@@ -469,7 +469,7 @@ A core component in optimising quantum computers is identifying which resources
Furthermore, the compiler stack and associated library set of post-classical resources will naturally become a software tool for benchmarking quantum devices, greatly enhancing the maturity of quantum computing technology.
The four major work packages of the project are structured into
various themes: the relation between \zx and other quantum computing representations (\ref{wp:frontend}); necessary theoretical developments of \zx(\ref{wp:representation}) and the identification of quantum-unique resources; optimisation strategies independent of implementations (\ref{wp:theory}); using annotated \zx to compile and optimise for specific hardware.(\ref{wp:usefulstuff}).
various themes: the relation between \zx and other quantum computing representations (\ref{wp:frontend}); necessary theoretical developments of \zx and the identification of quantum-unique resources (\ref{wp:representation}); optimisation strategies independent of implementations (\ref{wp:theory}); using annotated \zx to compile and optimise for specific hardware.(\ref{wp:usefulstuff}).
\subsubsection{A quantum compiler stack}
\label{sec:progr-lang-supp}
...
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@@ -708,8 +708,8 @@ This will make possible a reduction in the resources used in any particular hard
\TODOb{For some reason physics is missing: CQM/ZX emerged from compositional physical considerations.}
As shown the schema at the beginning of \S\ref{sec:summary:-},
the ambitious vertical structure of this project requires a uniquely
diverse range of expertise: from \textbf{Software Engineering \& Formal Methods} at the high level, through \textbf{Quantum Computation} and logic at the mid-level, down to quantum \textbf{Systems Architecture} at the low-level.
This project unites those working in quantum information theory from logical and pure mathematical perspectives with those working on practical error correction, quantum
diverse range of expertise: from \textbf{Software Engineering \& Formal Methods} at the high level, through \newt{\textbf{Quantum Physics},}\textbf{Quantum Computation} and logic at the mid-level, down to quantum \textbf{Systems Architecture} at the low-level.
This project unites those working in \newt{quantum physics from operational compositionality, and}quantum information theory from logical and pure mathematical perspectives with those working on practical error correction, quantum
hardware, and more generally programming language
design and system engineering.
It thus provides a unique opportunity for theoretical insight to inform future technology, and for technological problems to drive future theory.
