Complexity of graph-state preparation by Clifford circuits

Abstract

In this work, we study the complexity of graph-state preparation. We consider general quantum algorithms consisting of Clifford operations acting on at most two qubits for graph-state preparations. We define the CZ-complexity of a graph state |G as the minimum number of two-qubit Clifford operations (excluding single-qubit Clifford operations) for generating |G from a trivial state |0 n. We first prove that a graph state |G is generated by at most t two-qubit Clifford operations if and only if |G is generated by at most t controlled-Z (CZ) operations. We next prove that a graph state |G is generated from another graph state |H by t CZ operations if and only if the graph G is generated from H by some combinatorial graph transformation with cost t. As the main results, we show a connection between the CZ-complexity of graph state |G and the rank-width of the graph G. Indeed, we prove that for any graph G with n vertices and rank-width r, 1. The CZ-complexity of |G is O(rn). 2. If G is connected, the CZ-complexity of |G is at least n + r - 2. We also demonstrate the existence of graph states whose CZ-complexities are close to the upper and lower bounds. Finally, we present quantum algorithms for preparing graph states for three specific graph classes related to intervals: interval graphs, interval containment graphs, and circle graphs. We prove that the CZ-complexity is O(n) for interval graphs, and O(n n) for both interval containment graphs and circle graphs.