IQM FINLAND OY (20240259002). QUBIT CLOCK SIGNAL GENERATION simplified abstract

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QUBIT CLOCK SIGNAL GENERATION

Organization Name

IQM FINLAND OY

Inventor(s)

[[:Category:Pasi L�hteenm�ki of Espoo (FI)|Pasi L�hteenm�ki of Espoo (FI)]][[Category:Pasi L�hteenm�ki of Espoo (FI)]]

QUBIT CLOCK SIGNAL GENERATION - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240259002 titled 'QUBIT CLOCK SIGNAL GENERATION

The patent application relates to the generation of qubit clock signals using superconductive technology in a cryogenic environment.

  • Superconductive phase detector receives a reference frequency signal and generates an output.
  • Superconductive oscillator produces a pulse clock signal based on the output of a low-pass filter connected to the phase detector.
  • Frequency divider divides the pulse clock signal to create a feedback signal for the phase detector.
  • Pulse generator generates a qubit drive pulse sequence based on the pulse clock signal.

Potential Applications: - Quantum computing - High-speed data processing - Advanced communication systems

Problems Solved: - Precise clock signal generation in a cryogenic environment - Efficient qubit drive pulse sequence generation

Benefits: - Enhanced performance in quantum computing applications - Improved accuracy in data processing - Increased speed in communication systems

Commercial Applications: Title: "Superconductive Qubit Clock Signal Generation for Quantum Computing" This technology can be utilized in quantum computing research labs, data centers, and telecommunications companies to enhance performance and efficiency in various applications.

Questions about Superconductive Qubit Clock Signal Generation: 1. How does the superconductive phase detector receive and process the reference frequency signal? 2. What are the advantages of using superconductive technology for qubit clock signal generation in quantum computing applications?

Frequently Updated Research: Researchers are constantly exploring new ways to improve the efficiency and accuracy of qubit clock signal generation in superconductive systems for quantum computing advancements.


Original Abstract Submitted

example embodiments relate to generation of qubit clock signals. a superconductive phase detector may receive a reference frequency signal across a boundary of a cryogenic environment. a superconductive oscillator may be configured to generate a pulse clock signal based on an output of a low-pass filter electrically coupled to the output of the superconductive phase detector. a frequency divider may divide a frequency of the pulse clock signal to generate a feedback signal for the superconductive phase detector, which may generate its output based on a comparison of a phase of the reference frequency signal and a phase of the feedback signal. a pulse generator may generate a qubit drive pulse sequence based on the pulse clock signal. apparatuses and methods are disclosed.