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​When working with precision optics, laser systems, and imaging devices, the demand for accurate wavefront measurement is higher than ever. Engineers, researchers, and manufacturers all require reliable solutions that balance performance with cost-efficiency. This is where the NIR Cost-effective wavefront sensor comes into play. It is designed to provide precise measurements in the near-infrared spectrum while maintaining an affordable and accessible structure for industries that demand scalability and efficiency.

​In today's fast-paced manufacturing environment, quality control is no longer a manual process. The demand for precision, efficiency, and reliability has driven the adoption of Machine Vision Inspection systems across industries. I often ask myself: how can a machine see better than the human eye? The answer lies in advanced sensors, high-resolution cameras, and intelligent algorithms. At Bojiong (Shanghai) Precision Machinery Technology Co., Ltd., we have developed cutting-edge solutions that integrate seamlessly into production lines, ensuring every product meets the highest standards.

​In the world of modern optics and advanced manufacturing, the demand for accurate and reliable measurement technologies has never been higher. One of the most advanced tools that meets this need is the Wavefront Interferometer Sensor. This technology has become a cornerstone for industries that rely on ultra-precise measurement, from semiconductor production to aerospace engineering. Over the years, I have often asked myself whether such sensors truly make a difference in real applications.

​In modern industries, the demand for ultra-precise measurement tools has never been greater. Whether it's in aerospace engineering, semiconductor manufacturing, medical device production, or advanced research laboratories, accuracy defines performance and innovation. One such cutting-edge technology is the Four-wave Interferometric Sensor, a device that pushes the limits of traditional interferometry and provides engineers and scientists with previously unattainable measurement precision.

​In today's biomedical and life sciences field, technological advancements are rapidly reshaping how researchers observe and analyze cellular activity. Among these innovations, the 3D Living Cell Microscope has emerged as a powerful tool that allows real-time, three-dimensional observation of living cells without damaging them. Unlike traditional microscopes that provide only two-dimensional views, this instrument enables a deeper understanding of cell morphology, interaction, and development, which is essential for research in cancer studies, drug discovery, immunology, and regenerative medicine.

3D cell microscopes have revolutionized biological and medical research by providing unprecedented insights into cellular structures and processes. These advanced imaging systems allow scientists to observe cells in their native, three-dimensional state, leading to more accurate and meaningful data.