Operationalism, Causality, and Quantum Theory: a mostly time symmetric perspective

TL;DR

This book explores operational probabilistic theories from a mostly time symmetric perspective, demonstrating equivalences, modeling complex causal structures, and ensuring physicality and causality in quantum operations.

Contribution

It introduces a comprehensive, time symmetric framework for operational probabilistic theories, including quantum theory, with new theorems on causal dilations and complex operations.

Findings

Time symmetric perspective is equivalent to forward perspective for simple operations.

Physicality constraints prevent anomalous signalling in complex operations.

Develops diagrammatic notation and proves causal dilation theorems.

Abstract

This is a book about operational probabilistic theories. The standard approach in such theories is from a time forward perspective. In this book we mostly take a time symmetric perspective. This presents a branding problem. Is this a niche book merely about time symmetry? No. This is a comprehensive book about operational probabilistic theories, but mostly from a time symmetric perspective. In fact, this book consists of (1) a simple book about simple operations having simple causal structure (where all the inputs are before all the outputs), and (2) a complex book about complex operations that can have complicated causal structure (a complex operation is equipped with a causal diagram). For the simple case we are able to show that the time symmetric perspective is equivalent to the time forward perspective. In each book we set up (A) operational probabilistic theories (OPTs) in terms of operations, (B) Operational Quantum Theory (OQT) in terms of operator tensors which correspond to operations, and (C) the theory of Hilbert objects which can be doubled up to give operator tensors. Operations are required to be physical which guarantees that circuits built out of operations have probabilities between 0 and 1 and that certain causality conditions are met. We prove that when we wire together operations the resulting networks are also physical. We model Sorkin's impossible measurements with complex operations and show that physicality prevents anomalous signalling. We develop diagrammatic notation for Hilbert objects. This includes mirrors for doubling up and mirror theorems. We use this framework to prove time symmetric causal dilation theorems for various causal diagrams.