Abstract
There is always a great challenge for the structured light technique that it is difficult to deal with the surface with large reflectivity variations or specular reflection. This paper proposes a flexible and adaptive digital fringe projection method based on image fusion and interpolated prediction search algorithm. The multiple mask images are fused to obtain the required saturation threshold, and the interpolated prediction search algorithm is used to calculate the optimal projection gray-level intensity. Then, the projection intensity is reduced to achieve coordinate matching in the unsaturated condition, and the adaptive digital fringes with the optimal projection intensity are subsequently projected for phase calculation by using the heterodyne multifrequency phase-shifted method. The experiments demonstrate that the proposed method is effective for measuring the high-reflective surface and unwrapping the phase in the local overexposure region completely. Compared with the traditional structured light measurement methods, our method can decrease the number of projected and captured images with higher modulation and better contrast. In addition, the measurement process only needs two prior steps and avoids hardware complexity, which is more convenient to apply to the industry.
Highlights
Structured light technique has been widely used in academic research and industrial fields because of the advantages in their full-field inspection, noncontact operation, low cost, and high precision [1, 2]
When the coded fringe images are projected to measure the surface with large reflectivity variations, the high-reflective region is too bright to result in image saturation, which will lead to large deviation in the three-dimensional (3D) measurement [3, 4]
We propose an adaptive digital fringe projection method based on image fusion and interpolated prediction search algorithm to achieve the 3D measurement of the high-reflective surface with large reflectivity variations
Summary
Structured light technique has been widely used in academic research and industrial fields because of the advantages in their full-field inspection, noncontact operation, low cost, and high precision [1, 2]. We propose an adaptive digital fringe projection method based on image fusion and interpolated prediction search algorithm to achieve the 3D measurement of the high-reflective surface with large reflectivity variations. Compared with traditional optical 3D measurement methods, our method has optimal fringe contrast, which can achieve complete reconstruction in the overexposed region and effectively solve the problem of 3D shape measurement with high-reflective surface. It will avoid additional hardware complexity and projector nonlinear gamma compensation.
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