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Pietro Craighero Laboratory of Optoelectronics, University of Brescia 2D Vision Course Telecentric Measurement System.

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Presentation on theme: "Pietro Craighero Laboratory of Optoelectronics, University of Brescia 2D Vision Course Telecentric Measurement System."— Presentation transcript:

1 Pietro Craighero Laboratory of Optoelectronics, University of Brescia 2D Vision Course Telecentric Measurement System

2 Pietro Craighero Problem definition  Measurement of the inner and outer radius Set up for inner radius Set up for outer radius

3 Pietro Craighero System Engineers vision have to face these problems: 1.Alteration of the magnification (due to object displacement) 2.Image distortion 3.Perspective errors 4.Low image resolution 5.Uncertainty of the position of the boundary (due to lighting geometry)

4 Pietro Craighero Hardware available  Telecentric technology addresses the need to have high- contrast images and almost no distortion  Telecentric lenses reduce or even cancel most of these problem, and for this reason have become a key component for any high accuracy gauging applications

5 Pietro Craighero Alteration of the magnification (telecentric lenses) dH = ds * theta = 1 * 0.0017 mm = 0,0017 mm With telecentric lenses the image size is left unchanged with object displacement, provided the object stays within a certain range often referred to as “depth of field” or “telecentric range”  In a telecentric lens the magnification change is determined by the “telecentric slope”  theta = 0,0017 rad  ds = 1 mm

6 Pietro Craighero Perspective errors  Telecentric lenses eliminate the perspective effect This effect is due to the specific path of the rays Non telecentric lens Telecentric lens

7 Pietro Craighero Good image resolution The resolution provided by telecentric lenses is compatible with very small pixel sizes and high resolution cameras thus increasing the measurement resolution. Frame rate : 11.2 fps Sensor type : CMOS Pixel size : 3.2 um Optical size : 6.554 x 4.915 mm Resolution : 2048 x 1536 Optical class : ½” Resolution class : 3.15 Mpix RSx = FOVx/(#pixel) = 46.5 mm / 2048 pixel = 0.022 mm/pixel RSy = FOVy/(#pixel) = 34.9 mm / 1536 pixel = 0.022 mm/pixel

8 Pietro Craighero Imaging system set up  Working Distance : 182,3 (+/-) 5 [mm]  Field of View (with ½” detector) : 46,5 x 34,9 [mm] WDWD 46.5 mm 34.9mm

9 Pietro Craighero Software structure  State machine  User choises Init / Idle /Calibrazione offline /Calibrazione online / Acquisizione online / Acquisizione offline / Misura Raggi Interni Misura Raggi Esterni Calibration & Acquisition

10 Pietro Craighero Inner radius  ROI selection? Default mode Manual mode ROI Cluster  Compute inner radius and display

11 Pietro Craighero Outer radius While(stop == false){.. If(new ROI drawn == false) {.. }

12 Pietro Craighero Outer radius While(stop == false){.. If(new ROI drawn == false) {.. } 30,33 mm

13 Pietro Craighero Conclusion set and choose the right hardware friendly interface design Thank you for your attention

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