@article{Timmermeyer2013, Author = {A. Timmermeyer, H. Wojtczyk, W. Tenner, G. Bringout, M. Grüttner, M. Graeser, T. Sattel, A. Halkola, and T. M. Buzug}, Title = {Super-resolution approaches for resolution enhancement in magnetic particle imaging.}, Journal = {3rd International Workshop on {Magnetic Particle Imaging} ({IWMPI}), IEEE Xplore Digital Library.}, Year = {(2013).}, Note = {inproceedings}, Booktitle = {2013}, Doi = {10.1109/IWMPI.2013.6528360}, Keywords = {1D simulation, biomedical {MRI}, Image Enhancement, image resolution, Iron, low resolution images, magnetic particle imaging, magnetic particles, Magnetic Resonance Imaging, medical image processing, resolution enhancement, sampling points, Signal resolution, spatial resolution, super-resolution approach, visualization,Graeser}, Abstract = {Given a definition of spatial resolution that considers two objects as distinguished if the minimum value of the gap is less than 50\% of the value at the object position [7], both approaches achieved an improvement of the spatial resolution in the 1D simulation study as visualized in Fig. 1 and 2. If the spatial resolution is considered as the minimum width of two distinguished lines, the first approach using spatially shifted images achieved a spatial resolution of 1.7 mm and the second approach using different sampling points achieved a resolution of 2.6 mm. This is an improvement in comparison to the used low resolution images with a spatial resolution of 2 mm (first approach) and 2.9 mm (second approach).} } @COMMENT{Bibtex file generated on 2024-3-28 with typo3 si_bibtex plugin. Data from https://www.tuhh.de/ibi/people/matthias-graeser }