Bioengineering Applications of 3D Scanning and Reconstruction Using a Depth Sensor

Octavian Ciobanu

doi:10.4028/www.scientific.net/AMM.809-810.920

Paper Titles

Element Free Galerkin Formulation for Problems in Composite Micromechanics
p.896

Implementing some Evolutionary Computing Methods for Determining the Optimal Parameters in the Turning Process
p.902

Artificial Immune System in Topology Optimization of Mechanical Structures
p.908

Lagrange's Equations versus Bond Graph Modeling Methodology by an Example of a Mechanical System
p.914

Bioengineering Applications of 3D Scanning and Reconstruction Using a Depth Sensor
p.920

Redesign of a 500 kN Maximum Hook Load Workover Rig Mast for Operating Conditions and Wind Velocity of 70 km/h
p.926

Optimization Design of a 500 kN Workover Rig Mast after Computer Simulated Overload Test
p.932

Impact Properties of Parts Manufactured from Fiberglass and Kevlar Composite Panels
p.938

Examination of a Cargo Space of a Freight Wagon Modified with Composite Panels
p.944

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 809-810Bioengineering Applications of 3D Scanning and...

Bioengineering Applications of 3D Scanning and Reconstruction Using a Depth Sensor

Abstract:

Paper approaches some characteristics and bioengineering applications of a handheld depth sensor for low-cost 3D scanning and reconstruction. The Kinect depth sensor used in this work was launched on June 2009 and was based around a gaming webcam peripheral. The Kinect sensor uses a structured light technique in order to develop real-time 3D surfaces. The 3D model of anatomic surface may have a lot of bioengineering applications. Some observations and comparisons are presented in connection with the scanning and 3D reconstruction of different anatomic surfaces.

You might also be interested in these eBooks

Innovative Manufacturing Engineering 2015

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 809-810)

Pages:

920-925

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.809-810.920

Citation:

Cite this paper

Online since:

November 2015

Authors:

Octavian Ciobanu*

Keywords:

3D Reconstruction, 3D Scanning, Bioengineering, Depth Sensor, KINECT

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] O. Ciobanu, G. Ciobanu, M. Rotariu, Photogrammetric Scanning Technique and Rapid Prototyping Used for Prostheses and Orthoses Fabrication, Applied Mechanics and Materials. 371 (2013) 230-234.

DOI: 10.4028/www.scientific.net/amm.371.230

Google Scholar

[2] D. Calva, S. Calva, A. Landa, H. Rudolph, M. Lehman, Face recognition system using fringe projection and moiré: characterization with fractal parameters, IJCSNS. 9, 7 (2009) 78 – 84.

Google Scholar

[3] E. Hierholzer, B. Drerup, High-resolution rasterstereography, in: Editors: D' M Amico, A. Merolli, G.C. Santambrogio, Three-Dimensional Analysis of Spinal Deformities, IOS Press, Amsterdam, 1995, p.435 – 439.

Google Scholar

[4] C. Lippold, G. Danesh, G. Hoppe, B. Drerup, L. Hackenberg, Trunk Inclination, Pelvic Tilt and Pelvic Rotation in Relation to the Craniofacial Morphology in Adults, Angle Orthodontist. 77, 1 (2007) 29 – 35.

DOI: 10.2319/121205-434r.1

Google Scholar

[5] B. Treleaven, J. Wells, 3D Body Scanning and Healthcare Applications, Computer. 40, 7 (2007) 28 – 34.

DOI: 10.1109/mc.2007.225

Google Scholar

[6] D. Stoyanov, A. Darzi, and G. Z. Yang, Dense 3D depth recovery for soft tissue deformation during robotically assisted laparoscopic surgery, in Medical Image Computing and Computer-Assisted Intervention, MICCAI 2004, Springer, 2004, p.41–48.

DOI: 10.1007/978-3-540-30136-3_6

Google Scholar

[7] C. Schmalz, F. Forster, A. Schick, E. Angelopoulou, An endoscopic 3d scanner based on structured light, Medical Image Analysis. 16, 5 (2012) 1063–1072.

DOI: 10.1016/j.media.2012.04.001

Google Scholar

[8] B. Shin, R. Venkatramani, P. Borker, A. Olch, J. Grimm, K. Wong, Spatial Accuracy of a Low Cost High Resolution 3D Surface Imaging Device for Medical Applications, International Journal of Medical Physics, Clinical Engineering and Radiation Oncology. 2 (2013).

DOI: 10.4236/ijmpcero.2013.22007

Google Scholar

[9] M. Camplani, and L. Salgado, Efﬁcient Spatio-Temporal Hole Filling Strategy for Kinect Depth Maps, Proc. SPIE Int. Conf. on 3D Image Processing and Applications. 8290 (2012) 1-10.

DOI: 10.1117/12.911909

Google Scholar

[10] S. Milani, G. Calvagno, Joint Denoising and Interpolation of Depth Maps for MS Kinect Sensors, in Proceedings of IEEE Conf. Acoustics, Speech and Signal Processing, 2012, 797-800.

DOI: 10.1109/icassp.2012.6288004

Google Scholar

[11] T. Dutta, Evaluation of the Kinect Sensor for 3-D Kinematic Measurement in the Workplace, Applied Ergonomics. 43 (2012) 645-649.

DOI: 10.1016/j.apergo.2011.09.011

Google Scholar

[12] D.S. Alexiadis, P. Kelly, P. Daras, N.E. O'Connor, T. Boubekeur, M.B. Moussa, Evaluating a dancer's performance using Kinect-based skeleton tracking, in Proceedings of the 19th ACM international conference on Multimedia, 2011, p.659–662.

DOI: 10.1145/2072298.2072412

Google Scholar