Related papers: Evaluation of variational quantum states entanglement on a quantum computer by the mean value of spin

Evaluation of variational quantum states entanglement on a quantum computer by the mean value of spin

URL: http://arxiv.org/abs/2301.03885v1
Date: Tue, 10 Jan 2023 10:18:54 GMT
Title: Evaluation of variational quantum states entanglement on a quantum computer by the mean value of spin
Authors: Kh. P. Gnatenko
Abstract summary: We study n-qubit quantum states prepared by a variational circuit with a layer formed by the rotational gates and two-qubit controlled phase gates. The entanglement of a qubit with other qubits in the variational quantum states is determined by the angles of rotational gates. The dependence of the geometric measure of entanglement of variational quantum states on their parameters is quantified on IBM's quantum computer.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The geometric measure of entanglement of variational quantum states is studied on the basis of its relation with the mean value of spin. We examine n-qubit quantum states prepared by a variational circuit with a layer formed by the rotational gates and two-qubit controlled phase gates. The variational circuit is a generalization of that used for preparing quantum Generative Adversarial Network states. The entanglement of a qubit with other qubits in the variational quantum states is determined by the angles of rotational gates that act on the qubit and qubits entangled with it by controlled phase gates and also their parameters. In the case of one layer variational circuit, the states can be associated with graphs with vertices representing qubits and edges corresponding to two-qubit gates. The geometric measure of entanglement of a qubit with other qubits in the quantum graph state depends on the properties of the vertex that represents it in the graph, namely it depends on the vertex degree. The dependence of the geometric measure of entanglement of variational quantum states on their parameters is quantified on IBM's quantum computer.

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