SUPERCONDUCTING QUANTUM CIRCUIT

Organization Name

NEC Corporation

Inventor(s)

Yohei Kawakami of Tokyo (JP)

Yoshiro Urade of Tokyo (JP)

Yoshihito Hashimoto of Tokyo (JP)

Tsuyoshi Yamamoto of Tokyo (JP)

SUPERCONDUCTING QUANTUM CIRCUIT - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240016068 titled 'SUPERCONDUCTING QUANTUM CIRCUIT

Simplified Explanation

The abstract describes a superconducting quantum circuit that includes a resonator with a superconducting quantum interference device (SQUID) and a capacitor forming a closed loop. It also includes a control line connected to a control port and magnetically coupled to the SQUID. The control line has two lines with different characteristic impedances indicating different impedance values.

• The patent application describes a superconducting quantum circuit with a closed loop resonator and a SQUID.
• The circuit includes a control line that is magnetically coupled to the SQUID and has two lines with different characteristic impedances.
• The characteristic impedance values of the two lines are different from each other.

Potential Applications:

• Quantum computing: The superconducting quantum circuit can be used as a building block for quantum computers, enabling the manipulation and control of quantum states.
• Quantum communication: The circuit can be utilized in quantum communication systems for secure transmission of information using quantum entanglement.

Problems Solved:

• Control and manipulation of quantum states: The circuit provides a means to control and manipulate quantum states, which is crucial for various quantum technologies.
• Impedance matching: The use of two lines with different characteristic impedances allows for better impedance matching in the circuit, reducing signal reflections and losses.

Benefits:

• Enhanced quantum control: The circuit enables precise control and manipulation of quantum states, leading to improved performance in quantum computing and communication.
• Improved signal integrity: The use of different characteristic impedances in the control line helps in achieving better signal transmission and reducing losses.
• Scalability: The circuit can be scaled up to larger systems, allowing for the development of more complex quantum devices and systems.

Original Abstract Submitted

a superconducting quantum circuit includes: a first resonator having a superconducting quantum interference device and a capacitor that forms a closed loop together with the superconducting quantum interference device; and a control line being connected to a first control port and magnetically coupled to the superconducting quantum interference device, wherein the control line includes at least a first line having a characteristic impedance that indicates a first impedance value, and a second line being provided closer to a portion magnetically coupled to the superconducting quantum interference device than the first line and having a characteristic impedance that indicates a second impedance value being different from the first impedance value.