DYNAMIC ADAPTIVE THRESHOLDING FOR QUBIT RESET

Organization Name

International Business Machines Corporation

Inventor(s)

Ken Inoue of Elmsford NY (US)

MAIKA Takita of Croton on Hudson NY (US)

Antonio Corcoles-gonzalez of Mount Kisco NY (US)

Scott Douglas Lekuch of New York NY (US)

DYNAMIC ADAPTIVE THRESHOLDING FOR QUBIT RESET - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240020569 titled 'DYNAMIC ADAPTIVE THRESHOLDING FOR QUBIT RESET

Simplified Explanation

The patent application relates to a process for dynamically determining a threshold to determine the state of a qubit and applying the threshold to operate a pulse to de-excite the qubit. The system includes a memory storing computer executable components and a processor executing these components. The decision component determines a threshold to apply to the measurement of the qubit's state based on a probability distribution. Measurements on one side of the threshold indicate the qubit is in the ground state, while measurements on the other side indicate the qubit is in an excited state.

• The patent application describes a system and method for dynamically determining a threshold to measure the state of a qubit and operate a pulse to de-excite the qubit.
• The system includes a memory and a processor that execute computer executable components.
• The decision component determines a threshold to apply to the measurement of the qubit's state based on a probability distribution.
• Measurements on one side of the threshold indicate the qubit is in the ground state, while measurements on the other side indicate the qubit is in an excited state.

Potential applications of this technology:

• Quantum computing: This technology can be applied in quantum computing systems to accurately measure and control the state of qubits, which are the fundamental units of information in quantum computers.
• Quantum communication: By accurately determining the state of qubits, this technology can enhance the reliability and security of quantum communication systems.
• Quantum sensing: The ability to dynamically determine thresholds for qubit measurements can improve the sensitivity and accuracy of quantum sensors, enabling advancements in fields such as metrology and imaging.

Problems solved by this technology:

• Accurate qubit state measurement: The dynamic determination of thresholds allows for more precise measurement of the state of qubits, reducing errors and improving the reliability of quantum systems.
• Efficient qubit control: By applying the appropriate threshold, the system can efficiently operate pulses to de-excite the qubit, optimizing the performance of quantum devices.
• Adaptability to different qubit states: The probability distribution-based approach enables the system to adapt to different qubit states, enhancing the versatility and applicability of the technology.

Benefits of this technology:

• Improved quantum computing performance: Accurate measurement and control of qubit states can enhance the performance and computational power of quantum computers.
• Enhanced reliability and security: The precise determination of qubit states improves the reliability and security of quantum communication systems, protecting sensitive information.
• Advanced sensing capabilities: Quantum sensors utilizing this technology can achieve higher sensitivity and accuracy, enabling breakthroughs in various scientific and technological fields.

Original Abstract Submitted

one or more systems, devices, computer program products and/or computer-implemented methods of use provided herein relate to a process to dynamically determine a threshold for determining a state of a qubit and apply the threshold for operating a pulse to de-excite the qubit. a system can comprise a memory that stores computer executable components, and a processor that executes the computer executable components stored in the memory, wherein the computer executable components can comprise a decision component that is configured to determine a threshold of a plurality of thresholds to apply to measurement of a state of a qubit based on a probability distribution of state of the qubit, wherein a measurement at one side of the threshold is representative of the qubit being in the ground state, and wherein a measurement at another side of the threshold is representative of the qubit being in an excited state.