Evaluation of the impact of faulty scanning trajectories in robot-based x-ray computed tomography

Hiller, Jochen; Landstorfer, Peter; Marx, Philipp; Herbst, Matthias

doi:10.1088/1361-6501/abaf2a

Cited by 8 publications

(5 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The achievable accuracy for robot based setups however again depends on the positioning accuracy of the manipulator devices. While the pose repeatability of robot arms might be sufficient [2], comparatively high systematic deviations might make it more feasible to use calibration methods such as the multi-sphere based procedure in [8] that compensate for systematic errors.…”

Section: Discussionmentioning

confidence: 99%

“…In recent years, there is a trend towards extending scan trajectories to task-specific, non-planar shapes, especially for large measurement objects that are scanned with the help of robot arms as manipulator systems for the x-ray tube and detector [1][2][3][4]. Particularly with focus on such setups, there are several publications dealing with different methods to optimize 3D scan trajectories for industrial CT with regard to imaging quality and measurement time [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Calibration of 3D scan trajectories for an industrial computed tomography setup with 6-DOF object manipulator system using a single sphere

Butzhammer

Müller²,

Hausotte³

2022

Meas. Sci. Technol.

View full text Add to dashboard Cite

In industrial X-ray computed tomography (CT), the application of more complex scan paths in comparison to the typical circular trajectory (360° rotation of the measurement object) can extend the potential of CT. One way to enable such 3D scan trajectories is to use a 6-degrees-of-freedom object manipulator system. In our case, a hexapod is mounted on top of the rotary table of a commercial CT scanner. This allows for adaptive tilting of the measurement object during the scan. For high accuracy, the geometry calibration of such setups is typically done using the X-ray projections of a calibrated multi-sphere object. Contrary to this, here, we demonstrate a procedure that is based on only a single sphere and can therefore experimentally be implemented with low effort. Using the intrinsic geometry parameters of the CT device as prior information, the hexapod coordinate system with respect to the CT machine coordinate system is determined by means of a one-step optimization approach. The resulting parameters are used to calculate projection matrices that enable the volume reconstruction for 3D scan trajectories. The method is validated using simulated X-ray images and experimental investigations including dimensional measurements. For the used setup, geometric measurement results for 3D scan trajectories that are calibrated with the presented method show in sum increased errors compared to the circular scans. A limited pose accuracy of the manipulator system is discussed as a potential cause. The results nevertheless indicate that the presented method is generally feasible for dimensional CT measurements provided that the pose accuracy is sufficient. The calibration procedure can therefore be a low-cost and easier to implement alternative compared to trajectory calibration methods based on multi-sphere objects, but with a tendency towards lower measurement accuracy. The methodology can in principle be transferred to different setups with 6-DOF manipulator systems, e.g. C-arm CT devices with a robot arm.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Calibration of 3D scan trajectories for an industrial computed tomography setup with 6-DOF object manipulator system using a single sphere

Butzhammer

Müller²,

Hausotte³

2022

Meas. Sci. Technol.

View full text Add to dashboard Cite

show abstract

“…We think that it is worth to investigate also the usage of 2D projection images (without 3D reconstruction) to obtain information on the inner shoe volume in order to reduce scanning time. Subsequently, a high-speed x-ray system integrated in the goods conveyor, as shown in figure 20, could be developed and realised for the field using, for instance, a multi-source (see [17,18]) or a robot-based system (see [19]) as soon the questions above are answered satisfactorily.…”

Section: Discussionmentioning

confidence: 99%

Generation of a 3D model of the inside volume of shoes for e-commerce applications using industrial x-ray computed tomography

2021

Self Cite

View full text Add to dashboard Cite

In 2018, 47 % of global internet users had purchased footwear products through the internet, making it the second most popular online shopping category worldwide right after clothing with 57 %. In the same year, on average, about every sixth parcel delivered in Germany (16.3 %) was returned. With the effort and costs that are associated with the return of shoes, the objective of reducing the number of returns for shoes promises an enormous economic potential and helps to reduce the CO2 emissions due to a lower trafic volume. This paper presents a workflow for determining the inside volume surface of shoes using industrial X-ray computed tomography (CT). The fundamental idea is based on the Region Growing (RG) method for the segmentation of the shoe's inner volume. Experiments are performed to illustrate the correlation of image quality and segmentation result. After obtaining the 3D surface model of an individual foot, the inner volume surface data of a scanned shoe can then be registered and evaluated in order to provide a reliable feedback for the customer regarding the accuracy of fit of a shoe and the individual foot on the basis of an overall "metric of comfort" before buying online. This step is not part of the work at hand. Conclusions are drawn and suggestions for improving the robustness and the exibility of the workflow are given, so it can be adapted to various shoe types and implemented in a fully automated measurement process in the future.

show abstract

“…Custom-built or prototype devices all use robot arms to either position the source and the detector or the part. In [8], an overview of possible arrangements is given.…”

Section: Introductionmentioning

confidence: 99%

“…The possibility to scan components of large scale assemblies such as entire cars is the main benefit of using robot arms. Current research on robot arm CT systems addresses the characterization and improvement of the positioning accuracy [8,14]. As a precise knowledge of the geometry description for each single x-ray projection is necessary for a high quality volume reconstruction with good structural resolution (according to guideline VDI/VDE 2630 part 1.3 defined as the smallest structure that can still be measured dimensionally [15]), the positioning accuracy of the robot arms can be seen as a major challenge.…”

Section: Introductionmentioning

confidence: 99%

Complex 3D scan trajectories for industrial cone-beam computed tomography using a hexapod

Butzhammer

Hausotte

2021

Meas. Sci. Technol.

View full text Add to dashboard Cite

Industrial x-ray computed tomography (CT) represents an established measurement technique in the field of nondestructive testing and dimensional metrology. However, the measurement accuracy is sometimes limited by measurement artifacts that cannot be avoided using a standard circular scan trajectory. This problem can be addressed with the aid of flexible 3D trajectories, but up to date, the application of these is mainly restricted to special CT devices using robot arms. In this paper, we present results using a hexapod as an additional positioning system in a commercial industrial CT scanner. In addition to the 360∘ rotation, task-specific tilting of the part during the scan is possible in this way. We used and adapted geometry calibration procedures based on a multi-sphere reference object to enable reconstruction with high accuracy. Using a demonstrator test fixture with high absorbing elements, we show that severe metal and truncation artifacts can be avoided for a region-of-interest scan. Furthermore, cone-beam artifacts, which are inherent to circular scan trajectories, can be reduced significantly. Using measurement objects that can be measured well with a circular trajectory, we found that applying a 3D trajectory leads to dimensional measurement deviations in the same range or even lower than those of a circular trajectory. This suggests that the pose repeatability of the hexapod is sufficient to perform complex scan paths without general loss of accuracy. The obtained results could be relevant for end users of conventional CT scanners, as upgrading existing devices is in principle possible. The presented investigations form the basis for the application of trajectory optimization algorithms.

show abstract

Evaluation of the impact of faulty scanning trajectories in robot-based x-ray computed tomography

Cited by 8 publications

References 33 publications

Calibration of 3D scan trajectories for an industrial computed tomography setup with 6-DOF object manipulator system using a single sphere

Calibration of 3D scan trajectories for an industrial computed tomography setup with 6-DOF object manipulator system using a single sphere

Generation of a 3D model of the inside volume of shoes for e-commerce applications using industrial x-ray computed tomography

Complex 3D scan trajectories for industrial cone-beam computed tomography using a hexapod

Contact Info

Product

Resources

About