L. S. Chumbley,  M. Morris, R. Spotts, and C. Macziewski, "Development of a mobile tool mark characterization/comparison system," J. Forensic Sci., 62(1), 83-91 (2017), doi: 10.1111/1556-4029.13233

Since the development of the striagraph, various attempts have been made to enhance forensic investigation through the use of measuring and imaging equipment. This study describes the development of a prototype system employing an easy-to-use software interface designed to provide forensic examiners with the ability to measure topography of a toolmarked surface and then conduct various comparisons using a statistical algorithm. Acquisition of the data is carried out using a portable 3D optical profilometer, and comparison of the resulting data files is made using software named “MANTIS” (Mark and Tool Inspection Suite). The system has been tested on laboratory-produced markings that include fully striated marks (e.g., screwdriver markings), quasistriated markings produced by shear-cut pliers, impression marks left by chisels, rifling marks on bullets, and cut marks produced by knives. Using the system, an examiner has the potential to (i) visually compare two toolmarked surfaces in a manner similar to a comparison microscope and (ii) use the quantitative information embedded within the acquired data to obtain an objective statistical comparison of the data files. This study shows that, based on the results from laboratory samples, the system has great potential for aiding examiners in conducting comparisons of toolmarks.

[92] R. Chen, J. Xu, S. Zhang, H. Chen, Y. Guan, and K. Chen, "A self-recalibration method based on scale-invariaant registration for structured light measurement systems," Opt. Laser Eng., 88, 75-81 (2017); doi:10.1016/j.optlaseng.2016.07.003

Abstract

The measurement accuracy of structured light measurement depends on delicate offline calibration. However, in some practical applications, the system is supposed to be reconfigured so frequently to track the target that an online calibration is required. To this end, this paper proposes a rapid and autonomous self-recalibration method. For the proposed method, first, the rotation matrix and normalized translation vector are attained from the fundamental matrix; second, the scale factor is acquired based on scale-invariant registration such that the actual translation vector is obtained. Experiments have been conducted to verify the effectiveness of our proposed method, and the results indicate a high degree of accuracy.

[86] J. Xu, R. Chen, H. Chen, S. Zhang, and K. Chen, " Fast registration methodology for fastener assembly of large-scale structure," IEEE Trans Industrial Electronics, 64(1),  717-726 (2017); doi:10.1109/TIE.2016.2599140

Abstract

Fastener assembly is a tedious and time-consuming work because operators have to check assembly manuals and find right fastener for each hole. Hence, this article aims to develop a 3D projection system which projects assembly instruction onto the work piece surface directly to guide operators to assemble. However, in order to project the instruction accurately, the corresponding part of the CAD model of the physical scanned area needs to be attained through the rapid and accurate registration. In order to achieve this goal,firstly, a high-accuracy and rapid 3D measurement system is developed; secondly, a fast registration method based on local multi-scale geometric feature vector is proposed to accelerate the registration speed and improve the registration reliability. Experimental results demonstrate the measurement accuracy of the developed system, and verify the feasibility of the proposed registration method. Hence the proposed method can lead to improved assembly efficiency and decreased error probability, making great contributions to large-scale structure assembly.

[81] B. Chen and S. Zhang, "High quality 3D shape measurement using saturated fringe patterns,'' Opt. Laser Eng. (2016) (doi:10.1016/j.optlaseng.2016.04.012)

Abstract

This paper proposes a method to potentially conquer one of the challenges in the optical metrology community: optically measuring three-dimensional (3D) objects with high surface contrast. We discover that  for digitally equally phase-shifted fringe patterns, if the fringe period P is an even number, the N = P/2 x k, (k = 1, 2, 3, ...) step algorithm can accurately recover phase even if the fringe patterns are saturated; and if P is an odd number, N = P x k step algorithm can also accurately recover phase even if the fringe patterns are saturated.  This finding leads to a novel method to optically measure shiny surfaces, where the saturation due to surface shininess could be substantially alleviated. Both simulations and experiments successfully verified the proposed method.