4,889 research outputs found
Quantum Theory is a Quasi-stochastic Process Theory
There is a long history of representing a quantum state using a
quasi-probability distribution: a distribution allowing negative values. In
this paper we extend such representations to deal with quantum channels. The
result is a convex, strongly monoidal, functorial embedding of the category of
trace preserving completely positive maps into the category of quasi-stochastic
matrices. This establishes quantum theory as a subcategory of quasi-stochastic
processes. Such an embedding is induced by a choice of minimal informationally
complete POVM's. We show that any two such embeddings are naturally isomorphic.
The embedding preserves the dagger structure of the categories if and only if
the POVM's are symmetric, giving a new use of SIC-POVM's, objects that are of
foundational interest in the QBism community. We also study general convex
embeddings of quantum theory and prove a dichotomy that such an embedding is
either trivial or faithful.Comment: In Proceedings QPL 2017, arXiv:1802.0973
PyZX: Large Scale Automated Diagrammatic Reasoning
The ZX-calculus is a graphical language for reasoning about ZX-diagrams, a
type of tensor networks that can represent arbitrary linear maps between
qubits. Using the ZX-calculus, we can intuitively reason about quantum theory,
and optimise and validate quantum circuits. In this paper we introduce PyZX, an
open source library for automated reasoning with large ZX-diagrams. We give a
brief introduction to the ZX-calculus, then show how PyZX implements methods
for circuit optimisation, equality validation, and visualisation and how it can
be used in tandem with other software. We end with a set of challenges that
when solved would enhance the utility of automated diagrammatic reasoning.Comment: In Proceedings QPL 2019, arXiv:2004.1475
Universal MBQC with generalised parity-phase interactions and Pauli measurements
We introduce a new family of models for measurement-based quantum computation
which are deterministic and approximately universal. The resource states which
play the role of graph states are prepared via 2-qubit gates of the form
. When , these are equivalent, up
to local Clifford unitaries, to graph states. However, when , their
behaviour diverges in two important ways. First, multiple applications of the
entangling gate to a single pair of qubits produces non-trivial entanglement,
and hence multiple parallel edges between nodes play an important role in these
generalised graph states. Second, such a state can be used to realise
deterministic, approximately universal computation using only Pauli and
measurements and feed-forward. Even though, for , the relevant resource
states are no longer stabiliser states, they admit a straightforward, graphical
representation using the ZX-calculus. Using this representation, we are able to
provide a simple, graphical proof of universality. We furthermore show that for
every this family is capable of producing all Clifford gates and all
diagonal gates in the -th level of the Clifford hierarchy.Comment: 19 pages, accepted for publication in Quantum (quantum-journal.org).
A previous version of this article had the title: "Universal MBQC with
M{\o}lmer-S{\o}rensen interactions and two measurement bases
Pure Maps between Euclidean Jordan Algebras
We propose a definition of purity for positive linear maps between Euclidean
Jordan Algebras (EJA) that generalizes the notion of purity for quantum
systems. We show that this definition of purity is closed under composition and
taking adjoints and thus that the pure maps form a dagger category (which sets
it apart from other possible definitions.) In fact, from the results presented
in this paper, it follows that the category of EJAs with positive contractive
linear maps is a dagger-effectus, a type of structure originally defined to
study von Neumann algebras in an abstract categorical setting. In combination
with previous work this characterizes EJAs as the most general systems allowed
in a generalized probabilistic theory that is simultaneously a dagger-effectus.
Using the dagger structure we get a notion of dagger-positive maps of the form
f = g*g. We give a complete characterization of the pure dagger-positive maps
and show that these correspond precisely to the Jordan algebraic version of the
sequential product that maps (a,b) to sqrt(a) b sqrt(a). The notion of
dagger-positivity therefore characterizes the sequential product.Comment: In Proceedings QPL 2018, arXiv:1901.0947
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