Your search keyword '"Matheis, Carsten"' showing total 3 results

1. In-depth high-resolution SAR imaging using Omega-k applied to FMCW systems.

Author

Cristofani, Edison, Vandewal, Marijke, Matheis, Carsten, and Jonuscheit, Joachim

Abstract

Imagery applied to non-destructive testing implicitly includes the ability of imaging defects or foreign inclusions inside materials. Within a certain frequency range some nonmetal materials become highly transparent and only media interfaces or defects will scatter signals back to the sensor. Three-dimensional in-depth imaging is therefore possible and synthetic aperture processing can be applied to compensate cost-efficiently several main disadvantages present in typical high-resolution microwave imagery systems using focused beams. This work investigates under the framework of the DOTNAC Project (an FP7 project funded by the European Commission) the possibilities of applying synthetic aperture radar processing to a high-resolution frequency-modulated continuous-wave system for non-destructive testing purposes. The Omega-k range migration algorithm is used to perform efficient range migration of the raw data. This paper shows in-depth SAR images from real composite materials including ad-hoc defects. Assessment of results as well as discussion on the proposed 3-D in-depth imaging system will be presented. [ABSTRACT FROM PUBLISHER]

Published

2012

2. Nondestructive testing potential evaluation of a terahertz frequency-modulated continuous-wave imager for composite materials inspection.

Author

Cristofani, Edison, Friederich, Fabian, Wohnsiedler, Sabine, Matheis, Carsten, Jonuscheit, Joachim, Vandewal, Marijke, and Beigang, René

Subjects

COMPOSITE materials, SUBMILLIMETER waves, LENSES, MATERIALS, ELECTROMAGNETIC waves

Abstract

The sub-terahertz (THz) frequency band has proved to be a noteworthy option for nondestructive testing (NDT) of nonmetal aeronautics materials. Composite structures or laminates can be inspected for foreign objects (water or debris), delaminations, debonds, etc., using sub-THz sensors during the manufacturing process or maintenance. Given the harmless radiation to the human body of this frequency band, no special security measures are needed for operation. Moreover, the frequency-modulated continuous-wave sensor used in this study offers a very light, compact, inexpensive, and high-performing solution. An automated two-dimensional scanner carrying three sensors partially covering the 70- to 320-GHz band is operated, using two complementary measurement approaches: conventional focused imaging, where focusing lenses are used; and synthetic aperture (SA) or unfocused wide-beam imaging, for which lenses are no longer needed. Conventional focused imagery offers finer spatial resolutions but imagery is depth-limited due to the beam waist effect, whereas SA measurements allow imaging of thicker samples with depth-independent but coarser spatial resolutions. The present work is a compendium of a much larger study and describes the key technical aspects of the proposed imaging techniques and reports on results obtained from human-made samples (A-sandwich, C-sandwich, solid laminates) which include diverse defects and damages typically encountered in aeronautics multilayered structures. We conclude with a grading of the achieved results in comparison with measurements performed by other NDT techniques on the same samples. [ABSTRACT FROM AUTHOR]

Published

2014

3. Aeronautics composite material inspection with a terahertz timedomain spectroscopy system.

Author

Ospald, Frank, Zouaghi, Wissem, Beigang, René, Matheis, Carsten, Jonuscheit, Joachim, Recur, Benoit, Guillet, Jean-Paul, Mounaix, Patrick, Vleugels, Wouter, Venegas Bosom, Pablo, González Ion López, Laura Vega, Martínez Edo, Rafael, López, Ion, Sternberg, Yehuda, and Vandewal, Marijke

Subjects

TERAHERTZ spectroscopy, AERONAUTICS, TIME-domain analysis, SPECTRUM analysis, COMPOSITE materials

Abstract

The usability of pulsed broadband terahertz radiation for the inspection of composite materials from the aeronautics industry is investigated, with the goal of developing a mobile time-domain spectroscopy system that operates in reflection geometry. A wide range of samples based on glass and carbon fiber reinforced plastics with various types of defects is examined using an imaging system; the results are evaluated both in time and frequency domain. The conductivity of carbon fibers prevents penetration of the respective samples but also allows analysis of coatings from the reflected THz pulses. Glass fiber composites are, in principle, transparent for THz radiation, but commonly with significant absorption for wavelengths >1 THz. Depending on depth, matrix material, and size, defects like foreign material inserts, delaminations, or moisture contamination can be visualized. If a defect is not too deep in the sample, its location can be correctly identified from the delay between partial reflections at the surface and the defect itself [ABSTRACT FROM AUTHOR]

Published

2014