theory, the paper proves that no polynomial-time algorithm can generate or sustain nontrivial fourth homology along such filtrations. Systematic attempts to construct counterexamples fail for structural reasons. The result isolates bounded algorithmic assembly as a necessary condition for polynomial-time computation.

Algorithmic Topological Assembly and the Structural Boundary of Polynomial-Time Computation

Key Points

Abstract

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