Abstract: Methods, apparatuses, and systems include acquiring initial environmental information corresponding to a superconducting qubit received from a superconducting circuit, the superconducting circuit being in an environment; determining first environmental information corresponding to the superconducting qubit in response to a quantum energy level of the superconducting qubit being a first preset energy level; determining second environmental information corresponding to the superconducting qubit in response to the quantum energy level of the superconducting qubit being a second preset energy level; determining effective environmental information based on the first environmental information and the second environmental information; and determining arbitrary-order correlation information for identifying an environmental noise based on the effective environmental information and the initial environmental information.

Abstract: A superconducting circuit having a Josephson junction includes a first electrode layer for signal transmission; a second electrode layer for signal transmission; and an insulating layer arranged between the first electrode layer and the second electrode layer to form a Josephson junction, wherein, the first electrode layer and the second electrode layer are composed of a preset material, the insulating layer is composed of a compound corresponding to the preset material, and the preset material includes a non-aluminum superconducting material to prolong a coherence time of superconducting qubits.

Abstract: A layout generation method includes: determining a quantum device type; acquiring an original script corresponding to the quantum device type, wherein a device parameter is defined in the original script; acquiring a target value of the device parameter; assigning the target value to the device parameter to obtain a target script of a target quantum device corresponding to the quantum device type; and generating, based on the target script, a quantum chip layout including the target quantum device.

Abstract: A method for optimizing a quantum circuit is disclosured. The method comprises acquiring a representation of a quantum circuit comprising one or more qubits, transforming, by linear transformation, first Hamiltonian corresponding to the quantum circuit to generate modes, generating a third Hamiltonian by removing the free modes from a second Hamiltonian in which free modes are decoupled from non-free the second Hamiltonian, simulating a behavior of the quantum circuit using the third Hamiltonian, and adjusting a design of the quantum circuit based on the simulated behavior of the quantum circuit.

Abstract: Methods, apparatuses, and systems include acquiring initial environmental information corresponding to a superconducting qubit received from a superconducting circuit, the superconducting circuit being in an environment; determining first environmental information corresponding to the superconducting qubit in response to a quantum energy level of the superconducting qubit being a first preset energy level; determining second environmental information corresponding to the superconducting qubit in response to the quantum energy level of the superconducting qubit being a second preset energy level; determining effective environmental information based on the first environmental information and the second environmental information; and determining arbitrary-order correlation information for identifying an environmental noise based on the effective environmental information and the initial environmental information.

Abstract: A superconducting circuit having a Josephson junction includes a first electrode layer for signal transmission; a second electrode layer for signal transmission; and an insulating layer arranged between the first electrode layer and the second electrode layer to form a Josephson junction, wherein, the first electrode layer and the second electrode layer are composed of a preset material, the insulating layer is composed of a compound corresponding to the preset material, and the preset material includes a non-aluminum superconducting material to prolong a coherence time of superconducting qubits.

Abstract: Methods, apparatuses, and systems include acquiring initial environmental information corresponding to a superconducting qubit received from a superconducting circuit, the superconducting circuit being in an environment; determining first environmental information corresponding to the superconducting qubit in response to a quantum energy level of the superconducting qubit being a first preset energy level; determining second environmental information corresponding to the superconducting qubit in response to the quantum energy level of the superconducting qubit being a second preset energy level; determining effective environmental information based on the first environmental information and the second environmental information; and determining arbitrary-order correlation information for identifying an environmental noise based on the effective environmental information and the initial environmental information.