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Partial alignment for 3 D point sets is a challenging problem for laser calibration and robot calibration due to the unbalance of data sets, especially when the overlap of data sets is low. Geometric features can promote the accuracy of alignment. However, the corresponding feature extraction methods are time consuming. The purpose of this paper is to find a framework for partial alignment by an adaptive trimmed strategy.

First, the authors propose an adaptive trimmed strategy based on point feature histograms (PFH) coding. Second, they obtain an initial transformation based on this partition, which improves the accuracy of the normal direction weighted trimmed iterative closest point (ICP) method. Third, they conduct a series of GPU parallel implementations for time efficiency.

The initial partition based on PFH feature improves the accuracy of the partial registration significantly. Moreover, the parallel GPU algorithms accelerate the alignment process.

This study is applicable to rigid transformation so far. It could be extended to non-rigid transformation.

In practice, point set alignment for calibration is a technique widely used in the fields of aircraft assembly, industry examination, simultaneous localization and mapping and surgery navigation.

Point set calibration is a building block in the field of intelligent manufacturing.

The contributions are as follows: first, the authors introduce a novel coarse alignment as an initial calibration by PFH descriptor similarity, which can be viewed as a coarse trimmed process by partitioning the data to the almost overlap part and the rest part; second, they reduce the computation time by GPU parallel coding during the acquisition of feature descriptor; finally, they use the weighted trimmed ICP method to refine the transformation.

The purpose of this study is to develop an easy-to-use CAD software for fashion flat sketch that can create new sketches by combining the flat sketch modules.

A sample fashion flat module database was constructed by performing a sketch modularization process as well as a morphological analysis. In addition, an automatic module assembling algorithm was developed to create new sketches using the database.

The module assembling algorithm enabled the users to make new fashion flat sketches by the combination of design modules in the database. The example database constructed in this study was composed of bodice, sleeve, collar, cuffs and pocket modules chosen based on the results of a morphological analysis.

A CAD program has been developed that might improve the efficiency of design work by helping the users to make fashion flat sketches more easily.

The automatic module assembling algorithm developed in this study has not been implemented in any existing commercial systems. It is expected that users who do not have expertise in fashion design could be able to participate from the clothing design stage as a mass customization prosumer by using the software.