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A Novel Quantum State Transfer Method Based on Hamiltonian Learning

A technology of Hamiltonian and transfer method, applied in the field of new quantum state transfer, to achieve the effect of small loss, strong confidentiality and high fidelity

Active Publication Date: 2022-02-15
国科蓝盾(北京)科技有限公司
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  • Abstract
  • Description
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Problems solved by technology

[0005] However, in practical applications, the Hamiltonian in a specific physical system is generally uncertain, and the specific form of the Hamiltonian needs to be determined through a large number of experiments; moreover, due to the existence of the coin operator, although the discrete-time quantum walk has More flexibility, the disadvantage is that if the degrees of the vertices in the graph are not all the same, local control of the coin is required

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  • A Novel Quantum State Transfer Method Based on Hamiltonian Learning
  • A Novel Quantum State Transfer Method Based on Hamiltonian Learning
  • A Novel Quantum State Transfer Method Based on Hamiltonian Learning

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Embodiment Construction

[0040] Such as figure 1 Shown is the method flow diagram of the method of the present invention: this novel quantum state transfer method based on Hamiltonian learning provided by the present invention comprises the following steps:

[0041] S1. The sender prepares the input state; the input state is the transferred input quantum state: the known quantum input state of the sender Each |ψ in > is a quantum input mode in that passes through the dimensionless orthogonal components and Represents, and the complex magnitude of the quantum input mode in is The Wigner function is W(γ);

[0042] S2. The sender performs forward unitary evolution on the prepared input state; specifically, the following formula is used as the forward unitary evolution operator:

[0043] U(t)=e -iH(V)t

[0044] where U(t) is the forward unitary evolution operator; H(V) is the parameterized Hamiltonian; t is the evolution time;

[0045] At the same time, the parameterized Hamiltonian H(V) is de...

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Abstract

The invention discloses a new quantum state transfer method based on Hamiltonian learning, which comprises the steps of preparing the input state by the sender and performing forward unitary evolution on it; the sender sends the input state after forward evolution to the Receiver; the receiver performs reverse unitary evolution of the received evolution quantum state and performs likelihood evaluation; the receiver uses Bayesian rule to update and resample the probability distribution of the measurement output data; the receiver updates and resamples according to As a result, it is judged whether the input state exists and is perfectly transferred to the receiver with probability 1 at a certain moment. The method of the present invention can be evaluated by the likelihood function and the mean square error, the likelihood function is the fidelity of the quantum state transfer, and the mean square error is the Bayesian loss, which is exponential with the measurement times of the interactive quantum likelihood evaluation experiment decline. Therefore, the method of the invention has the characteristics of strong confidentiality, high fidelity and small loss.

Description

technical field [0001] The invention belongs to the field of quantum communication, and in particular relates to a novel quantum state transfer method based on Hamiltonian learning. Background technique [0002] With the development of economy and technology, people's demand for information is increasing day by day, and information interaction has become inseparable from people's life. [0003] With the development of communication technology, there are a large number of phenomena in the process of information transmission, such as eavesdropping, interception, tampering and forgery. In order to reduce or avoid these situations, a reliable information transmission system needs to be established. The commonly used methods of information transmission include letters, telephones, computers, television, advertisements, etc. On the one hand, these transmission methods require information carriers such as text, language, electromagnetic waves or electrical signals; on the other h...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): H04B10/70
CPCH04B10/70
Inventor 施荣华冯艳艳石金晶陈淑慧郭迎
Owner 国科蓝盾(北京)科技有限公司
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