Dagger linear logic for categorical quantum mechanics

Robin Cockett,Priyaa Srinivasan,Cole Comfort

doi:10.46298/lmcs-17(4:8)2021

Abstract

Categorical quantum mechanics exploits the dagger compact closed structure of finite dimensional Hilbert spaces, and uses the graphical calculus of string diagrams to facilitate reasoning about finite dimensional processes. A significant portion of quantum physics, however, involves reasoning about infinite dimensional processes, and it is well-known that the category of all Hilbert spaces is not compact closed. Thus, a limitation of using dagger compact closed categories is that one cannot directly accommodate reasoning about infinite dimensional processes. A natural categorical generalization of compact closed categories, in which infinite dimensional spaces can be modelled, is *-autonomous categories and, more generally, linearly distributive categories. This article starts the development of this direction of generalizing categorical quantum mechanics. An important first step is to establish the behaviour of the dagger in these more general settings. Thus, these notes simultaneously develop the categorical semantics of multiplicative dagger linear logic. The notes end with the definition of a mixed unitary category. It is this structure which is subsequently used to extend the key features of categorical quantum mechanics.

Highlights

Categorical quantum mechanics (CQM), as described in [CK17, HJ19], employs a graphical calculus for †-compact closed categories (†-KCCs) to study quantum processes within the †-KCC of finite dimensional Hilbert spaces (FHilb)
The graphical calculus is the proof theory of a compact fragment of multiplicative †-linear logic [Dun06]. This programme of CQM was initiated by Abramsky and Coecke’s seminal paper [AC04] and it has allowed much of the structure of FHilb to be abstracted away and absorbed into the graphical calculus
First we show that the unitary construction on a †-isomix category produces a mixed unitary category (MUC) which is couniversal

Summary

Introduction

Categorical quantum mechanics (CQM), as described in [CK17, HJ19], employs a graphical calculus for †-compact closed categories (†-KCCs) to study quantum processes within the †-KCC of finite dimensional Hilbert spaces (FHilb). The graphical calculus is the proof theory of a compact fragment of multiplicative †-linear logic [Dun06]. This programme of CQM was initiated by Abramsky and Coecke’s seminal paper [AC04] and it has allowed much of the structure of FHilb to be abstracted away and absorbed into the graphical calculus. A well-known limitation of compact closed categories, is that, while they model finite dimensional Hilbert spaces, they do not model infinite dimensional spaces [Heu08]. From a categorical perspective, Partially supported by NSERC, Canada

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