Our products serve global research institutions and cutting-edge companies with reliable quality and exceptional performance.
We highly value the technology innovation, product quality, and customer service. We will continue the technology transformation of quantum optoelectronic to provide quantum empowerment for industry, medical care, scientific research, environment, energy and other fields, to provide customers with professional and comprehensive new optoelectronic solutions.
Advancing the accumulation and application of scientific knowledge
Contributing to environmental improvement and human health protection
Our engineering team conducts detailed consultations with customers to determine the following aspects:
Our engineering team conducts detailed consultations with customers to determine the following aspects:
Based on the customer’s requirements, we select the most suitable materials and carry out preliminary designs to ensure the product meets all technical requirements and feasibility considerations. This phase involves:
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We employ advanced manufacturing technologies and flexible production capabilities to handle all demands from small to large-scale production. This includes:
High-Precision Manufacturing: Using both automated and manual high-precision manufacturing techniques to ensure product accuracy and consistency.
Our quality management system complies with ISO9001 standards, ensuring stable quality and reliability of our products. We conduct industry-specific testing and validation, including but not limited to:
Performance Testing: Verifying that product performance parameters meet design requirements.
Single-photon detection technology is a high-sensitivity technique used to detect and count individual photons.
It is commonly applied in fields such as quantum optics, quantum information processing, quantum computing, photon counting, and photonics.
Single-photon ranging and imaging technology involves measuring distances and creating images using individual photons.
This technology is typically used in applications requiring high precision and high resolution, such as optical ranging, 3D imaging, and Lidar.
Lithium niobate crystals are used to prepare waveguides through titanium diffusion or proton exchange processes, enabling high-speed phase modulation and intensity modulation functions.
Through optical microfabrication processes, we integrate internal components within butterfly-shaped packaging tubes, advancing the application and development of high-performance, multifunctional optical devices in fields such as communication, sensing, and laser technology.
Quantum entropy source technology is constructed based on the principle of quantum uncertainty, ensuring that the high entropy performance of random numbers meets national standards (such as GM/T0005-2021 issued by the China National Cryptography Administration) and internationally recognized randomness testing requirements (such as NIST SP800-22).
