SHENZHEN, May 27, 2025 — MicroAlgo Inc. Explores Optimization of Quantum Error Correction Algorithms to Enhance Quantum Algorithm Accuracy
Shenzhen, May 27, 2025 –– MicroAlgo Inc. (the “Company” or “MicroAlgo”) (NASDAQ: MLGO) announced today that it is working on improving the precision and dependability of quantum algorithms by investigating and refining quantum error correction algorithms. These algorithms are designed to find and fix errors in qubits, which are easily disturbed by noise and interference during quantum computation due to their delicate nature. Challenges arise from ensuring efficient error correction in large qubit systems and adapting to constantly changing error patterns in complex settings, leading to errors in qubits.
MicroAlgo is optimizing quantum error correction algorithms by using extra qubits (auxiliary qubits) and specific measurement techniques to spot errors in qubits. It then uses a series of complex operations to fix these errors and restore the correct quantum state. The key to quantum error correction algorithms is creating stable quantum information encoding and effective mechanisms for detecting and correcting errors, which guarantees the accuracy and reliability of quantum computation.
Quantum Information Encoding: The first step in a quantum error correction algorithm is encoding quantum information. This is usually done by adding extra qubits, which distribute the original quantum information across multiple qubits to create a quantum codeword. This encoding method ensures that quantum information retains enough data to detect and correct errors, even when there is noise and interference. An effective quantum encoding scheme can make quantum information more resistant to disturbances while maintaining high encoding efficiency.
Error Detection: Once the quantum information is encoded, the next step is error detection. This is achieved through specific measurement operations, typically by measuring auxiliary qubits to see if there are errors in the quantum codeword. A well-designed, highly sensitive measurement scheme can accurately detect even small errors in qubits. The scheme should also be robust, capable of withstanding various types of noise and interference, ensuring accurate error detection.
Error Correction: Once an error is found in a quantum codeword, it must be corrected. This usually involves a series of complex quantum operations to return the faulty qubits to their correct states. An efficient error correction algorithm allows for quick and accurate localization and correction of faulty qubits based on the error information detected. The algorithm should also be scalable, allowing it to be used in quantum computing systems of different sizes.
Iterative Optimization: After each round of error detection and correction, the quantum error correction algorithm undergoes iterative optimization. This involves continuously repeating the encoding, detection, and correction processes to gradually reduce the error rate in qubits and improve the accuracy of quantum algorithms. The algorithm can also dynamically adjust the encoding scheme, measurement protocol, and correction algorithm based on feedback from the iterations, further improving the performance of quantum error correction.
MicroAlgo’s quantum error correction algorithm uses an efficient quantum encoding scheme that enhances the resistance of quantum information to interference while maintaining high encoding efficiency. This algorithm is highly sensitive, capable of accurately detecting even minor errors in qubits. It is also robust, enabling it to quickly and precisely locate and correct faulty qubits, and it offers excellent scalability.
MicroAlgo’s quantum error correction algorithm has broad application possibilities in multiple fields. In quantum communication, it enhances the anti-interference capability and security of quantum communications, providing strong support for quantum key distribution and quantum-secure communication. In quantum computing, it reduces error rates in qubits, improving the accuracy and reliability of quantum algorithms, which strongly supports the promotion and adoption of quantum computing in practical applications. The algorithm can also be used in areas like quantum simulation and quantum optimization, offering new technological tools and solutions for research and development in these areas.
About MicroAlgo Inc.
MicroAlgo Inc. (the “MicroAlgo”), a Cayman Islands exempted company, focuses on developing and applying customized central processing algorithms. MicroAlgo offers comprehensive solutions to clients by integrating these algorithms with software, hardware, or both. This helps them increase customer numbers, improve end-user satisfaction, achieve direct cost savings, reduce power consumption, and meet technical goals. MicroAlgo’s services include algorithm optimization, accelerating computing power without hardware upgrades, lightweight data processing, and data intelligence. MicroAlgo’s ability to efficiently deliver software and hardware optimization through bespoke central processing algorithms drives its long-term development.
Forward-Looking Statements
This press release includes statements that may be considered “forward-looking statements.” These statements are subject to numerous conditions, many beyond MicroAlgo’s control, including those in the Risk Factors section of MicroAlgo’s reports on Forms 10-K and 8-K filed with the SEC. Copies are available on the SEC’s website. Terms like “expect,” “estimate,” “project,” “budget,” “forecast,” “anticipate,” “intend,” “plan,” “may,” “will,” “could,” “should,” “believes,” “predicts,” “potential,” “continue,” and similar expressions are used to identify such statements. These forward-looking statements include, without limitation, MicroAlgo’s expectations regarding future performance and anticipated financial impacts of the business transaction.
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