Marius Vögtli scite author profile

Marius Vögtli

5Publications

12Citation Statements Received

73Citation Statements Given

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University of Zurich

Publications

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A multi-temporal hyperspectral target detection experiment: evaluation of military setups

Gross

Queck

Vögtli

et al. 2021

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This paper shows three experiments from our HyperGreding'19 campaign that combine multitemporal hyperspectral data to address several essential questions in target detection. The experiments were conducted over Greding, Germany, using a Headwall VNIR/SWIR co-aligned sensor mounted on a drone with a flight altitude of 80 m. Additionally, high-resolution aerial RGB data, GPS measurements, and reference data from a field spectrometer were recorded to support the hyperspectral data pre-processing and the evaluation process for the individual experiments. The focus of the experiments is the detectability of camouflage materials and camouflaged objects. When the goal is to transfer hyperspectral analysis to a practical setting, the analysis must be robust regarding realistic and changing conditions. The first experiment investigates the SAM and the SAMZID approaches for change detection to demonstrate their usefulness for target detection of moving objects within the recorded scene. The goal is to eliminate unwanted changes like shadow areas. The second experiment evaluates the detection of different camouflage net types over two days. This includes camouflage nets in shadows during one flight and brightly illuminated in another due to varying solar elevation angles during the day. We demonstrate the performance of typical hyperspectral target detection and classification approaches for robust detection under these conditions. Finally, the third experiment aims to detect objects and materials behind the cover of camouflage nets by using a camouflage garage. We show that some materials can be detected using an unmixing approach.

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A Multi-Scale and Multi-Temporal Hyperspectral Target Detection Experiment - From Design to First Results

Vögtli

Schreiner

Böhler

et al. 2020

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Hyperspectral target detection experiments under nonideal conditions are scarce. An extensive multi-scale and multi-temporal field experiment was designed towards the goal of knowledge expansion under such circumstances. A range of camouflage materials and specific targets of interest were placed in a realistic natural environment with vegetation cover and varying illumination. In several experiments, aspects like changes in the sun position, variable moisture, and relocations of targets were analysed. Using an aircraft-based and a drone-based imaging spectrometer, the target scenarios were mapped at different daytimes. The data were radiometrically, atmospherically and geometrically processed to allow subsequent data analysis. First insights deliver promising results.

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About the Transferability of Topographic Correction Methods From Spaceborne to Airborne Optical Data

Vögtli

Schläpfer²,

Richter

et al. 2021

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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In rugged terrain, topography substantially influences the illumination and observation geometry and thus the bidirectional reflectance distribution function (BRDF) of a surface. While this problem has been known and investigated for spaceborne optical data since the 1980s, it has led to several well-known topographic correction methods. To date, the methods developed for spaceborne data were equivalently applied to airborne data with distinctly higher spatial resolution, illumination/observation angle configurations and finally (instantaneous) field of view ((i)FOV). On the one hand, this paper evaluates, whether such a transfer of methods from spaceborne to airborne acquisitions is reasonable. On the other hand, a new Lambertian/statistical-empirical (LA+SE) correction method is introduced. While in the spaceborne case the modified Minnaert (MM) and the statistical-empirical (SE) methods performed best, MM led to the statistically and visually best compromise for the airborne data. Our results suggest further, that with a higher spatial resolution various effects come into play (FOV widening; changing the fraction of geometric, volumetric and isotropic scattering, etc.), compromising previously successful methods, such as the statistical-empirical (SE) method.

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A multi-temporal hyperspectral camouflage detection and transparency experiment

Gross

Queck²,

Schreiner³

et al. 2022

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Hyperspectral sensors are used to measure the electromagnetic spectrum in hundreds of narrow and contiguous spectral bands. The recorded data exhibits characteristic features of materials and objects. For tasks within the security and defense domain, this valuable information can be gathered remotely using drones, airplanes or satellites. In 2021, we conducted an experiment in Ettlingen, Germany, using a drone-borne hyperspectral sensor to record data of various camouflage setups. The goal was the inference of camouflage detection limits from typical hyperspectral data evaluation approaches for different scenarios. The experimental site is a natural strip of vegetation between two corn fields. Our main experiment was a camouflage garage that covered different target materials and objects. The distance between the targets and the roof of the camouflage garage was modified during the experiment. Together with the target variations, this was done to determine the material dependent detection limits and the transparency of the camouflage garage. Another experiment was carried out using two different types of camouflage nets in various states of occlusion by freshly cut vegetation. This manuscript contains a detailed experiment description, as well as, the first results of the camouflage transparency and occlusion experiment. We show that it is possible to determine the target inside the camouflage garage and that vegetation cover is not suitable additional camouflage for hyperspectral sensors.

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Level 3 wide-area backscatter time-series for wet-snow mapping and forest classification

Small¹,

Rohner²,

Miranda³

et al. 2018

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Marius Vögtli

A multi-temporal hyperspectral target detection experiment: evaluation of military setups

A Multi-Scale and Multi-Temporal Hyperspectral Target Detection Experiment - From Design to First Results

About the Transferability of Topographic Correction Methods From Spaceborne to Airborne Optical Data

A multi-temporal hyperspectral camouflage detection and transparency experiment

Level 3 wide-area backscatter time-series for wet-snow mapping and forest classification

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