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<p><b>New page</b></p><div>[[File:3-proj2cam.svg|3-proj2cam|thumb]] '''Structured-light 3D scanner'''<br />
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A '''structured-light 3D scanner''' is a type of [[3D scanner]] that employs a method of [[3D scanning]] where a series of light patterns are projected onto an object. The way these patterns deform when striking the object's surface is captured by a camera and analyzed to reconstruct the 3D shape of the object. This technology is widely used in various fields such as [[industrial design]], [[reverse engineering]], [[quality control]], and [[medical imaging]].<br />
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==Principle of Operation==<br />
The structured-light 3D scanner operates by projecting a known pattern of light, often a grid or series of parallel lines, onto the surface of the object being scanned. The deformation of this pattern is then captured by one or more cameras. By analyzing the deformation, the system can calculate the depth and surface information of the object. This process is based on the principles of [[triangulation]], where the position of a point in 3D space is determined by measuring angles from known points.<br />
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==Components==<br />
A typical structured-light 3D scanner consists of the following components:<br />
* '''Projector''': Projects the structured light pattern onto the object.<br />
* '''Camera(s)''': Captures the deformed light pattern.<br />
* '''Computer''': Processes the captured images to reconstruct the 3D model.<br />
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==Applications==<br />
Structured-light 3D scanners are used in a variety of applications, including:<br />
* [[Industrial design]]: For creating accurate 3D models of prototypes and parts.<br />
* [[Reverse engineering]]: To create CAD models from existing objects.<br />
* [[Quality control]]: To inspect and measure parts for manufacturing tolerances.<br />
* [[Medical imaging]]: For creating detailed 3D models of anatomical structures.<br />
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==Advantages and Disadvantages==<br />
===Advantages===<br />
* High accuracy and resolution.<br />
* Non-contact measurement, which is ideal for delicate or sensitive objects.<br />
* Fast data acquisition.<br />
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===Disadvantages===<br />
* Sensitive to ambient light conditions.<br />
* Limited by the projector's and camera's field of view.<br />
* Can be complex and expensive.<br />
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==Related Technologies==<br />
* [[Laser scanning]]<br />
* [[Photogrammetry]]<br />
* [[Time-of-flight camera]]<br />
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==See Also==<br />
* [[3D scanning]]<br />
* [[Industrial design]]<br />
* [[Reverse engineering]]<br />
* [[Quality control]]<br />
* [[Medical imaging]]<br />
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==References==<br />
{{Reflist}}<br />
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==External Links==<br />
{{Commons category|Structured-light 3D scanners}}<br />
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[[Category:3D imaging]]<br />
[[Category:Optical devices]]<br />
[[Category:Industrial design]]<br />
[[Category:Medical imaging]]<br />
[[Category:Quality control]]<br />
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