3D1.6UM

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3D1.6UM improves upon traditional technologies by providing the general public with much more precise measurement and analysis capabilities.

3D 1.6UM (ultra-precision 3D imaging system) is a powerful 3D imaging technology developed by Ohio State University using laser beam scanning. This technology is widely used in medical science, automotive, aeronautical engineering, digital factories, computer aided design systems, and other fields.

3D1.6UM relies on the phenomenon of laser deflection to capture and digitize three-dimensional shapes. Through the adjustment of the components of the 3D1.6UM system, such as laser wavelength, sampling frequency, and other parameters, 3D1.6UM can accurately measure the geometry, surface roughness, color, texture, and even the structure of the object.

3D1.6UM mainly uses a self-adjusting two-dimensional scanner system to scan in three cycles, combined with a sophisticated optical imaging system, to accurately capture 3D scanning images. First, the laser light emitted from an emitting device first passes through a 3D scanner multi-axis lens, and then the reflected light pass through a 3D scanner system. Through the analysis of the data collected, 3D 1.6UM has the ability to accurately calculate the three-dimensional characteristics of the surface of the object.

Since the flexibility of 3D1.6UM relies on the number of polarization angles, illumination angles, the number of scan strips, the scanning power, and the accuracy of the imaging system, the system can be optimized to achieve different application possibilities. For example, it can be optimized for a variety of materials with fast scanning, high resolution, and high precision. In the medical field, 3D 1.6UM can be used to identify and measure tissue, cellular structure, and pathology during surgical or autopsy.

3D 1.6UM is also able to detect the defects of a surface, accurately measure the size of objects, and measure the position of objects accurately. Similarly, it can be applied to the area of military intelligence, manufacturing, automotive, and engineering as well. In these areas, 3D1.6UM can be used to measure accurate dimensions of objects, detect cracks or defects, identify flaws in metallic surfaces or in design components that require precision.

For automotive, aeronautical, and engineering, this technology can be used to create 3D maps which allow engineers to design intricate parts, tailor a design to fit a specific environment or customer’s requirements, or measure the airflow of a turbine engine. It can also be used to measure the size of an object that would otherwise be too difficult or impossible to measure with traditional methods.

In short, with the development of 3D1.6UM technology , 3D scanning has become an invaluable tool in many fields, ranging from medical to military and engineering. Its ability to provide high precision measurements of a variety of objects solves many problems that could not be solved easily with traditional methods. 3D1.6UM is not only fast, accurate, and efficient, but also unleashes a new wave of possibilities, in the research and development space.

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