Rodrigo Farnham scite author profile

Rodrigo Farnham

4Publications

32Citation Statements Received

43Citation Statements Given

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Improved accuracy and speed in scanning probe microscopy by image reconstruction from non-gridded position sensor data

Ziegler¹,

Meyer²,

Farnham³

et al. 2013

Nanotechnology

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Scanning probe microscopy (SPM) has facilitated many scientific discoveries utilizing its strengths of spatial resolution, non-destructive characterization and realistic in situ environments. However, accurate spatial data are required for quantitative applications but this is challenging for SPM especially when imaging at higher frame rates. We present a new operation mode for scanning probe microscopy that uses advanced image processing techniques to render accurate images based on position sensor data. This technique, which we call sensor inpainting, frees the scanner to no longer be at a specific location at a given time. This drastically reduces the engineering effort of position control and enables the use of scan waveforms that are better suited for the high inertia nanopositioners of SPM. While in raster scanning, typically only trace or retrace images are used for display, in Archimedean spiral scans 100% of the data can be displayed and at least a two-fold increase in temporal or spatial resolution is achieved. In the new mode, the grid size of the final generated image is an independent variable. Inpainting to a few times more pixels than the samples creates images that more accurately represent the ground truth.

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Height drift correction in non-raster atomic force microscopy

Meyer¹,

Ziegler²,

Brüne³

et al. 2014

Ultramicroscopy

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We propose a novel method to detect and correct drift in non-raster scanning probe microscopy. In conventional raster scanning drift is usually corrected by subtracting a fitted polynomial from each scan line, but sample tilt or large topographic features can result in severe artifacts. Our method uses self-intersecting scan paths to distinguish drift from topographic features. Observing the height differences when passing the same position at different times enables the reconstruction of a continuous function of drift. We show that a small number of self-intersections is adequate for automatic and reliable drift correction. Additionally, we introduce a fitness function which provides a quantitative measure of drift correctability for any arbitrary scan shape.

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Bandwidth of trees of diameter at most 4

Bilinski¹,

Choi²,

Chun³

et al. 2012

Discrete Mathematics

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Encased Cantilevers and Alternative Scan Algorithms for Ultra-Gantle High Speed Atomic Force Microscopy

Ashby

Ziegler

Frank

et al. 2012

Biophysical Journal

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Rodrigo Farnham

Improved accuracy and speed in scanning probe microscopy by image reconstruction from non-gridded position sensor data

Height drift correction in non-raster atomic force microscopy

Bandwidth of trees of diameter at most 4

Encased Cantilevers and Alternative Scan Algorithms for Ultra-Gantle High Speed Atomic Force Microscopy

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