Martin Metzner’s research while affiliated with University of Stuttgart and other places

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Publications (5)


The location of the City of Constance.
Flow chart of the methods applied to this study, outlining the steps taken to model, data processing, and the various analyses conducted.
The comparison of LAI/FAPAR: (a) original downloaded LAI from CDS; (b) linear model LAI; (c) original downloaded FAPAR from CDS; (d) linear model FAPAR.
The map of vegetation health status.
The probability of location for vegetation generated from random forest regression and classification: (a) vegetation can grow both healthy and stressed; (b) vegetation can grow healthy and stressed.

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Modelling Vegetation Health and Its Relation to Climate Conditions Using Copernicus Data in the City of Constance
  • Article
  • Full-text available

February 2024

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109 Reads

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1 Citation

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Martin Metzner

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Monitoring vegetation health and its response to climate conditions is critical for assessing the impact of climate change on urban environments. While many studies simulate and map the health of vegetation, there seems to be a lack of high-resolution, low-scale data and easy-to-use tools for managers in the municipal administration that they can make use of for decision-making. Data related to climate and vegetation indicators, such as those provided by the C3S Copernicus Data Store (CDS), are mostly available with a coarse resolution but readily available as freely available and open data. This study aims to develop a systematic approach and workflow to provide a simple tool for monitoring vegetation changes and health. We built a toolbox to streamline the geoprocessing workflow. The data derived from CDS included bioclimate indicators such as the annual moisture index and the minimum temperature of the coldest month (BIO06). The biophysical parameters used are leaf area index (LAI) and fraction of absorbed photosynthetically active radiation (FAPAR). We used a linear regression model to derive equations for downscaled biophysical parameters, applying vegetation indices derived from Sentinel-2, to identify the vegetation health status. We also downscaled the bioclimatic indicators using the digital elevation model (DEM) and Landsat surface temperature derived from Landsat 8 through Bayesian kriging regression. The downscaled indicators serve as a critical input for forest-based classification regression to model climate envelopes to address suitable climate conditions for vegetation growth. The results derived contribute to the overall development of a workflow and tool for and within the CoKLIMAx project to gain and deliver new insights that capture vegetation health by explicitly using data from the CDS with a focus on the City of Constance at Lake Constance in southern Germany. The results shall help gain new insights and improve urban resilient, climate-adaptive planning by providing an intuitive tool for monitoring vegetation health and its response to climate conditions.

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Driving Environment Inference from POI of Navigation Map: Fuzzy Logic and Machine Learning Approaches

November 2023

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37 Reads

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2 Citations

Sensors

To adapt vehicle control and plan strategies in a predictive manner, it is usually desired to know the context of a driving environment. This paper aims at efficiently inferring the following five driving environments around vehicle’s vicinity: shopping zone, tourist zone, public station, motor service area, and security zone, whose existences are not necessarily mutually exclusive. To achieve that, we utilize the Point of Interest (POI) data from a navigation map as the semantic clue, and solve the inference task as a multilabel classification problem. Specifically, we first extract all relevant POI objects from a map, then transform these discrete POI objects into numerical POI features. Based on these POI features, we finally predict the occurrence of each driving environment via an inference engine. To calculate representative POI features, a statistical approach is introduced. To composite an inference engine, three inference systems are investigated: fuzzy inference system (FIS), support vector machine (SVM), and multilayer perceptron (MLP). In total, we implement 11 variants of inference engine following two inference strategies: independent and unified inference strategies, and conduct comprehensive evaluation on a manually collected dataset. The result shows that the proposed inference framework generalizes well on different inference systems, where the best overall F1 score 0.8699 is achieved by the MLP-based inference engine following the unified inference strategy, along with the fastest inference time of 0.0002 millisecond per sample. Hence, the generalization ability and efficiency of the proposed inference framework are proved.


Figure 1. Data sources, data streams, and data processing functionalities in the present application context, including the AMCDS toolbox (highlighted in blue). Please note that the figure depicts exemplary commercial software applications (*), however, CoKLIMAx will also utilize and apply open-source software to complement the described components.
Application of Copernicus Data for Climate-Relevant Urban Planning Using the Example of Water, Heat, and Vegetation

September 2021

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316 Reads

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16 Citations

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Diana Rechid

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Specific climate adaptation and resilience measures can be efficiently designed and implemented at regional and local levels. Climate and environmental databases are critical for achieving the sustainable development goals (SDGs) and for efficiently planning and implementing appropriate adaptation measures. Available federated and distributed databases can serve as necessary starting points for municipalities to identify needs, prioritize resources, and allocate investments, taking into account often tight budget constraints. High-quality geospatial, climate, and environmental data are now broadly available and remote sensing data, e.g., Copernicus services, will be critical. There are forward-looking approaches to use these datasets to derive forecasts for optimizing urban planning processes for local governments. On the municipal level, however, the existing data have only been used to a limited extent. There are no adequate tools for urban planning with which remote sensing data can be merged and meaningfully combined with local data and further processed and applied in municipal planning and decision-making. Therefore, our project CoKLIMAx aims at the development of new digital products, advanced urban services, and procedures, such as the development of practical technical tools that capture different remote sensing and in-situ data sets for validation and further processing. CoKLIMAx will be used to develop a scalable toolbox for urban planning to increase climate resilience. Focus areas of the project will be water (e.g., soil sealing, stormwater drainage, retention, and flood protection), urban (micro)climate (e.g., heat islands and air flows), and vegetation (e.g., greening strategy, vegetation monitoring/vitality). To this end, new digital process structures will be embedded in local government to enable better policy decisions for the future.


Figure 1. Data sources, data streams, and data processing functionalities in the present application context, including the AMCDS toolbox (highlighted in blue).
Figure 2. Data sources, data streams, and data processing functionalities in the present application context, including the AMCDS toolbox (highlighted in blue).
Application of COPERNICUS Data for Climate-Relevant Urban Planning Using the Example of Water, Heat, and Vegetation

July 2021

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117 Reads

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6 Citations

Specific climate adaptation and resilience measures can be efficiently designed and implemented at the regional and local level. Climate and environmental databases are of critical importance to achieving sustainability goals (SDGs) and for the efficient planning and implementation of suitable mitigation measures: Available databases can serve municipalities as a vital starting points to determine requirements, prioritize resources and allocate investments under consideration of commonly tight budget restrictions. High-quality geo, climate and environmental data are now available – data from remote sensing, i.e. Copernicus services will be of crucial importance. Forward-looking approaches exist to using such data to derive forecasts for urban planning process optimization for municipal administrations. On municipal level, however, the existing data have so far only been used to a limited extent, since there are no practical tools for urban planning that can be used to merge and meaningfully combine remote sensing data with local data and to further process and apply in municipal planning processes. Therefore, our project CoKLIMAx aims at the development of new digital products, advanced urban services and procedures, such as the development of practice-oriented technical tools that acquire various remote sensing and in-situ data sets for validation and further processing.


Figure 1. Data sources, data streams, and data processing functionalities in the present application context, including the AMCDS toolbox (highlighted in blue).
Figure 2. Data sources, data streams, and data processing functionalities in the present application context, including the AMCDS toolbox (highlighted in blue).
Development of Low-Threshold Tools and Efficient Work Processes for Data Acquisition, Processing, Evaluation, and Application by Municipalities

July 2021

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77 Reads

Specific climate adaptation and resilience measures can be efficiently designed and implemented at the regional and local level. Climate and environmental databases are of critical importance to achieving sustainability goals (SDGs) and for the efficient planning and implementation of suitable mitigation measures: Available databases can serve municipalities as a vital starting points to determine requirements, prioritize resources and allocate investments under consideration of commonly tight budget restrictions. High-quality geo, climate and environmental data are now available – data from remote sensing, i.e. Copernicus services will be of crucial importance. Forward-looking approaches exist to using such data to derive forecasts for urban planning process optimization for municipal administrations. On municipal level, however, the existing data have so far only been used to a limited extent, since there are no practical tools for urban planning that can be used to merge and meaningfully combine remote sensing data with local data and to further process and apply in municipal planning processes. Therefore, our project CoKLIMAx aims at the development of new digital products, advanced urban services and procedures, such as the development of practice-oriented technical tools that acquire various remote sensing and in-situ data sets for validation and further processing.

Citations (3)


... In addition, an efficient fertilizer use can reduce nitrous oxide (N2O) concentrations in the atmosphere, promoting the uptake of key crop nutrients through rational use of available water resources (Iizumi et al., 2018). In recent years, numerous studies have been conducted to highlight the intrinsic relationship between vegetation and bioclimatic variables (Buehler et al., 2021;Chen et al., 2021;Khikmah et al., 2024), with particular attention to the role of new technologies in making the primary sector more productive and sustainable through a rational and targeted management of production factors to the benefit of farmers' income and the environment (Deng et al., 2022). In this regard, to achieve this goal, a fundamental contribution could come from the largescale application of the Precision Farming (PF), developed in the 1970s in the USA with technologies derived from control centres, and later implemented with the introduction of microprocessors and GPS in the 1990s (Zhang et al., 2023;Pierpaolia et al., 2013). ...

Reference:

Impact of climate change on vegetation growth trends in a citrus farmland in the south-eastern Sicily
Modelling Vegetation Health and Its Relation to Climate Conditions Using Copernicus Data in the City of Constance

... Ferenc et al. [28] explored the effectiveness of fuzzy logic in context awareness prediction, using a set of 14 key prediction factors, including decision time, significance, eye-related indicators, and driver experience, to achieve accurate context awareness assessment. Li et al. [29] constructed a fuzzy inference system (FIS), using point-of-interest (POI) data from navigation maps as semantic cues to effectively infer various driving environments around the vehicle, such as shopping areas, tourist spots, public stations, service areas, and safety zones. Ye et al. [30] used power-law distribution (PD) to model user check-in behavior and proposed a collaborative point of interest (POI) algorithm based on geographical influence for prediction and recommendation using naive Bayes (NB). ...

Driving Environment Inference from POI of Navigation Map: Fuzzy Logic and Machine Learning Approaches

Sensors

... Buontempo et al. (2020) presented Climate Change Service (C3S) which has been designed of quality-controlled climate data for agriculture applications. Bühler et al. (2021) applied Copernicus services, to derive forecasts for storm water drainage, retention, flood protection, and vegetation for optimizing urban planning processes for local governments. ...

Application of Copernicus Data for Climate-Relevant Urban Planning Using the Example of Water, Heat, and Vegetation