17897727. MULTI-MODE RESONATOR FOR QUANTUM COMPUTING ELEMENT simplified abstract (Samsung Electronics Co., Ltd.)
MULTI-MODE RESONATOR FOR QUANTUM COMPUTING ELEMENT
Organization Name
Inventor(s)
MULTI-MODE RESONATOR FOR QUANTUM COMPUTING ELEMENT - A simplified explanation of the abstract
This abstract first appeared for US patent application 17897727 titled 'MULTI-MODE RESONATOR FOR QUANTUM COMPUTING ELEMENT
Simplified Explanation
The patent application describes a multi-mode resonator for a quantum computing element. The resonator includes a cavity with two side surfaces facing each other, and iris regions are positioned along one side surface of the cavity. When electromagnetic energy is supplied to the cavity, the iris regions overlap with the electromagnetic fields that form in the cavity in a specific mode.
- The patent application describes a multi-mode resonator for a quantum computing element.
- The resonator includes a cavity with two side surfaces facing each other.
- Iris regions are positioned along one side surface of the cavity.
- The iris regions overlap with the electromagnetic fields that form in the cavity in a specific mode when electromagnetic energy is supplied.
Potential Applications
- Quantum computing
- Quantum information processing
- Quantum communication
Problems Solved
- Enhances the functionality and performance of quantum computing elements
- Enables the manipulation and control of electromagnetic fields in a multi-mode resonator
Benefits
- Improved efficiency and accuracy in quantum computing operations
- Increased control over electromagnetic fields in quantum computing systems
- Potential for faster and more powerful quantum computing capabilities
Original Abstract Submitted
A multi-mode resonator for a quantum computing element is included. In one general aspect, an apparatus including a multi-mode electromagnetic resonator includes a structure configured with a cavity therein that extends lengthwise in a first direction, the cavity including a first side surface and a second side surface facing each other, iris regions are at positions along the first direction on the first side surface of the cavity, the iris regions are arranged to overlap respective electromagnetic fields that form in the cavity in a target mode when electromagnetic energy is supplied to the cavity.