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Quantum Algorithms
A Sound and Complete Equational Theory for 3-Qubit Toffoli-Hadamard Circuits
arXiv
Authors: Matthew Amy, Neil J. Ross, Scott Wesley
Year
2024
Paper ID
65369
Status
Preprint
Abstract Read
~2 min
Abstract Words
161
Citations
N/A
Abstract
We give a sound and complete equational theory for 3-qubit quantum circuits over the Toffoli-Hadamard gate set { X, CX, CCX, H }. That is, we introduce a collection of true equations among Toffoli-Hadamard circuits on three qubits that is sufficient to derive any other true equation between such circuits. To obtain this equational theory, we first consider circuits over the Toffoli-K gate set { X, CX, CCX, K }, where K = HxH. The Toffoli-Hadamard and Toffoli-K gate sets appear similar, but they are crucially different on exactly three qubits. Indeed, in this case, the former generates an infinite group of operators, while the latter generates the finite group of automorphisms of the well-known E8 lattice. We take advantage of this fact, and of the theory of automorphism groups of lattices, to obtain a sound and complete collection of equations for Toffoli-K circuits. We then extend this equational theory to one for Toffoli-Hadamard circuits by leveraging prior work of Li et al. on Toffoli-Hadamard operators.
Why This Paper Matters
- It adds a 2024 reference point for readers tracking recent quantum research.
- We give a sound and complete equational theory for 3-qubit quantum circuits over the Toffoli-Hadamard gate set X, CX, CCX, H .
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