Algorithms for Constructing 3-D Point Clouds Using Multiple Digital Fringe Projection Patterns

Peng, Tao; Gupta, Satyandra K.; Lau, K.

doi:10.1080/16864360.2005.10738337

Cited by 17 publications

(14 citation statements)

References 6 publications

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“…This is in contrast to systems such as Fechteler and Eisert [2008] and Peng et al [2005], where the warping of the projected pattern is used to estimate the 3D geometry of the object. The advantage 5:6 • R. Mv et al of not choosing the route of warp estimation is that the position of the pattern need not be precisely calibrated with respect to the cameras, and the pattern itself can be simple and static.…”

Section: Projector Systemmentioning

confidence: 95%

A camera flash projector-based reconstruction system for digital preservation of artifacts

Rohith

Somanath

Norris

et al. 2013

J. Comput. Cult. Herit.

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Computer vision techniques have been applied for rapid and accurate structure recovery in many fields. Most methods perform poorly in areas containing little or no texture and in the presence of repetitive patterns. We present a portable, cost-effective pattern projector system powered by the flash of a camera, to aid the reconstruction of such areas. No calibration is required between the camera-projector, projector-scene, or pattern. We demonstrate the effectiveness of our system on various representative surfaces like stone, metal, clay, porcelain, and natural fibers, with different inherent colors/textures. A pipeline is presented to automatically generate textured, true-scale metric models, that can be used for quantitative studies or visualization. The practicability of our system is explored in the specific area of digital archiving of historically significant objects. We show results from field trips to 12th century temples at Belur and Halebidu in South India and objects from the Wintherthur museum, Delaware, USA. ACM Reference Format:Mv, R., Somanath, G., Norris, D., Gutierrez, J., and Kambhamettu, C. 2013. A camera flash projector-based reconstruction system for digital preservation of artifacts. ACM J.

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Section: Projector Systemmentioning

confidence: 95%

A camera flash projector-based reconstruction system for digital preservation of artifacts

Rohith

Somanath

Norris

et al. 2013

J. Comput. Cult. Herit.

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“…Typical 3D shape measurement techniques, such as laser scanning method [1], moire method [2], interferometry method [3], photogrammetry method [4], laser tracking method [5], digital image correlation (DIC) method [6], and fringe (or structured light) projection method [7][8][9][10][11][12][13][14][15][16], generally fall into two categories. One is capable of providing accurate measurement, and the other is capable of supplying fast measurement.…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional, Real-Time, and High-Accuracy Inline Monitoring System for Roll to Roll Manufacturing

Wang

Park

2008

2008 Flexible Electronics and Displays Conference and Exhibition

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A non-contact, real-time, high-accuracy, low-cost, broad-range, and full-field 3D shape measurement technique is presented. The technique is based on a generalized fringe projection profilometry approach, and it employs random phase shifting, doublefrequency projection fringes, ultrafast direct phase unwrapping, and inverse self-calibration schemes to perform 3D shape determinations with enhanced accuracies in a real-time manner. The measurement accuracy can reach 1/10000 of the field of view or higher, and the acquisition speed is capable of achieving 5 to 30 3D views per second. Experiments have been conducted to verify the validity of the proposed technique. Due to its superior capability, the real-time, high-accuracy 3D shape measurement technique is very suitable for inline monitoring the flexible electronics products during roll to roll manufacturing, and it can also serve as an experimental tool to investigate the mechanical/thermal reliability issues involved in flexible electronics design and optimization analysis.Three-dimensional (3D) shape measurement techniques for the determination of 3D shapes of objects have emerged as important tools for product inspection and quality control applications in electronics industry. Typical 3D shape measurement techniques, such as laser scanning method [1], moire method [2], interferometry method [3], photogrammetry method [4], laser tracking method [5], digital image correlation (DIC) method [6], and fringe (or structured light) projection method [7-16],generally fall into two categories. One is capable of providing accurate measurement, and the other is capable of supplying fast measurement. The techniques in the former category such as coordinate measurement and laser-based measurement methods are capable of providing accurate 3D imaging, but the measurement speed is usually very low because these techniques measure various points on the object sequentially. On the contrary, the techniques in the fast measurement category generally yield relatively faster 3D imaging with lower accuracies.As the technologies of electronics design and manufacturing evolve, there has been a high demand for the 3D shape measurement and monitoring techniques to provide not only accurate, but also realtime measurements. For example, the manufacturing of electronic components needs an inspection process that can measure and analyze various 3D features on the components and determine whether the desired features are within the tolerance specifications or not. In this application, both high inspection speed and high accuracy are required because the inspection speed must match the manufacturing speed. Measurement errors can result in erroneous inspection that leads to an acceptable part being rejected or a defective part being accepted. At present, however, a technique capable of providing both real-time and high-accuracy 3D shape measurement and 3D imaging is lacking and is highly on demand.In this paper, a non-contact, real-time, highaccuracy, low-cost, broad-range, and full-field 3D s...

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“…Three-dimensional (3D) shape measurement or imaging technique for determining the 3D shape of objects has emerged as an important tool for many applications such as object detection, digital model generation, object replication, reverse engineering, rapid prototyping, product inspection, and quality control. Typical 3D shape measurement techniques, including the laser scanning method [1], the moiré method [2], the interferometry method [3], the photogrammetry method [4], the laser tracking method [5], the digital image correlation method [6], and the fringe (or structured light) projection method [7][8][9][10][11][12][13][14][15][16][17], mostly fall into two major categories. One category is capable of providing accurate measurements, and the other is capable of supplying fast measurements.…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional shape measurement with a fast and accurate approach

Wang

Park

et al. 2009

Appl. Opt.

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A noncontact, fast, accurate, low-cost, broad-range, full-field, easy-to-implement three-dimensional (3D) shape measurement technique is presented. The technique is based on a generalized fringe projection profilometry setup that allows each system component to be arbitrarily positioned. It employs random phase-shifting, multifrequency projection fringes, ultrafast direct phase unwrapping, and inverse self-calibration schemes to perform 3D shape determination with enhanced accuracy in a fast manner. The relative measurement accuracy can reach 1/10,000 or higher, and the acquisition speed is faster than two 3D views per second. The validity and practicability of the proposed technique have been verified by experiments. Because of its superior capability, the proposed 3D shape measurement technique is suitable for numerous applications in a variety of fields.

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Algorithms for Constructing 3-D Point Clouds Using Multiple Digital Fringe Projection Patterns

Cited by 17 publications

References 6 publications

A camera flash projector-based reconstruction system for digital preservation of artifacts

A camera flash projector-based reconstruction system for digital preservation of artifacts

Three-Dimensional, Real-Time, and High-Accuracy Inline Monitoring System for Roll to Roll Manufacturing

Three-dimensional shape measurement with a fast and accurate approach

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