Completeness of qufinite ZXW calculus, a graphical language for finite-dimensional quantum theory

TL;DR

This paper introduces the qufinite ZXW calculus, a graphical language for finite-dimensional quantum theory, and proves its completeness by establishing a unique normal form for diagrams.

Contribution

The paper develops a complete, universal graphical calculus for finite-dimensional quantum theory, enabling diagrammatic reasoning equivalent to the category FHilb.

Findings

Proves the completeness of the qufinite ZXW calculus.

Establishes a unique normal form for diagrams in the calculus.

Demonstrates the calculus's applicability to various quantum domains.

Abstract

Finite-dimensional quantum theory serves as the theoretical foundation for quantum information and computation. Mathematically, it is formalized in the category FHilb, comprising all finite-dimensional Hilbert spaces and linear maps between them. However, there has not been a graphical language for FHilb which is both universal and complete and thus incorporates a set of rules rich enough to derive any equality of the underlying formalism solely by rewriting. In this paper, we introduce the qufinite ZXW calculus - a graphical language for reasoning about finite-dimensional quantum theory. We set up a unique normal form to represent an arbitrary tensor and prove the completeness of this calculus by demonstrating that any qufinite ZXW diagram can be rewritten into its normal form. This result implies the equivalence of the qufinite ZXW calculus and the category FHilb, leading to a purely diagrammatic framework for finite-dimensional quantum theory with the same reasoning power. In addition, we identify several domains where the application of the qufinite ZXW calculus holds promise. These domains include spin networks, interacting mixed-dimensional systems in quantum chemistry, quantum programming, high-level description of quantum algorithms, and mixed-dimensional quantum computing. Our work paves the way for a comprehensive diagrammatic description of quantum physics, opening the doors of this area to the wider public.