PrePEP - Conference: Precipitation Processes - Estimation and Prediction

16 Mar 2025, 09:00 → 21 Mar 2025, 16:00 Europe/Berlin

Aula (University of Bonn)

University of Bonn, main building, copyright: Volker Lannert / University of Bonn

March 16 - 21, 2025 international researchers on observations, numerical models, and hydrology will meet in Bonn, Germany, for the conference Precipitation Processes - Estimation and Prediction (PrePEP). We discuss multi-sensor, new emerging and opportunistic in-situ and remote sensing techniques, which help to better understand and monitor precipitation processes. Central topics of the PrePEP conference are methodologies for exploiting observations for retrievals, nowcasting, data assimilation and parametrization development for NWP models as well as blending and probabilistic techniques towards seamless prediction including hydrological forecasts. A better understanding, assessment and prediction of extreme precipitation events and floods are additional key elements of PrePEP.

Contact

If you have any questions please reach out to prepep2025@uni-bonn.de

Important dates

• 19 August 2024: Abstract submission and registration open
• 10 November 2024: Abstract submission deadline
• 2 December 2024: Acceptance E-mails sent out 
• 8 December 2024: Early bird registration deadline
• 16 February 2025: Registration deadline

Overview of sessions and their scope

We welcome contributions to the following five sessions, with two sub-sessions each.

Session 1: From Classical to Integrated Remote Sensing

The session invites contributions, which introduce and exploit observational networks for the description, quantification and improved process understanding of clouds and precipitation. This includes e.g. ground- and satellite-based remote sensing techniques as well as in-situ measurements, opportunistic sensors and citizen science contributions. We especially welcome multi-sensor, multi-frequency, (spectral) polarimetry and integrated approaches to improve accuracy or get deeper insights in precipitation generating processes. This session also addresses advanced retrieval and estimation techniques to improve and extend the observational data set with high-level products for further use in e.g. nowcasting and data assimilation.

• 1.A New observation strategies for clouds and precipitation (multi-frequency, spectral polarimetry, multi-sensor)
• 1.B New retrieval and estimation techniques (e.g. fusion, Bayesian)

Invited speaker:
Filippo Giannetti, University of Pisa

Session 2: Enhancing Process Understanding

A better understanding of precipitation formation processes is key to improving precipitation forecasting. This session focuses on how new observation types and novel techniques of data analysis and data integration are used to evaluate and improve models of precipitation formation. Contributions on enhancing microphysics process understanding and process modeling, model microphysics evaluations, parameterization development and model parameter estimation, either in the framework of classical NWP or modern AI methods, are welcome.

• 2.A New observations for modeling and parameterization development
• 2.B Model parameter estimation 

Invited speaker:
Linda Schlemmer, Deutscher Wetterdienst (DWD)

Session 3: Prediction Scales and Model Development

Weather extreme events are becoming more prevalent. An informed decision-making requires sophisticated numerical models which help us to better understand, simulate, and forecast the relevant atmospheric processes. The public demands in particular timely and accurate predictions and warnings of extreme precipitation and hazards such as large hail and severe wind gusts. The session invites contributions on classical or AI-based nowcasting techniques for very small scales and short lead times, integrated nowcasting based on different observation types, and NWP-informed nowcasting down to hectometer scales. Also approaches addressing longer lead times and uncertainty estimation for these techniques are welcome.

• 3.A Modeling elements in nowcasting 
• 3.B Hectometer scale modeling for precipitation

Invited speaker:
Ulrich Hamann, MeteoSwiss
Léa Berthomier, Météo-France

Session 4: Seamless Prediction 

Seamless forecasting from minutes to hours and days is of utmost importance to communicate consistent warnings to both individuals and institutions involved in managing high-impact weather related activities. In this session, we welcome contributions to the following topics: convective-scale data assimilation, ensemble generation, predictability analyses, post-processing techniques, blending approaches, and assimilation of new data sources.

• 4.A Data assimilation integrating nowcasting and new observations
• 4.B Blending and probabilistic techniques based on nowcasting and NWP ensembles

Invited speaker:
Daniele Nerini, MeteoSwiss
Katie Norman, Met Office

Session 5: Precipitation and Hydrological Models

The increasing incidents of intense precipitation and related floodings lead to significant socio-economic consequences, while the high spatial and temporal variability of precipitation hampers timely and reliable warnings and limits the accuracy of precipitation modeling and hydrological forecasting. This session invites both the scientific and operational communities to interact towards effective early warning approaches. We welcome contributions on precipitation modeling, analysis of extreme precipitation events, flood simulation and forecasting, uncertainty representation, verification, and the visualization of flood risks.

• 5.A Extreme precipitation events 
• 5.B Evaluation, verification and interfaces

Invited speaker:
Christel Prudhomme, European Centre for Medium-Range Weather Forecasts (ECMWF)
Natalie Stahl-van Rooijen, State Environmental Agency Bavaria
Erwin Zehe, Karlsruhe Institute of Technology (KIT)

The Rhine in Bonn, copyright: Volker Lannert / University of Bonn

Material PrePEP2025__Book_of_Abstracts.pdf

Sunday 16 March

09:00 → 10:30 Short Course: Microphysical Fingerprinting in Multi-Peaked Radar Doppler Spectra

Conveners: Martin Radenz (TROPOS), Teresa Vogl

09:00 → 10:30 Short Course: Open Radar – Open Source Software Tools for Radar Data Processing

Convener: Kai Mühlbauer (Institut für Geowissenschaften, Abteilung Meteorologie, Uni Bonn)

09:00 → 10:30 Short Course: Processing of Opportunistic Rainfall Sensors Data from CML, PWS and SML Networks

Conveners: Christian Chwala (KIT (IMK-IFU)), Maximilian Graf

09:00 → 10:30 Short Course: Weather radar system design including antenna front-end aspects

Convener: Stefano Turso (Fraunhofer FHR)

10:30 → 10:50 Coffee Break

10:50 → 12:30 Short Course: Microphysical Fingerprinting in Multi-Peaked Radar Doppler Spectra

Conveners: Martin Radenz (TROPOS), Teresa Vogl

10:50 → 12:30 Short Course: Open Radar – Open Source Software Tools for Radar Data Processing

Convener: Kai Mühlbauer (Institut für Geowissenschaften, Abteilung Meteorologie, Uni Bonn)

10:50 → 12:30 Short Course: Processing of Opportunistic Rainfall Sensors Data from CML, PWS and SML Networks

Conveners: Christian Chwala (KIT (IMK-IFU)), Maximilian Graf

10:50 → 12:30 Short Course: Weather radar system design including antenna front-end aspects

Convener: Stefano Turso (Fraunhofer FHR)

12:30 → 13:30 Lunch Break

13:30 → 15:15 Short Course: Microphysical Fingerprinting in Multi-Peaked Radar Doppler Spectra

Conveners: Martin Radenz (TROPOS), Teresa Vogl

13:30 → 15:15 Short Course: Open Radar – Open Source Software Tools for Radar Data Processing

Convener: Kai Mühlbauer (Institut für Geowissenschaften, Abteilung Meteorologie, Uni Bonn)

13:30 → 15:15 Short Course: Processing of Opportunistic Rainfall Sensors Data from CML, PWS and SML Networks

Conveners: Christian Chwala (KIT (IMK-IFU)), Maximilian Graf

13:30 → 15:15 Short Course: Weather radar system design including antenna front-end aspects

Convener: Stefano Turso (Fraunhofer FHR)

15:15 → 15:35 Coffee Break

15:35 → 17:00 Short Course: Microphysical Fingerprinting in Multi-Peaked Radar Doppler Spectra

Conveners: Martin Radenz (TROPOS), Teresa Vogl

15:35 → 17:00 Short Course: Open Radar – Open Source Software Tools for Radar Data Processing

Convener: Kai Mühlbauer (Institut für Geowissenschaften, Abteilung Meteorologie, Uni Bonn)

15:35 → 17:00 Short Course: Processing of Opportunistic Rainfall Sensors Data from CML, PWS and SML Networks

Conveners: Christian Chwala (KIT (IMK-IFU)), Maximilian Graf

15:35 → 17:00 Short Course: Weather radar system design including antenna front-end aspects

Convener: Stefano Turso (Fraunhofer FHR)

Monday 17 March

09:30 → 10:00 Welcome

PrePEP_2025_welcome.pptx

10:00 → 10:30 Keynote 1: The amazing journey through an opportunistic satellite sensing system: from the "bad-looking" raw data to the "handsome" precipitation estimate

Convener: Filippo Giannetti (University of Pisa)

PrePep-Bonn-2025-v08_FGiannetti.pdf

PrePep-Bonn-2025-v08_FGiannetti.pptx

10:30 → 10:45 Weather radar adjustment with pyRADMAN: Experiments with and without commercial microwave links

Data from commercial microwave links (CMLs) have proven to provide useful rainfall estimates. With their extensive numbers, potential for real-time data availability, and measurement near the ground, they offer the potential to adjust weather radar data, similar to the operational use of rain gauges by national meteorological services (NMS). Furthermore, CMLs offer a path-averaged rainfall estimate that resembles the areal measurements obtained from weather radars more closely than the point measurements from rain gauges.
However, several challenges hinder the use of CML data for radar within the operational setting of NMS. These include the (real-time) acquisition of CML data from mobile network operators, the uncertainties related to their rainfall estimation and the question how to actually merge gridded data with their path-averaged information.
In the HoWa-PRO project, we have established a CML data stream from Ericsson to the German Weather Service (DWD) and developed the Python framework pyRADMAN to merge radar, rain gauge and CML data in real-time. In this contribution, we will present pyRADMAN and its resulting rainfall products. The methodology in pyRADMAN builds on the adjustment technique from the operational software RADOLAN, using refined methods for CMLs. Additionally, we tested other adjustments like kriging with external drift and conditional merging, used classic advection correction or the deep-learning model ResRadNet to correct the radar prior to the adjustment and increased the temporal resolution of adjusted products to up to 15 minutes. pyRADMAN enables modular implementation and testing of new pre-processing and adjustment methods, supporting future collaborative efforts.

Speaker: Maximilian Graf (Deutscher Wetterdienst)

prePEP_Graf.pptx

10:45 → 11:00 Tropical rainfall nowcasting with Commercial Microwave Links: opportunities and current limitations

Accurate and timely precipitation forecasts are crucial for flood early warnings and mitigating other rainfall-induced natural hazards like landslides. For forecasts up to three hours ahead, rainfall nowcasts are increasingly being used. Generally, these nowcasts statistically extrapolate real-time remotely sensed quantitative precipitation estimates, often based on weather radars. However, the global distribution of high-resolution (gauge-adjusted, ground-based) weather radar products is heavily skewed, largely favoring Europe, Northern America, and parts of East Asia. In many low- and middle-income countries, predominantly located in the tropics, weather radars are largely unavailable due to high installation and maintenance costs, and rain gauges are often scarce, poorly maintained, or not available in (near) real-time.

A viable and ‘opportunistic’ source of high-resolution space-time rainfall estimates is based on the rain-induced signal attenuation experienced by commercial microwave links (CMLs) in cellular communication networks. Based on received signal power levels, path-averaged rainfall intensities can be estimated, and then interpolated to produce high-resolution rainfall maps. In this study, we explore the opportunities and limitations that arise from using only CML-based rainfall estimates for rainfall nowcasting in Sri Lanka.

Using 12 months of data from 2019 and 2020 from a Sri Lankan CML network that predominantly covers the northern half of the country, we create spatial rainfall fields at 15-minute intervals. With the nowcasting algorithm pySTEPS, probabilistic nowcasts are created for lead times up to three hours for events with different durations ranging from 1 to 24 hours. The nowcasts (QPF) are evaluated against the CML rainfall fields (QPE) across 12 catchments of varying sizes and with varying CML coverage and density. The results are further analyzed by season to determine the potential influence of rainfall intensity and dominant wind direction on the nowcasts' accuracy. Hourly rain gauges, where available, are used as an independent (point) reference source of rainfall information.

With this novel application of CML-derived rainfall fields, essentially providing a ‘weather radar’ in the tropics, we identify the major sources of uncertainty in the nowcasts and highlight the potential impact of relying solely on CMLs for operational early warning services in regions that lack dedicated rainfall sensors.

Speaker: Bas Walraven (Delft University of Technology)

presentation_29_BW.pptx

11:00 → 11:30 Coffee Break

11:30 → 11:45 Urban surveillance camera for urban extreme rainfall estimation

In recent years, under the dual influence of global warming and urbanization, extreme precipitation events in cities have become more frequent. The randomness, suddenness, and spatiotemporal variability of urban precipitation have significantly increased, posing serious threats to the healthy development of society and the safety of people's lives and property. High spatiotemporal resolution surface precipitation observations are crucial for meteorological forecasting, climate analysis, and disaster warning. The widely distributed urban surveillance cameras can continuously record precipitation events and dynamically describe changes in rainfall intensity, offering advantages such as high density, rapid speed, and low cost. This provides a new opportunity for a high-resolution perception of urban precipitation.
To this end, this study analyzes the imaging patterns of heavy rainfall from the novel perspective of urban surveillance videos. It establishes a dynamic model for the relationship between precipitation intensity and video features. Based on this, a deep learning-based algorithm for quantitative estimation of precipitation from surveillance videos is proposed, and long-term precipitation observation experiments are conducted in various locations, including Nanjing, Wuxi, Changzhou, and Vienna. Comparison with synchronous measurements from devices like 2-DVD and Parsivel shows that in heavy rainfall scenarios with intensities ranging from 20 mm/h to 90 mm/h, the surveillance cameras achieve 75% accuracy in estimating rainfall intensity and 83% accuracy in measuring cumulative rainfall. In scenarios with rainfall intensities from 90 mm/h to 140 mm/h, the surveillance cameras can achieve 70% accuracy in measuring precipitation intensity and 78% accuracy in cumulative rainfall measurements.
This research aims to enhance the quantitative estimation accuracy of precipitation using surveillance cameras, thereby providing a beneficial supplement to improve the high-resolution perception capability of urban heavy rainfall and offering foundational data support for the forecasting and analysis of urban precipitation.

Speaker: Xing Wang (Nanjing university)

11:45 → 12:00 Achievements of the COST Action on Opportunistic Precipitation Sensing (OpenSense)

The COST Action OpenSense (https://opensenseaction.eu) focuses on opportunistic sensing (OS) of precipitation using data from commercial microwave links (CML), satellite microwave links (SML) and personal weather stations (PWS). OpenSense brings together scientists, experts from national weather services, owners of sensor networks, and end-users of rainfall products. The main goals of OpenSense are, to improve the access to country-wide and continental-scale OS data, to establish OS data as a widely acknowledged data source capable of providing reliable operational rainfall data, and to facilitate the use of the OS data for weather and hydrological forecasts. OpenSense has been active since the year 2022 and currently has more than 140 participants.

Here we present the main achievements of OpenSense and its working groups. We will highlight the large datasets that have been curated and made openly available in a standardized format. We will introduce the software ecosystem which was developed to simplify and standardize how CML, SML and PWS data are being processed and evaluated. In addition we will show examples of OS data merging and application of OS rainfall products. Finally an outlook will be given on the activities of OpenSense which aim to facilitate OS data access and operational usage on a global scale, with a particular focus to bring OS rainfall estimation to regions where traditional observation networks are sparse.

Speaker: Christian Chwala (KIT (IMK-IFU))

20250317_PrePEP_OPENSENSE_overview_talk.pptx

12:00 → 12:15 Rainfall estimation over the San Francisco Bay Area: a new system to infuse microphysical information into QPE

Accurate rainfall estimation in regions with complex terrain, such as the San Francisco Bay Area, poses unique challenges. This region, like much of the western United States, is strongly influenced by atmospheric rivers (ARs), narrow corridors of intense water vapor transport that significantly impact coastal and mountainous regions. The present-day routine Z-R estimation is inadequate to capture the microphysics in ARs and hence results in inaccurate quantitative precipitation estimation (QPE). The Advanced Quantitative Precipitation Information (AQPI) system, a regional initiative, employs enhanced weather radar technology to track AR-associated precipitation with high precision, with a key goal of recording microphysical features. The AQPI system supplements the large-scale coverage of the WSR-88D network with additional, locally deployed X-band and C-band radars, enhancing the accuracy of weather monitoring, forecasting, and emergency response across the Bay Area.

This study utilizes the AQPI system’s hybrid, multi-frequency radar network to improve rainfall estimation accuracy in this complex topographic environment. Key technical advancements in the AQPI system facilitate use of microphysical signatures into the QPE products and include networked calibration and enhanced radar visibility adjustments suited for complex terrain. Additionally, ongoing physical refinements are set to further improve rainfall accuracy. These include corrections for the Vertical Profile of Reflectivity (VPR) and tuning of the rainfall relationship based on microphysics and dual-polarization measurements, preventing contamination from ice.

These enhancements collectively aim to improve the precision of hydrological forecasting, providing critical insights for effective water resource management and flood mitigation efforts in the Bay Area.

Speaker: Renzo Bechini (Colorado State University)

AQPI_QPE_PrePEP2025.pptx

12:15 → 12:30 Deep Learning for Multimodal Precipitation Estimation: From Research to Operationalization

Deep Learning (DL) has seen multiple successes in Artificial Intelligence (AI) applications, such as image and text generation, visual recognition, and speech recognition. Its popularity has grown beyond AI, with wide usage in geoscience applications like meteorology, where large datasets are available for training DL models.

At the Royal Meteorological Institute of Belgium (RMIB), we studied the application of DL for precipitation estimation, particularly to merge multiple data modalities like rain gauges, weather radars, and satellite radiometer images. A model combining these modalities offers improved coverage compared to traditional methods that rely on radar scans corrected by rain gauges. Additionally, a well-trained DL model could provide more accurate precipitation estimates.

We developed a Convolutional Neural Network (CNN) at RMIB that uses automatic rain gauge measurements, the OPERA radar composite, and infrared satellite channels of SEVIRI as inputs. The CNN employs an encoder-decoder architecture to perform a multiscale analysis of these inputs, simultaneously estimating rainfall probability and precipitation rate. The model was trained and evaluated on a dataset spanning five years (2015-2019) and covering Belgium, the Netherlands, and Germany. Our DL method was validated using an independent rain gauge dataset for both instantaneous rain detection and rain rate estimation, as well as for daily precipitation accumulation. The results showed a significant improvement over the OPERA radar composite product.

Our method is currently being developed for operationalization at RMIB and will run in near real-time. Encouraged by these results, we are also studying the application of this method to dual polarization radar variables to further enhance the accuracy of precipitation estimation.

Speaker: Arthur Moraux (Royal Meteorological Institute of Belgium)

12:30 → 12:40 Correcting the melting layer effects on rainfall retrievals with a polarimetric vertical profile approach based on a local climatology

Radar-based rainfall products may suffer from strong inaccuracies due to the effect of the melting layer (ML) when the radar beam approaches the height where the temperature is 0°C. The ML is known for its enhanced reflectivity (ZH) leading to surface rainfall overestimation, but also for its decrease the cross-correlation coefficient (ρHV).
To overcome this issue, methods have been developed based on the observed vertical profiles of reflectivity (VPR) which project ZH at a certain height to the surface, assuming spatially homogeneity. The method proposed here refines this approach by incorporating polarimetric variables, hence PVPR for Polarimetric Vertical Profile of Reflectivity. The model uses lookuptables generated for various ML thicknesses and heights at several elevation angles to simulate the effect of ML on the radar beam. To accurately represent the local microphysical processes, a 5-year detailed climatology of vertical profiles of polarimetric variables was generated from three C-band radars belonging to the German national meteorological service.
For each radar beam, the PVPR starts by identifying the range where the bottom of the ML is reached (Hb), and the strength of the ML (S), defined by how much ρHV decreases. These two parameters are sufficient to characterize the ML. In the next step, the algorithm matches the observed values to the closest parameters in the lookuptables and applies the corresponding correction for each radial. This yields a corrected ZH field minimizing the effects of the ML and the snow beyond, which is used to calculate rain rates.
Daily rainfall accumulations were validated against a dense rain gauge network, showing significant improvements compared to classical retrievals. However, some issues remain. The local climatology shows substantial variability in the parameters that define the shape of the correction, including the maximum ZH in the ML, the slope of the ZH profile in snow (β), the ML thickness, among others. To examine their impact, the parameters were modified and the PVPR applied to one month of observations. Results show that adjusting β has the largest impact, but optimal results depend on estimating its value beforehand. The effect of adjusting other parameters will also be presented and discussed.

Speaker: Raquel Evaristo (Institute for Geosciences, University of Bonn)

PrePEP2025EvaristoPresentationPVPR.pdf

12:45 → 14:00 Lunch Break

14:00 → 14:30 Keynote 2: Flood forecasting in Bavaria: Organization of the flood information service (HND) and limits of early warning due to model uncertainties discussed on the basis of examples from the 2024 flood event in Swabia

Convener: Natalie Stahl-van Rooijen (Bayerisches Landesamt für Umwelt)

PrePEP neu Natalie Stahl van Rooijen_forecast_to_mitigation.pdf

PrePEP neu Natalie Stahl van RooijenFrom_forecast_to_mitigation.pptx

14:30 → 14:45 Revealing the Structure of Precipitation Extremes: a spatio-temporal Wavelet Approach

In the BMBF-funded ClimXtreme CoDEx project, we use advanced data compression techniques to analyze and characterize high-dimensional spatio-temporal weather extremes. By reducing the number of degrees of freedom, we improve the signal-to-noise ratio, facilitating a more precise assessment and detailed characterization of extreme weather events.

Here, we present a novel approach using wavelet decomposition to capture and analyze the complex spatio-temporal characteristics of precipitation extremes. Wavelet decomposition has proven to be highly effective in uncovering underlying frequency structures in time series data and is well-suited for analyzing two-dimensional patterns. Previous applications to spatial precipitation fields demonstrate their benefit for a better understanding and improved description of precipitation events.
We extend these methods to capture both spatial and temporal characteristics, providing a comprehensive description of three-dimensional precipitation fields across space and time.

We show that this approach is effective in capturing the diverse spatio-temporal features of precipitation extremes, enabling a more targeted and nuanced description of processes driving extreme weather phenomena. Our applications include comparisons of various datasets for their their representation of extreme precipitation events, with a focus on high-resolution data such as radar observations and simulations on convective-permitting scales. We also analyze and describe recent precipitation extremes in Germany, including the May/June 2024 flooding in southern Germany and the Ahr flooding in 2021.

Speaker: Svenja Szemkus (Institute of Geosciences, Meteorology Section, University of Bonn, Germany)

Vortrag_PrePEP_Szemkus.pdf

14:45 → 15:00 Simulating intra-event return period co-occurrences in short-duration intense precipitation events

Design storms mimicking extreme rainfall events are essential for planning drainage networks and managing flood risks, as they serve as input to estimate the resulting flood hydrograph. They are typically characterized by high return periods of intensity-duration relationships, which are estimated from historical records. However, current methods for estimating design storms, such as block-maxima, fail to account for observed return period co-occurrence over different durations within rainfall events and tend to oversimplify and overestimate the total rainfall amount. Focusing on short-duration intense precipitation events recorded in Zurich (Switzerland), we investigated the dependencies between critical precipitation intensities over several duration intervals, namely over the 10-, 30-, 60-, 180-, and 360-min intervals. Our analysis reveals strong dependencies, with maximum and average pairwise return period Kendall’s τ rank correlation coefficients over two of these duration intervals of 0.69 and 0.39, respectively. We model these multivariate relationships with a vine copula, which is then used to simulate critical precipitation intensities over different duration intervals, thus respecting the observed dependencies within rainfall events. These intensities are used to constrain a micro-canonical cascade model that produces the corresponding precipitation hyetographs. With the new introduced approach, we find a reduction of 29% on average in total storm volume compared to a common block-maxima approach for events with a 10-year return period on the 60-min interval. Yet, we also find that 10% of these events show an increase in the 10-min interval precipitation intensity. The new method allows for the simulation of extreme precipitation events that reflect observed intra-event return period co-occurrence and the results suggest potential implications for hydrological applications demanding realistic design storms.

Speaker: Tabea Cache (Institute of Earth Surface Dynamics, University of Lausanne, Lausanne, Switzerland)

Cache_PrePEP.pptx

15:00 → 15:15 Extreme rainfall over West Africa: Current state and projected impacts of climate change

West Africa is increasingly experiencing socio-economic distress caused by floods due to extreme precipitation events, the frequency of which is projected to increase in light of climate change. Working towards adaptation strategies generally require reliable and ideally long-term observational datasets in order to increase the knowledge about the spatiotemporal nature of extreme rainfall in the region. Thus, leveraging the capabilities of the high-resolution, satellite-based Global Precipitation Measurement (GPM) dataset Integrated Multi-satellite Retrievals for GPM (IMERG), this study evaluates the present-day as well as future statistics of daily precipitation extremes over West Africa by utilizing an extreme value analysis approach. Extreme precipitation values in IMERG for the period 2001-2022 are modelled with the generalized extreme value (GEV) distribution through yearly-based block maxima sampling of daily rainfall. A decrease of spatial uncertainty is further accomplished by using the Regional Frequency Analysis (RFA)” based on the so-called “Index-flood method”.

Results show that high return values, up to around 300 mm at a 50-year return period, are largely found over the coastal areas of West Africa, highlighting, among other things, the influence of the coastal shape on the formation of intense land-sea breeze convection, and orographic enhancement of rainfall along the Guinea Highlands. Thus, while extreme precipitation is prevalent along the highly urbanized coast, return values decrease with (a) distance from the coastline, and (b) towards the climatologically drier Sahelian region. Overall, the spatial pattern of return values for a given return period are strongly correlated with the pattern of mean daily rainfall, which suggests that the magnitude of mean daily rainfall is widely driven by precipitation extremes.

In a further step, the projection of future precipitation extremes is compiled using the statistically downscaled dataset of CMIP6 models “NASA Earth Exchange Global Daily Downscaled Projections (NEX-GDDP-CMIP6)”. By determining the difference in the GEV parameters between future scenarios and the historical runs, an adjustment of the IMERG-based GEV parameters is accomplished to mimic a potential future state of the rainfall distribution (“Delta method”). Here, the most extreme scenario SSP5-8.5 projected onto the long-term period 2081-2100 suggest an increase of the return value magnitude by over 100% in the populous coastal region of West Africa. Together with growing urbanization and the rise of sea levels, West Africa is facing dire socioeconomic stress without dedicated action plans against flood risk, especially in the densely populated Guinea Coast region.

Speaker: Marlon Maranan (Karlsruhe Institute of Technology)

PrePEP2025_maranan_extreme_westafrica.pdf

PrePEP2025_maranan_extreme_westafrica.pptx

15:15 → 15:30 Comprehending Meteorological Drought in the Tons River Basin, India: A Spatio-Temporal Assessment of Variability and its impact on water resources

Meteorological drought, a climatic phenomenon with long-term precipitation deficits, significantly affects water resources, agriculture, and ecosystems in a region with monsoon rainfall. Precipitation is becoming more variable over space and time, and hydroclimatic extremes are occurring in all types of climates, more in a warming climate. The Tons River basin (one of the Ganges' major sub-basins) frequently experiences drought, which has a negative impact on agriculture, water resources, health, and food security, leading to out-migration from the region. The basin frequently experiences meteorological drought, primarily occurring during the monsoon months with more regional variability. In the present study, an attempt has been made to analyze the seasonal precipitation variation and characteristics of the meteorological drought in the Tons River basin over space and time in the Tons River basin. The study made use of 0.25° x 0.25° Daily Gridded Rainfall Data obtained from the India Meteorological Department for the duration from 1991 to 2024. The coefficient of variation, standardized precipitation index (SPI), and the Mann-Kendall test have been calculated to understand the pattern. Furthermore, to assess the effect of meteorological drought on surface water resources, regression analysis has been used. Surface water bodies have been extracted from the Landsat Satellite images using a convolutional Neural Network.
The current study demonstrates that the Tons River basin was characterized by a severe meteorological drought in 2007-2008, 2009-2010, 2010-2011, and 2015-2015, out of which 2007-2008, had a more severe meteorological drought. Furthermore, the basin experienced 19 years of meteorological drought over a 34-year span between 1991 and 2024, ranging from moderate to severe drought. The results also reveal that drought intensity varies over space in the river basin. The study also demonstrated that surface water resources are also being affected by the extremely low precipitation. This spatio-temporal analysis of the rainfall pattern and the meteorological drought provides significant insights for policymakers and other stakeholders to enhance resilience to drought in the Tons River basins.

Speaker: Samiul Sk (Jawaharlal Nehru University, New Delhi, India)

PPT_For_Presentation Samiul_PrePep_Bonn_2025.pdf Samiul_PrePep_Bonn_2025.pptx

15:30 → 16:00 Coffee Break

16:00 → 16:30 Keynote 3: On the importance of precipitation datasets for operational hydrological monitoring and forecasting

Convener: Christel Prudhomme (European Centre for Medium-Range Weather Forecasts (ECMWF))

PEPConferenceBonn_CPrudhomme.pdf

PEPConferenceBonn_CPrudhomme.pptx

16:30 → 16:45 Prognostic ParFlow Integrated Hydrologic Model Applications at Stakeholder Scale Over Central Europe

Integrated physics-based hydrologic models (IHMs) have evolved into versatile tools constituting a cornerstone of many water resources and hydrologic hazard impacts applications from catchments to global model domains. IHMs allow for a physically consistent terrestrial water cycle representation, where groundwater and surface processes interact. To simulate groundwater-to-atmosphere feedbacks more realistically and account for the lateral redistribution of water, IHMs are hence increasingly incorporated into coupled Earth system models. Here we show applications of high-resolution prognostic simulations with the IHM ParFlow (https://github.com/parflow). Since 2020, ParFlow, with its integrated Common Land Model, is applied on GPUs in an experimental quasi-operational setup over central Europe, at a spatial resolution of approximately 600m for daily 10-day forecasts in a 52 member probabilistic forecast ensemble driven by ECMWF forecasts. Additionally, a 7-month seasonal prediction ensemble is run each meteorological season. Informed primarily by agricultural stakeholder needs in a co-design process, we provide diagnostics, such as water table depth, seepage water, plant available water, total water storage, etc., of the current state and the near-term evolution of the terrestrial water cycle through specific, targeted interfaces to data and information products (e.g., https://wasser-monitor.de, in German). The seasonal predictions are disseminated with a focus on water availability through an experimental Water Resources Bulletin (https://www.adapter-projekt.de/bulletin/index_en.html) that shows subsurface monthly water storage anomalies, including shallow groundwater down to 60m depth, with reference to a long-term ParFlow climatology, that captures the recent hydrometeorological extremes very well. ParFlow prognostic capabilities have also been demonstrated through a process-based analysis of forecasts and hindcast runs of the 2021 extreme flood event in western Germany and eastern Belgium. While this is an uncalibrated model, ParFlow well simulates many aspects including magnitude and timing of this extreme event. The physical representation of groundwater-surface water interactions affords hypothesis testing and is used to improve our process understanding of the 2021 flood event.

Speaker: Klaus Goergen (Research Centre Juelich)

PrePEP_S5Amon_KGoergenEtAl_v30f_r0-1_pdf.pdf

PrePEP_S5Amon_KGoergenEtAl_v30f_r0-1.pptx

16:45 → 17:00 GSDR: A global sub-daily rainfall dataset for understanding extreme precipitation

Precipitation extremes result in flooding and droughts, causing substantial damages and loss of life. Understanding the variability of precipitation extremes with climate change is challenging, as we do not fully understand processes causing extreme precipitation under current climate variability. The INTENSE project focuses on understanding of the nature and drivers of global sub-daily precipitation extremes and change on societally relevant timescales. As part of this, a global sub-daily precipitation dataset (GSDR) has been collected, containing hourly rainfall data from a wide range of sources (25,000 rain gauges across over 200 territories). The dataset is quality controlled (rule-based open-source methodology, GSDR-QC), combining a number of checks (e.g. neighbouring gauges, known biases and errors, Expert Team on Climate Change Detection and Indices thresholds).

Recent updates to the dataset have been made – including data from 2018-2023 – essential for understanding the current and future impacts of climate change, with current work is focused on the development of a regularly (semi-automated) global dataset, providing an extra decade of GSDR data, particularly relevant for understanding the behaviour of precipitation extremes in a changing climate, at a global scale. A set of global hydroclimatic indices have been produced (GSDRI), characterising key aspects of shorter duration precipitation variability, including intensity, duration and frequency properties, which are publicly available where possible alongside a precipitation climate indices dataset.

Speaker: Amy Green (Newcastle University)

prepep_v2.pptx

17:00 → 17:15 Hybrid modelling setups for real-time urban pluvial flood mapping

Extreme rainfall events and the resulting pluvial floods are projected to increase in frequency due to climate change. Accurate and timely flood forecasts are crucial for mitigating the impact of these events, but traditional hydrodynamic models are computationally expensive, limiting their use for real-time processing of probabilistic rainfall forecasts. This study explores the development and evaluation of spatiotemporal surrogate models that can rapidly convert rainfall nowcasts into probabilistic flood maps for highly urbanized catchments.
The focus of this research is on the hybrid surrogate modeling approach, which combines a simplified, physically-based hydrodynamic model with a data-driven component. The study investigates different formulations of the simplified physically-based model setup, ranging from coarse-resolution 1D-2D coupling to models that entirely neglect the subsurface sewer system dynamics. These simplified models are then paired with a data-driven module that bridges the gap to the detailed flood inundation patterns simulated by the reference hydrodynamic model. This hybrid structure offers a potentially beneficial balance between physical representation and computational efficiency.
In an initial analysis for the city of Antwerp, Belgium, the hybrid modelling approach resulted in a calculation speed improvement with a factor between 30 and 300, depending on the selected physically-based model component. Interestingly, utilisation of a relatively fast physically-based model which ignores the sub-surface component altogether, resulted in the best R² at the peak of the flood event (0.86), slightly better than a 1D2D physically-based model component with thrice the calculation time with (R² = 0.85). These preliminary findings will be further investigated through an extended analysis incorporating a wider range of storm events and additional physically-based model configurations to better understand the trade-offs between model complexity, computational efficiency, and prediction accuracy.

Speaker: Daan Buekenhout (KU Leuven)

PrePEP2025 - Slides - Daan Buekenhout - Hybrid modelling for real-time urban pluvial flood mapping.pdf

PrePEP - Slides - Daan Buekenhout - Hybrid modelling for real-time urban pluvial flood mapping.pptx

17:15 → 17:30 Evaluating the performance of X-band radars for QPE during heavy rain events in western Germany

Dual-polarisation X-band radars have become popular tools in the operational and research sectors to address a broad range of scientific goals: examining cloud microphysics, monitoring up-close and rapidly developing storms, quantitative precipitation estimation (QPE), among others. These weather radars can fill gaps in existing operational radar networks or provide precipitation estimates with higher temporal and spatial resolution in areas of particular interest, e.g., urban environments.
This study thoroughly investigates rain-rate retrievals derived from polarimetric X-band measurements. In particular, events related to severe heavy rain that occurred in the Rhenish mining region (western Germany) are examined. The DWD operational C-band radar network is used to evaluate the performance of the X-band radars for QPE, but also to assess the improvements when using the latter as gap fillers. The advantages and main challenges of using X-band radars for QPE are also presented. For instance:

1. Attenuation resulting from rain is significant at shorter wavelengths. It was observed that at the X-band wavelength, the specific attenuation $(A_H)$ and specific differential attenuation $(A_{DP})$ are up to three times larger than those at C-bands. Even more, heavy attenuation can lead to the total extinction of the signal in the presence of thunderstorms.
2. It is required to implement robust techniques for quality control, calibration monitoring, rainfall estimation and compositing of precipitation products based on polarimetric data collected by C-and X-band radars to generate reliable QPE products.
3. There are clear benefits of using rain estimators based on $A_H$ or the specific differential phase $(K_{DP})$ over traditional $R(Z_H)$ or $R(Z_H,Z_{DR})$ estimators as the former show a better performance in the presence of heavy rain when compared with rain gauge measurements, due to the independence of $A_H$ and $K_{DP}$ on radar power calibrations, less sensitivity to DSD variations, and being relatively immune to attenuation and beam blockage. However, methodologies especially devised to improve $R(Z_H)$ and hybrid $R(Z_H,A_H)$, $R(Z_H,K_{DP})$ estimators and overcome the issues related to power-based measurements are presented.

Speaker: Daniel Sanchez-Rivas (University of Bonn)

PrePEP_DSR_130.pdf

17:30 → 21:00 Icebreaker

Tuesday 18 March

08:45 → 09:15 Keynote 4: Flash floods predictions and mitigation under change – challenges, models, perspectives

Convener: Erwin Zehe (Institute of Water and Environment, Karlsruhe Institute of Technology)

Erwin Zehe Flash floods predictions and mitigation under changeZehe_final (1).pptx

09:15 → 09:45 Keynote 5: Advancing Precipitation Estimation and Prediction through Deep Learning at Météo- France

Convener: Léa Berthomier (Meteo-France)

PrePEP_Conference_LBerthomier_uselink.pdf

Use_link_Advancing precipitation estimation ...

09:45 → 10:00 Precipitation forecast enhancements in Destination Earth: advancing toward km-scale Global simulations

The European Commission's Destination Earth initiative is developing several digital replicas (digital twins) of the Earth system, combining state-of-the-art Earth system models and observations. One such digital twin focuses on weather-induced extremes and has two main components: daily global high-resolution forecasts developed by ECMWF, and on-demand regional simulations developed by a consortium led by Météo-France.

The Global Extremes Digital Twin (Global DT) is designed to forecast extreme weather events worldwide with unprecedented precision, offering continuous, kilometre-scale global high-resolution forecasts. Currently, the Global DT uses ECMWF's Integrated Forecasting System (IFS) cycle 48r1 with a grid spacing of approximately 4.4 km (TCo2559).

This presentation highlights the significant improvements of global km-scale simulations performance for precipitation, especially in complex orographic regions, compared to the current operational IFS 9 km resolution forecasts. The Global DT reduces both the overestimation of small 24-hour precipitation values and the underestimation of extreme precipitation amounts observed in the 9 km forecasts, resulting in a smaller absolute bias. However, challenges in simulating convective precipitation remain, such as the failure to propagate marine convective systems further inland, to simulate localised convective events in flat areas and squall lines with realistic structures in tropical areas. Adjusting the cloud base convective mass flux within the convective parameterization shows potential in addressing some of these issues. However, further investigation is required before these changes can be applied operationally, as they may lead to a decrease in forecast skill in certain regions. Additionally, several case studies of extreme precipitation events have been explored at even higher resolutions to assess their potential for improving the detection of extreme weather.

Finally, we evaluated the benefit of km-scale information for flood forecasting with simulations using the river routing model CaMa-Flood, which is directly integrated in the Global DT workflow.

Speaker: Estíbaliz Gascón (European Centre for Medium-Range Weather Forecasts (ECMWF))

prePEPconference_EGascon_March2025.pdf

prePEPconference_EGascon_March2025.pptx

10:00 → 10:15 The Southern German flooding in May and June 2024

Between Mai 30th and June 6th 2024, heavy rainfall in Southern Germany lead to severe flooding in the Danube, Neckar and Main catchment. Hazardous events of this nature receive considerable public attention, particularly due to the ongoing debate around the impacts of man-made climate change.
The BMBF funded research project ClimXtreme aims to improve our understanding of such weather extremes in a changing climate through physics, statistics and impact modeling. A main goal is the creation of a knowledge base and the dissemination of relevant information to decision makers as well as the interested public. As part of this initiative, ongoing state-of-the-art research is applied to current events and the results are published in the form of scientific reports.
The analysis reveals that the southern German floods resulted from a mix of precipitation processes on several spatio-temporal scales including convection as well as large-scale stratiform rain. Compared to previous floods, the most remarkable characteristic is the large extent in space and time. The aggregated intensity, on the other hand, was not particularly unusual and has been slightly increased by the warming climate. Nevertheless, the reaction of river runoff was extreme, particularly on the scale of small river catchments: while the overall regional runoff was the second largest in the past century, several local runoff values had estimated return times well over 100 years.

Speaker: Sebastian Buschow (University of Bonn)

PrePEPtalk_buschow.pdf

10:15 → 10:30 Return Period Analysis of Maximum Daily Rainfall Disasters in the Zagros Mountains, Iran: March (2019)

This study investigates the return period of heavy rainfall events in the Zagros Mountains of Iran, with a particular focus on the floods that occurred in March 2019. The annual and monthly variation and statistical characteristic of maximum daily rainfall variation were examined over the available data in the Karkheh River Basin, located in western Iran's Zagros Mountain. The return period of the extreme rainfall intensity is estimated using “HyfranPlus” to assess various probability distributions, including Generalized Extreme Value (GEV), log-normal, log-normal Type III, Pearson Type III, Gumbel, and Inverse Gamma.
The result shows in the annual total rainfall did not exhibit a significant trend; however, maximum daily rainfall demonstrated an increasing trend, indicating a rise in heavy rainfall events. While the Gumbel distribution proved most effective for the 72-year record at Khorramabad, the Inverse Gamma distribution provided the best fit for shorter data periods, estimating return periods of 50 to 300 years for extreme rainfall events at different stations. However, at the Pol-Dokhtar and Nurabad stations, which recorded maximum daily rainfall of 139 mm and 101 mm, respectively, in March 2019, the statistical distributions indicated return periods ranging from 70 to 300 years. Notably, the highest daily rainfall over the long term did not occur in March or April.
In March 2019, maximum daily rainfall exceeded the long-term average, a consequence of increased rainfall upstream that led to flooding downstream in the Karkheh basin. While the heavy rainfall events in March and April 2019—potentially linked to climate change—resulted in significant flooding and damage, other factors, such as alterations in land surface structure, particularly along riverbanks, also contributed to the increased human and financial losses. Overall, our research contributes to the understanding of hydrological extremes and informs strategies to mitigate flood-related damages in the Zagros Mountains, ultimately supporting climate resilience efforts in vulnerable regions.

Speaker: Jeff (Jafar) Sepehri (PhD Candidate, Earth and Space Science Dept., York University)

PerPEP-2025-Lecture.ppsx

PerPEP-2025-Lecture.pptx

10:30 → 10:45 A globally-applicable conceptual model for extreme precipitation events

Forecasting extreme precipitation events often comes with limited warning due to large uncertainties associated with convective precipitation. Given the vast socio-economic impacts of the resulting hazards of extreme rainfall, e.g., flash flooding and landslides, fundamental research into what causes these extremes remains an important priority for the community.

Using observational data from the UK a new four-stage conceptual model for extreme precipitation was developed. The conceptual model consists of i) a pre-conditioning phase, ii) a lifting phase, iii) the realization phase, and iv) the transition phase. Throughout the model a three-layered structure for the atmosphere exists: a conditionally unstable layer sandwiched between a low-level layer of increased stability and an upper-level stable layer. The conditionally unstable layer takes the form of a Moist Absolutely Unstable Layer (MAUL), and it is the release of the instability within the MAUL that drives the extreme rainfall.

To release the instability from the MAUL certain properties were observed. The MAUL needs to be associated with weak CAPE (typically < 500 J kg-1 for the UK). The MAUL also requires a warm top to ensure that warm rain processes can dominate and increase the precipitation. However, to make the most extreme events the MAUL also needs to be deep whilst remaining within the other constraints.

The conceptual model was tested over Jakarta and shown to apply in the tropics. Thus, it is a globally-applicable model. Examination of extreme rainfall events in 2024 has shown the importance of the saturation fraction in distinguishing between extremes from convective activity (localised saturation fractions close to one) and large-scale activity (widespread saturation fractions close to one). The ability to distinguish between precipitation modes enhances the forecast via inference of the predictability and characteristics of the system likely to produce the extreme event.

Global model representation shows biases in MAUL base and CAPE suggesting that improved representation of extremes will require improved vertical profiles in the model. However, due to the sparse nature of observed profiles the constraints for the model are limited.

The novel conceptual model for predicting extreme precipitation could help increase the lead time for warnings of extreme events and help focus the planning of emergency responders and public to enable to increase awareness, preparedness, and ultimately save lives.

Speaker: David Flack (Met Office)

Global_Conceptual_Model_PPN_Extremes_Flack_PrePEP_Bonn_2025.pdf

10:45 → 11:15 Coffee Break

11:15 → 11:30 Operational Hydrologic Ensemble Forecasts in Small Catchments – Implementing New Products for Precipitation Estimation and Seamless Predictions

Flood forecasting and warning for small catchments are challenging due to the short response time of the catchments on heavy rainfall events. Thus, disaster managers are interested in extended lead times to initiate flood defense measures, which can be obtained by employing forecasts of numerical weather models as driving data for hydrological models. To portray the inherent uncertainty of weather model output, ensemble hydro-meteorological forecasts can be used.
Within the scope of the project HoWa-PRO (funded by the Federal Ministry of Education and Research, Germany) we develop a hydrologic ensemble forecasting system for flood early warning in small catchments with lead times up to 48 hours. The so-called sentinel watches meteorological ensemble forecasts of the German Weather Service (DWD). If a specific precipitation criterion is surpassed, the sentinel starts collecting and concatenating various established precipitation products for precipitation estimation based on radar (Radolan-RW), nowcast (Radolan-RV), and ensemble forecast (Icon-D2-EPS, Icon-EU) to initiate a hydrologic ensemble flood forecast. The results can be followed via the web platform howapro.de.
Besides this renowned precipitation products, we set up a second hydrologic ensemble forecasting system using prototypic data of upcoming products for precipitation estimation and forecasting to explore their capabilities. Here we combine (1) observed radar data assimilated to precipitation gauges and commercial microwave links (pyRADMAN), and (2) the seamless prediction data SINFONY-INTENSE. The latter is a combination of nowcasting and numerical forecast ensembles. Both data products are delivered some minutes earlier than the established products which offer benefits for disaster managers.
The sentinel system scales well with additional catchments which can be simulated in parallel. Currently, the sentinels for both data versions (established and upcoming precipitation products) are invoked each 30 min, shortly after new observed data is delivered. The used WeatherDataHarmonizer library (Wagner and Grundmann, 2023) ensures a temporally, spatially, and formally homogeneous precipitation data set with a lead time of maximum 180 h, a time resolution of 15 min, and a spatial resolution of about 1 km. Each component of the sentinel is robust in a sense of handling missing operational data or machine faults. Additionally to the technical aspects, we present results of operational hydrologic ensemble forecasts for selected events and catchments in Saxony, Germany, and compare the performance of both systems.

Speaker: Jens Grundmann (TU Dresden, Institute of Hydrology and Meteorology)

PrePEP25_grundmann.pptx

11:30 → 11:45 Evaluation of precipitation products’ characteristics over Germany for hydrologic model forecasts

Precipitation is central to the Earth's hydrological cycle. Climate change is expected to increase the frequency and intensity of hydrometeorological extremes, highlighting the demand to improve hydrological forecasting to enable effective water resource management. Accurate precipitation data, as the main input for hydrological modeling, is key to enhance the forecast accuracy. This study evaluates the ECMWF High Resolution (HRES) NWP precipitation data jointly with other precipitation products of various origins (in-situ observations, meteorological radars, satellite observations, reanalyses). This assessment is performed in the context of our daily in-house integrated, high-resolution hydrological forecasts over central Europe, employing ParFlow/CLM driven by HRES. The European Climate Assessment & Dataset (ECA&D) in-situ daily precipitation observations serve as the reference for the 2014 to 2022 time span. The datasets evaluated include the ERA5 and COSMO reanalyses, HYRAS raster data, near real-time RADOLAN and climatological RADKLIM radar data, the OPERA radar composite with its EURADCLIM climatological dataset, and the two integrated multi-satellite products IMERG-Late and IMERG-Final. Results show that both HRES and ERA5 are well suited as atmospheric forcing for the ParFlow/CLM hydrological model runs, but have limitations in accurately simulating extreme events. The HYRAS, RADOLAN, and RADKLIM datasets, however, demonstrate a good performance with respect to extremes. As a consequence, these datasets appear to be beneficial for bias adjustments of HRES, though their application is geographically restricted to Germany. The European near real-time OPERA product often underestimates precipitation, while EURADCLIM improves the spatial representation of precipitation patterns in capturing magnitude and extremes. Both IMERG datasets tend to overestimate precipitation magnitudes and extremes, but are improving the spatial accuracy during summer months. As a next step, we plan to implement a machine learning-based bias adjustment into the quasi-operational hydrological forecasting workflow.

Speaker: Suad Hammoudeh (Institute of Bio- and Geosciences (IBG-3, Agrosphere), Forschungszentrum Jülich (FZJ), Jülich, Germany)

Suad_Hammoudeh_Evaluation_of_precipitation_product_characteristics_over_Germany_for_hydrologic_model_forecast_PrePEP.pdf

11:45 → 12:00 DeepWaive: A Paradigm Shift in Flood Forecasting through a Hybrid AI Foundation Model

The increasing frequency and severity of extreme precipitation events necessitate innovative approaches to flood forecasting and risk management. Traditional hydrodynamic modeling, while physically robust, faces significant computational constraints that limit its applicability for real-time flood prediction and ensemble-based probabilistic forecasting. This paper presents DeepWaive, a novel hybrid AI foundation model that fundamentally transforms the landscape of flood forecasting.

DeepWaive overcomes the traditional limitations of both hydrodynamic and machine learning approaches through a unique AI foundation architecture that combines the physical understanding of flood processes with the computational efficiency of deep learning. Our model achieves unprecedented processing speeds, enabling the real-time computation of two-dimensional flood inundation mapping with a computational acceleration factor of 10^6 compared to conventional hydrodynamic models. This breakthrough allows, for the first time, the parallel processing of ensemble precipitation forecasts from the German Weather Service's SINFONY products, enabling probabilistic flood forecasting at previously unattainable spatial and temporal resolutions.

A key innovation of DeepWaive lies in its generalization capabilities. Unlike conventional deep learning models that require retraining for each geographical domain, our approach demonstrates remarkable transferability across diverse topographical and hydrological conditions. This is achieved through extensive training on a comprehensive dataset of hydrodynamic simulations encompassing various geographical and meteorological scenarios. Validation results show that DeepWaive maintains high accuracy levels (R² > 0.9) across different regions while providing real-time inundation predictions.

The model's capabilities extend beyond pure forecasting to include real-time evaluation of flood protection measures, enabling dynamic assessment of intervention strategies during extreme events. This feature represents a significant advancement in operational flood management, offering decision-makers the ability to rapidly evaluate and optimize response strategies.

These developments mark a significant step forward in flood forecasting and risk management, offering new possibilities for early warning systems and risk mitigation planning. The implementation of DeepWaive demonstrates the potential of AI-driven approaches to address critical challenges in hydrological-hydraulic engineering while maintaining the physical basis necessary for reliable predictions.

Speaker: Julian Hofmann

Julian Hofmann 20250318_PrePEP 2025_FloodWaive_Hofmann (1).pptx

12:00 → 12:15 Development of Flood Level Prediction Model for Hangang Jamsoo Bridge Using Weather Climate Data and Artificial Neural Networks

Climate change has increased the frequency and intensity of intense rainfall events and the resulting flood damage is increasing every year. The accurate application of various runoff estimation methods is prone to subjective views among designers and experts. Physical models used for water resource management are difficult to build and require a high level of user understanding, including the selection of parameterization formulas. This can lead to unreliable results depending on the user, which affects the design and dimensional safety of river hydraulic structures. To compensate for these problems, artificial intelligence (AI) is increasingly being utilized. Therefore, in this study, a machine learning model was used to develop a flood level prediction model for the Han River submerged bridge, and the data of July 2011, August 2018, July 2020, August 2020, and July 2022, when heavy rainfall was concentrated, were trained and used for verification in August 2022 and July 2023. A model for predicting the water level of the submerged bridge was built using 10-minute rainfall (AWS Yongsan, Jung-gu, Seongdong, Gwangjin, Seocho, Songpa, Gangdong, and Guri) and Paldam Dam discharge as independent variables, and the water level of the submerged bridge with a 6-hour delay as the dependent variable. The models used for prediction were LSTM (Long Short-Term Memory), an artificial neural network model, and Bi-LSTM (Bi-directional Long Short-Term Memory), and the test results showed that the error of Bi-LSTM was less and the accuracy was higher, evaluating the usefulness of flood level prediction using the Bi-LSTM model.

Speaker: HA SUNG CHUL (Kangwon National Univ.)

SungChulHa_Development of Flood Level Prediction Model for Hangang River Jamsoo Bridge Using Weather Climate Data and Artificial Neural Networks.pdf

12:15 → 12:30 Tailoring SINFONY forecasts and other DWD products to flood forecasting applications following a co-design approach

In recent years, several regions in Germany experienced devastating impacts from heavy precipitation events associated with severe convective storms. To improve the prediction of such events, Deutscher Wetterdienst (DWD) is strengthening its collaboration with Germany´s flood forecasting authorities.

With its focus on the seamless and probabilistic prediction of severe summertime convective events and associated heavy precipitation, DWD´s novel Seamless Integrated Forecasting System (SINFONY) is considered as a major step towards improving precipitation information for the forecast range from minutes to approx. 12 hours. To ensure a significant contribution of the newly developed SINFONY data and products for hydrological applications, in particular the prediction of floods in smaller catchments, the SINFONY team engages in a continuous dialogue with users from flood forecasting centres. One of the main objectives is to identify user requirements and to utilize this information for targeted development of forecast products. In addition, users are supported in implementing the novel data and products in their models and decision-making processes.

Together with colleagues from regional German Flood Forecasting Centres, a joint project for augmenting the hydrometeorological value chain through co-design was initiated in 2023. The project is part of DWD´s new binational research program “Italia – Deutschland science-4-services network in weather and climate”, part of which is jointly funded by DWD and the state of Rhineland-Palatinate.

The activities within the “Co-Design Project” stretch across the value chain for the generation of hydrometeorological forecasts. They aim for:

1. a user-oriented evaluation and optimization of DWD´s
   precipitation forecasts (SINFONY, GLORI, ICON-D2-EPS,…);
2. the implementation of functionalities tailored to the needs of flood
   forecasting centres into DWD´s new warning system;
3. the evaluation of (new) DWD data and products within operational
   flood forecasting models;
4. the harmonisation and improvement of the communication of precipitation as well as flood forecasts and warnings for a better basis for decision-making

With this contribution we will provide an overview of the “Co-Design-Project”. It will be accompanied by separate presentations, providing first examples and results on the user-oriented evaluation and communication aspects. We are also interested in an exchange with participants of the PrePEP Conference, working at the intersection of meteorology and hydrology, to learn about their experiences.

Speakers: Jan Bondy (Deutscher Wetterdienst (DWD)), Julia Keller (Deutscher Wetterdienst)

Keller_Bondy_Overview_Co-Design_Project_final.pptx

12:30 → 12:45 Developing early warning systems for Greek Prefectures and Municipalities

With the aim to develop early warning systems that meet the needs of prefectures and local communities, the METEO Unit of the National Observatory of Athens has started, during the last two years, to build early warning systems that envelop a multitude of datasets on a web interface that permit to the users to easily assess the current and future weather conditions. These systems are developed in close collaboration with the local authorities to meet their specific needs.

The system includes the installation and operation of a network of meteorological stations as well as the installation and operation of level meters in selected rivers/streams. Satellite data (e.g. precipitation probability) as well as lightning data are also included. Moreover, the early warning system provides high-resolution meteorological forecasts as well as high-resolution fire weather forecasts, and expected conditions on the roads. An automatic generation of warnings sent to the authorities is also implemented, based on predefined thresholds for each category of hazard. The totality of observations and forecasts are provided through a web service. The web service is modular, so additional layers of information can be added in the future.The system is, by definition, a powerful tool for the better information of the authorities and the public before and during a severe weather event. However, the information shown in the early warning system can be used for other activities, such as agriculture, transportation and tourism.

Speaker: Kostas Lagouvardos (National Observatory of Athens)

D2_S2_6_2025-bonn-Lagouvardos.pptx

12:45 → 14:00 Lunch Break

14:00 → 14:30 Keynote 6: Precipitation nowcasting: from Lagrangian models to advanced ML approaches

Convener: Ulrich Hamann (MeteoSwiss)

2025-03-14_Hamann-et-al_Nowcasting-Methos_PrePEP_14h00.pptx

14:30 → 14:45 Application of a predictive recurrent neural network for quantitative precipitation nowcasting

Deep learning has recently become a very effective tool in radar meteorology for precipitation nowcasting. Predictive deep learning aims to learn time series and sequential data to predict future sequences, where the data is assumed to have modular structures. A predictive recurrent neural network (PredRNN) has been implemented with spatiotemporal long and short-term memory (ST-LSTM) units and additional connections between time steps and forces memory states to flow throughout the network. The model is further extended with a decoupling and reverse sampling mechanism to learn long and short-term dynamics to model the shape deformation and motion trajectories more efficiently. Polarimetric rainfall retrievals based on specific attenuation AH and specific differential phase KDP (R(AH, KDP)) are developed within the research unit RealPEP by using the Polara C++ platform from the German Weather Service (DWD). The generated rainfall maps with 5-minute temporal resolution covering the whole of Germany are fed into the PredRNN model. We investigated daily precipitation events and resized composite images for efficient data management. So far a total of 192 sequences (18 images per sequence) have been used to train, while 48 sequences are used to test the model. For the model evaluation, 6 sequential input images are used to predict the future 12 images. The PredRNN model is also opposed to an extended version of the spectral prognosis model (SPROG-LOC), which estimates spatially localized parameters of the inherent auto-regressive (AR) process. A primary comparison with SPROG-LOC showed that PredRNN outperforms. However, the experiment is still preliminary, and the best hyperparameter set has yet to be found. We will also train the model with the polarimetric radar variables to investigate further improvements. Furthermore, we aim to exploit the PredRNN to combine the predictive information content of radar measurements with satellite-based retrievals, e.g. MTG-FCI satellite-based cloud products and probability index fields for convective initiation, to further improve the lead time.

Speaker: Mst Mahfuja Akter

18March_PrePEP2025_Mahfuja.pptx

14:45 → 15:00 Enhancing radar-based nowcasting of heavy precipitation using IoT Rain Sensors and Machine Learning: A Field Study in Four German Cities

The "heavyRain" project (duration: 2022 – 2025) aims to improve short-term, radar-based forecasting of heavy rainfall events by integrating machine learning (ML) methods with Internet of Things (IoT) sensors. In a field trial conducted in four German cities—Bochum, Hagen, Lübeck, and Lüdenscheid—50 IoT-compatible low-cost rain sensors are deployed in each city. These sensors use an automotive infrared rain sensor, combined with a LoRaWAN transmitter and a photovoltaic element. LoRaWAN (Long Range Wide Area Network), a low-power wireless protocol, is already widely available in these cities. The sensors can distinguish between dry conditions and seven rainfall intensity levels, transmitting minute-averaged data through the municipal LoRaWAN network. This data is automatically collected, validated, and made accessible for further use.
Despite being single-point measurements, the dense network of sensors offers the potential to better capture the spatial structure of rainfall events due to their rapid response, even to low rain intensities. With broad deployment and optimized placement, this network is expected to enhance rainfall pattern detection at scales of 0.5 to 1 km, complementing gauge, radar and satellite data.

The project aims to utilize these sensor data to improve radar-based nowcasting. ML methods will be integrated with a classical, cell-based nowcasting algorithm implemented in the SCOUT software (hydro & meteo), which interpolates motion vectors into a 2D vector field, accounting for cell rotation and divergence, using a semi-Lagrangian method for extrapolation of radar-measured rainfall fields. Nowcast ensembles are generated based on observed uncertainties in cell detection, offering reasonable accuracy in predicting cell direction and path. However, challenges remain in forecasting cell genesis, growth, and decay. This project examines whether ML-generated insights at the cell level can address these gaps. Furthermore, the integration of additional data sources, such as satellite and radar volumetric data, will be assessed for potential improvements to nowcasting accuracy.

The "heavyRain" project is funded within the initiative MFUND by the German Federal Ministry of Transport and Digital Infrastructure.

Speaker: Annika Jahnke-Bornemann (hydro & meteo GmbH)

prepep2025_jahnke-bornemann_16-9-Format_final.pdf

15:00 → 15:15 Studies of Convection-Permitting Ensemble Forecasting for ICON-D2 with a 1km Nest over the Alps

Within the context of the “Global-to-Regional ICON digital twin” (GLORI) project, a convection-permitting ensemble forecasting is established in order to study the predictability of high-impact weather events with high-resolution modeling (up to 500 m) and the influence of the land-surface—atmosphere coupling mechanisms.
At the DWD, ICON-D2-EPS is the limited-area high-resolution component of the ICON modeling system, running as an ensemble of 20 members at 2 km horizontal resolution over Germany and surrounding areas. The perturbed initial conditions are provided by the km-scale ensemble data assimilation system KENDA, run at the same resolution, assimilating a wide range of observations, including radar-derived radar volumes. Boundary conditions are provided by ICON-EPS, the global ensemble with a refinement at 13 km over Europe and is refreshed every 3 hours.
In this work, we employ a nested domain with horizontal resolution of 1-km in the southern region of the ICON-D2, encompassing the Alps mountains. We run a 24-hour forecast simulation starting at 00UTC on the 21st of June 2022, with 20 ensemble members. The choice of the date is crucial as it corresponds to a day when the DWD recorded instances of heavy rain and hail in southern Germany.
In our study, we perform all experiments using a two-moment microphysics scheme. Additionally, we incorporate the standard operational model perturbations and subsequently analyze the influence of various convection schemes on the predictability of processes that lead to convection development. Specifically, we examine the behavior of the convection scheme in two configurations: shallow convection only and deep convection parameterization in the so-called gray-zone-tuning version. By selectively enabling and disabling these schemes, our goal is to evaluate their individual contributions to predictability.
Following this, we implement a tailored variant of the stochastically perturbed parameterization scheme (SPP) in ICON in order to delve into the influence of some uncertain parameters within either microphysics or turbulent parameterization, further advancing our understanding of its effects on the model performance.

Speaker: Zara Parsakhoo (DWD)

PrePEP2025_Bonn_ZahraParsakhoo.pdf

PrePEP2025_Bonn_ZahraParsakhoo.pptx

15:15 → 18:00 Poster Session

Poster session with coffee and drinks in the Aula

Wednesday 19 March

08:45 → 09:15 Keynote 7: How ML is transforming our approach to seamless weather forecasting

Convener: Daniele Nerini (MeteoSwiss)

20250319_PrePEP_Seamless_DNerini.pptx

09:15 → 09:30 Assimilation of Lightning and Reflectivity Texture Fraction in ICON-LAM

Since mid-2024, the German Weather Service's Rapid Update Cycle (RUC) has been running operationally, marking the culmination of work that began in 2016, in response to catastrophic floods caused by extreme summer precipitation. The core of the RUC is the ICON-LAM regional model, running with 2-moment microphysics and a 1-hourly data assimilation cycle.

A key feature of the RUC's data assimilation process is the incorporation of not only conventional observations but also cloud- and precipitation-dependent data, such as radar reflectivities and radial winds, and visual and infrared wavelengths from the SEVIRI instrument. The implementation of 2-moment microphysics has notably improved the simulation of convection and precipitation, leading to a reduction in the rejection rate of precipitation-related observations during data assimilation and weaker a priori biases for the assimilation increments to overcome. These advancements have paved the way for the inclusion of additional precipitation-related observations, including lightning flash rate and convective object features derived from the cell-tracking system used in nowcasting.

Nevertheless, substantial challenges remain in constraining convective processes via hourly data assimilation, in particular because convective systems are nonlinear, non-Gaussian, and often discontinuous, making them difficult to constrain with typical assimilation methods. Here we investigate how the assimilation of convection-related quantities can be improved by considering the so-called texture fraction, a quantity that measures observation-model misfit on customizable scales and thresholds. We apply this principle to two convection-related observation types: two-dimensional radar reflectivity composites and lightning flash rates from ground-based antennas. We show that judiciously choosing the length scales and thresholds of this quantity can improve forecast precipitation within the first one to three forecast hours following an assimilation update.

Speaker: Lisa Neef (Deutscher Wetterdienst)

neef.pptx

09:30 → 09:45 Assimilation of 3D polarimetric microphysical retrievals using the operational ICON model framework of DWD

The use of dual-polarization radar data for model evaluation and data assimilation (DA) has the potential to enhance the representation of microphysical processes in numerical weather prediction (NWP) models and short-term quantitative precipitation forecasts (QPFs). Reimann et al. (2023) evaluated in a first study but for only two stratiform and one convective rainfall events in the summers of 2017 and 2021 the benefits of radar-derived liquid water content (LWC) and ice water content (IWC) in data assimilation. These two quantities are derived from observations of the operational dual-polarimetric C-band radar network of the German national meteorological service (DWD, Deutscher Wetterdienst) and assimilated into the operational convective-scale NWP model ICON-D2 of DWD using the ensemble-based KENDA (Kilometer-Scale Ensemble Data Assimilation system) framework.
This study extends the work by Reimann et al. (2023). E.g. since spring 2021, the radial resolution of the radar volume scans has been increased from 1 km to 0.25 km, enabling also to increase the accuracy of the microphysical retrievals. We present our advanced setup, including e.g. Z$_{DR}$ calibration, and will show our preliminary results on the performance of different assimilation configurations. The configurations are the assimilation of conventional observations (CONV), the additional assimilation of 3D reflectivities (Z$_{H}$), the assimilation of 3D LWC or IWC below or above the melting layer instead of Z$_{H}$ where possible and the joint assimilation of all radar sets together with CONV. We demonstrate how the use of updated retrievals using both the new higher radial resolution only and revised optimized DA settings compares to previous assimilation results from Reimann et al. (2023). Since the accuracy of state-of-the-art polarimetric microphysical retrievals is still reduced in the presence of riming, we focus on stratiform events only, such as the precipitation event on 14 July 2021 in the Ahr valley and the recent event on 31 May 2024 in Bavaria and Baden-Württemberg. Both events led to devastating floods. Further investigations are underway to apply the double-moment bulk microphysics scheme in the data assimilation framework, which is potentially more suited to digest the polarimetric information content compared to the single-moment scheme.

Speaker: Armin Blanke (Institute of Geosciences, Departement of Meteorology, University of Bonn)

19032025_PrePEP_Bonn_Armin_Blanke.pdf

09:45 → 10:00 Commercial Microwave Link (CML) Data Assimilation with the LETKF

In this study, we examine the assimilation of a novel data source, namely commercial microwave link (CML) data. Originally, CMLs are employed for the interconnection of cell phone towers operated by mobile network providers, however, CML data also contain valuable information about atmospheric conditions at the ground level due to interactions of the transmitted radiation signal with, for example, raindrops. In fact, CML data are already successfully used for the purpose of quantitative precipitation estimation with high spatio-temporal resolutions and are becoming an important complement to radar data in this respect.

Here, we deal with the assimilation of CML attenuations in NWP models and investigate whether CML data are also able to improve precipitation forecasts and how the effects of a CML data assimilation compare to those of an assimilation of other observation types, such as radar data. An important building block of this work is the use of EMVORADO, originally a radar forward operator, to compute a simulated model equivalent for each CML observation. Furthermore, the state-of-the-art, convective-scale ICON-KENDA ensemble data assimilation framework—based on an implementation of the LETKF and the regional NWP model ICON-D2 covering central Europe—is employed for our numerical calculations.

Performing single-time assimilation experiments, we study internal details of the LETKF assimilation process, spatial distributions of increments for the temperature and specific humidity, and the behavior of the NWP model in short-time periods directly following an assimilation—and compare these results with those obtained from an assimilation of conventional or radar data. We are able to show that an assimilation of CML data, even on top of an assimilation of either conventional or a combination of conventional and radar data, is able to accurately initiate new convection and to significantly improve the fractional skill score by up to 10%.

Speaker: Klaus Vobig (DWD)

presentation_vobig_2025-03-19.pdf

10:00 → 10:15 Evaluate the Impact of Dual-Polarization Radar Data Assimilation Using Observation Operators

The characteristics of simulated dual-polarimetric (dual-pol) parameters are significantly affected by configurations of dual-pol operators, leading to different covariance structures and results of data assimilation. In this study, the simulated reflectivity (ZH) and differential reflectivity (ZDR) are obtained via two different calculation methods, analytic and numerical integration of the scattering amplitude (SA). , The former fits the SA with power law to obtain an analytic solution while the latter integrates the SA bin by bin. The results show that the ZHH structure can be well simulated by the analytic integration method, but it leads to negative ZDR values for small raindrops and exaggeratedly large ZDR values for large raindrops. . Besides, the joint frequency between ZDR and ZHH is different from observation. On the contrary, the numerical integration method presents reasonable simulation of both ZHH and ZDR and well capture the joint frequency pattern of ZHH and ZDR. To sum up, directly integrating SAs bin by bin results in a reasonable ZDR structure in the background field and leads the analysis closer to the observation.

Speaker: Chin-Chuan Chang (Department of Atmospheric Sciences, National Central University, Taiwan)

Chang_et al_Evaluate_the_Impact_of_Dual-Polarization_Radar_Data_Assimilation_Using_Observation_Operators.pptx

10:15 → 10:30 Latest Result of Including ZDR Column for Enhanced Radar Data Assimilation at German weather Service (DWD)

Radar data assimilation has been operationally used in the short-range ensemble numerical weather prediction (SRNWP) system (ICON-D2-KENDA LETKF system) at DWD since 2020 (radial wind from March 2020 and reflectivity from June 2020). It is in addition to the traditional Latent Heat Nudging (LHN) of 2D radar-derived precipitation rates.

Moreover, the study of radar data assimilation in numerical weather prediction (NWP) models, especially its impact on short-term forecasts, has gained significant focus recently at DWD. The seamless Integrated Forecasting System (SINFONY) project, which leads a short-term forecasting system for convective events from minutes up to 12 hours, clearly demonstrates the benefits of radar data assimilation in enhancing short-term forecast accuracy.

Furthermore, the integration of polarimetric radar parameters as a novel observational source into the data assimilation system at DWD has recently gained attention. Among these parameters, the ZDR column—defined by differential radar reflectivity (ZDR)—stands out as a distinct vertical layer of positive ZDR above the 0°C level. This feature is closely associated with deep convective storms and can indicate large raindrops or hail. We present our latest results on incorporating the ZDR column as a new observational input in Observing System Simulation Experiments (OSSE), complementing radial wind and reflectivity data within DWD’s operational data assimilation framework.

Speaker: Kobra Khosravian

PrePep_March2025_KKhosravian.pdf

10:30 → 11:00 Coffee Break

11:00 → 11:15 High resolution data assimilation in the GLORI Project

The GLORI (Global-to-Regional ICON) project, born from the trilateral collaboration between German, Italian and Swiss institutions, aims to develop a global to regional digital twin based on the prediction capability of the ICON modeling system. One of the main focuses of the project is to improve forecasts, including quantitative precipitation forecasts, at different scales by exploiting the knowledge and capabilities known about high resolution.

The model integration domain encompasses the Italian peninsula and includes areas characterized by complex orography where high resolution is expected to better resolve physical processes and provide more accurate forecasts. The improvement is conditioned by several factors that are concurrently investigated by the different research groups involved in the project. The relevant topics for high resolution are the description of the physical processes, the improvement of the ensemble and the data assimilation.

In this context, this work presents the first step towards high-resolution assimilation by investigating the case study of the flood in Emilia-Romagna last October. The ultimate goal is the direct assimilation at 1 km, which requires a thorough assessment of the entire assimilation chain. Achieving this involves a new evaluation of the thinning and averaging of observations, their localization and the observation error. For this reason, the first step is to analyse and evaluate the behavior of assimilation at 2 km, with nesting at 1 km.

The system and tests results will then be described. Results include QPF verification over forecasts performed both using fractions skill score and dichotomous scores.

Speaker: Virginia Poli (Agenzia ItaliaMeteo / Arpae Emilia-Romagna)

PrePEP_Poli.pdf

11:15 → 11:30 Current status of SINFONY – The combination of nowcasting and numerical weather prediction for forecasting convective events at DWD

DWD's new Seamless Integrated Forecasting system (SINFONY) is targeted to improve very-short-range forecasting of intense convective events from observation time up to 12 h ahead for Germany. Weather radar is at the heart of it.
The goal is to produce seamless ensemble forecast products in observation space, i.e., radar reflectivity composites, precipitation fields and convective cell objects, as well as informations on the probability of hazards like heavy precipitation, hail, wind gusts and lightning. These products will hopefully serve as basis to improve DWD's meteorological warnings (forecasters, automated systems) as well as the warnings of the German flood forecasting authorities.

There are different optimal forecast methods for different forecast lead times, and the idea is to improve and combine them in an optimal way. Focusing on convective events and their related hazards up to several hours, we developed in the last seven years in an interdisciplinary team

1) radar Nowcasting ensembles for areal precipitation, reflectivity (STEPS-DWD) and convective cell objects including hail and life cycle information (KONRAD3D-EPS) with good forecast quality up to 1-2 hours,

2) a new regional NWP ICON-ensemble model (ICON-RUC-EPS) with assimilation of 3D radar volumes, cell objects, Meteosat VIS and IR channels and hourly new forecasts on the km-scale, whose quality exceeds Nowcasting after forecast hour 1-2,

3) and to get the best of both worlds for our customers, an optimal combinations ("blending") of Nowcasting and NWP ensemble forecasts in observation space, which constitute the seamless forecasts of the SINFONY. Gridded combined precipitation and reflectivity ensembles are targeted towards hydrologic warnings. Combined Nowcasting- and NWP cell object ensembles help evolve DWD’s warning process for convective hazards towards flexible “warn-on-objects.

4) Common Nowcasting and NWP verification systems for precipitation, reflectivity and cell objects help to continuously improve the SINFONY components.

For 2), efficient forward operators for radar volumes (EMVORADO) and visible/infrared satellite data enable direct operational assimilation of these data in an LETKF framework. Advanced model physics (2-moment bulk microphysics with prognostic hail) contribute to an improved forecast of convective clouds, whose simulated life-cycle proofed to be surprisingly realistic.

For 3), the ICON-RUC-EPS forecasts output simulated reflectivity volume can ensembles of the German radar network every 5’. Radar composites and KONRAD3D cell objects and their tracks are generated by the exact same methods as in the Nowcasting. These are seamlessly combined with the STEPS-DWD- and KONRAD3D-EPS Nowcasts with encouraging quality - resting upon the improvements for Nowcasting (1) and NWP (2).

Meanwhile the system has matured and is in the process of operational installation. A number of its components have been run continuously during the last four convective seasons. This presentation will give a short overview on the system components and its performance during the last years.

Speaker: Ulrich Blahak (DWD)

SINFONY_prepep2025_ublahak.pptx

11:30 → 11:45 Project IMA: seamless predictions at the Royal Meteorological Institute of Belgium

Seamless prediction systems are designed to deliver frequently updated forecasts that span various timescales by combining extrapolations of the most recent observations - such as weather radar data - with numerical weather prediction models. End users such as hydrological services, local authorities, smartphone users and the renewable energy sector, require increasingly early and accurate forecasts, especially for fields with a high spatiotemporal variability such as precipitation. Moreover, downstream impact models such as (urban) hydrological models have a strong nonlinear dependence on the meteorological input. So in addition to being fast and accurate, we also need calibrated ensembles of forecasts to conduct a proper error propagation to assess the impact uncertainty.

In response to these requirements, many national meteorological services have introduced seamless prediction systems, with notable examples including DWD's SINFONY, Met Office's IMPROVER, and Geosphere Austria's SAPHIR. In Belgium, Project IMA (after the Japanese word for "now" or "soon") represents the country’s seamless prediction approach, utilising the RMI's observations network, the gauge-corrected quantitative precipitation estimate RADQPE, the pysteps-be probabilistic rainfall nowcasting system, the INCA-BE analysis and nowcasting system, and the ACCORD NWP model configurations ALARO and AROME. Unlike many other seamless systems, Project IMA features seamless ensemble precipitation nowcasts from 0 to 6 hours, aimed to improve predictions of flash floods and their uncertainty.

We present the advancements within Project IMA and especially the novelties in pysteps. We share a glimpse of deep learning-based blending methods to extend forecast horizons and improve calibration, sharpness, and general utility for hydrologists, crisis managers, and other stakeholders.

Project IMA aims to integrate research swiftly into operational processes. It encourages contributing to open-source software such as pysteps, promoting transparency, reproducibility, and international collaboration, and supporting the UN's initiative for “Early Warnings for All” by 2027.

Speaker: Lesley De Cruz (Royal Meteorological Institute of Belgium - Vrije Universiteit Brussel)

Project IMA - Lesley De Cruz - PrePEP conference.pptx

11:45 → 12:00 Seamless Combination of Object-Based Probabilistic Nowcasting and NWP Ensemble of Convective Cells From KONRAD3D

Convective events have long been one of the most difficult phenomena to predict, making them a major focus of the SINFONY project at the DWD. Our new product is at the forefront of this effort, designed to revolutionize short-range forecasting (up to 14 hours) for convective storms by seamlessly integrating enhanced nowcasting and numerical weather prediction (NWP) into one powerful, cohesive forecast tool.

In this work, we aim to combine convective cells detected through probabilistic nowcasting with those from numerical weather prediction (NWP). The detection of these cells is performed using KONRAD3D, a state-of-the-art method developed at the DWD to identify and track convective cells based on radar reflectivity. This approach can also be applied to cells simulated by NWP, as the model forward operator, EMVORADO, generates simulated radar data with the same structure and temporal resolution as actual radar observations.

First, the simulated cells are spatially clustered using the DBSCAN method. After clustering, each observed cell is linked to the nearest cluster of simulated objects. The properties of the simulated cells are then compared to those of the observed radar cells using a score known as the total interest. Only cells that exceed a certain total interest threshold—indicating the greatest similarity to the observations—are selected for combination. Finally, the selected simulated cells are spatially adjusted so that their centroid matches the position of the nearest observed cell. Simulated cells detected within a specific time window around the observation but not matched to an observed cell are excluded from further consideration.

We also perform ensemble nowcasting of observed cells. In this process, the position, movement, and severity are subjected to stochastic noise. Additionally, a parabolic lifecycle of cell severity is assumed.
As a result, each observed cell receives a seamless forecast of its development through ensemble nowcasting, as well as from assigned model cells.
Moreover, thanks to the model input, our approach can account for the formation of new cells, which offers an advantage over pure nowcasting.

For forecasters, we provide compact information in the form of representative members and occurrence probabilities for cells based on their severity.
Since last year, the product has been under evaluation not only by the DWD but also by the ESSL Testbed.
We present an overview of our product, along with statistical verification and a prominent case study.

Speaker: Lukas Josipovic (Deutscher Wetterdienst)

20250319_ljosipov_PrePEP_2025.pptx

12:00 → 12:15 Seamless Integrated Rainfall Forecasts using Nowcasting and NWP-Ensembles

Reliable and accurate short-term rainfall forecasts are crucial for effective weather warnings, particularly during the convective season. At Deutscher Wetterdienst (DWD), rainfall warnings traditionally rely on either nowcasting or numerical weather prediction (NWP). Recent advancements within the SINFONY project (Seamless Integrated Forecasting System) aim to deliver seamless ensemble forecasts of short-term rainfall. In addition, flood forecasting is an important application and has gained more focus after extreme flooding events in recent years. Here, we will present a seamless combination technique that integrates radar nowcasts from DWD's STEPS implementation with NWP forecasts from the new rapid update cycle of the ICON-D2 model. Moreover, we will show a thorough verification for a period in May and June 2016 with lots of severe convection and heavy rainfall.

The proposed method INTENSE (Integration of NWP Ensembles and Extrapolation) employs a localized Bayesian approach inspired by an ensemble Kalman filter. It begins with a stochastic extrapolation of current radar observations with a 5-minute lead time using STEPS. This is followed by a localized analysis of extrapolation and NWP ensemble spread. Next, a correction is applied to the extrapolation forecast, shifting it towards the NWP forecast. The local degree of correction depends on the comparison ensemble spreads, i.e., the higher the extrapolation spread in comparison with NWP spread, the stronger the correction towards NWP for the current lead time. This process is repeated iteratively, with the corrected data as the input for the next lead time.

INTENSE delivers combined ensemble forecasts consisting of 21 members with a maximum lead time of 12 hours at a spatial resolution of 1 km² and a temporal resolution of 5 minutes. Moreover, we provide spatial analysis of ensemble spread, exceedance probability for certain thresholds, as well as percentiles. Real-time test operations are running with a preliminary version since June 2024 and the evaluation by DWD meteorologists is about to start.

This contribution offers an overview of the seamless combination approach and presents verification results demonstrating its advantages over pure NWP and nowcasting approaches. Fraction Skill Score as well as Critical Success Index show a clear improvement in comparison with pure STEPS nowcasting and pure NWP forecasts. For short lead times, INTENSE performs similar to STEPS and for longer lead times it preserves the forecast quality of the ICON-D2-RUC model. Furthermore, we will show an example of a recent convective event and discuss shortcomings as well as future improvements.

Speaker: Christian Berndt (Deutscher Wetterdienst)

20250319_cberndt_PrePep2025_Bonn.pptx

12:15 → 18:00 Excursion: Excursion to the Ahr valley with guided hydrological tour

Thursday 20 March

08:45 → 09:15 Keynote 8: Nowcasting extreme rainfall over the UK

Convener: Katie Norman (Met Office)

Katie Norman_PrePEP.pptx

09:15 → 09:30 Towards smarter weather radar: a simulation study of adaptive scanning strategies for improved precipitation monitoring and forecasting.

Weather radars are essential to the reliable monitoring and forecasting of intense precipitation. Yet, the current radar-based nowcasting systems often rely on sub-optimal scanning strategies which limit the system’s effectiveness. Adaptive scanning techniques - where the radar’s rotation speed or direction are dynamically adjusted in response to a cell’s position, movement, and intensity - have the potential to significantly improve nowcasting performance. So far, these benefits have largely been assumed rather than systematically tested. In this study, we present preliminary findings from numerical simulations designed to quantify the advantages of adaptive scanning strategies for an X-band weather radar.

Our approach uses a single radar with unidirectional azimuth scanning and a variable rotation speed, targeting a single moving precipitating cell within its range. A closed-loop control system adjusts the radar’s rotation speed based on real-time estimates of the cell’s location and motion. We compare this adaptive scanning strategy to the conventional approach of a fixed antenna rotation speed, extending the analysis to more complex cell trajectories for greater realism. Whilst preliminary, we hope these findings will spark further research into the science of adaptive scanning and its potential to enhance precipitation monitoring, tracking, and forecasting within radar networks.

Speaker: Shafi Sardar (Technische Universiteit Delft)

PrePEP d2.pptx

09:30 → 09:45 Development and Calibration of a Low-cost AESA Module for Weather Sensing at X-band

Phased Array Radars (PAR) are based on Active Electronically Scanned Array (AESA) antenna apertures enabling nearly instantaneous beam steering. Being not constrained by the inertial steering of mechanical parts, only the electronics settling time acts as a limiting factor, leading to a beam repositioning latency ranging around just a few microseconds. AESA technologies clearly bear potential to reach the goal of providing volumetric weather maps with a faster update time and therefore contribute to improving forecasting accuracy.
Crucial for the actual instantiation of this technology is the development and validation of engineered solutions suitable to originate a data quality similar to their mechanically-steered counterparts while targeting reduction of ownership cost.
Favorably, technological breakthroughs leading to increased functional integration on dice can finally empower electronic designs requiring a drastically reduced board surface. A compact PCB layout with a lower number of layers, tracks and parts count is an essential condition for streamlined assemblies. Additionally, inexpensive FPGAs and related COTS ICs have been found capable to generate control signals with sufficient timing accuracy and dynamic to drive the core AESA ICs like beamformers and transceivers.
An AESA front-end capable of steering up to four channels, the so-called ARM (Active Row Module), has been developed to ensure actual feasibility and evaluate the achieved performance.
Central for reaching the required data quality by means of cross-polarimetric discrimination in excess of 30 dB, a specialized antenna design based on feed-probe rotation has been validated.
Furthermore, to ensure compliancy of the aperture radiation diagram at steering conditions (namely, sidelobe levels and similarity of beam aperture across polarizations) an automated calibration methodology has been developed to compensate for chipsets and board specific imbalances.
Similarly to fully-fledged AESA implementations featuring multiple digital channels, actual radiation performance thoroughly depends on array calibration. However, while digital architectures allow for precise adjustments of the radiated power per each channel (via controlling of DACs and potentially per each radiator), the same does not hold true for single-channel analog beamformers, where analog multiport networks excite transmitting ICs and combine the received echo. Originating from the cost-compromised nature of analog beamforming architectures, an additional source of complexity therefore requires proper addressing via a calibration process relying on ICs characterization and selection of the most appropriate steering states per each hardware implementation.
Initial results show suitability of properly calibrated analog beamformers for the generation of polarimetric weather products.

Speaker: Stefano Turso (Fraunhofer FHR)

250318~PrePEP.2025.WRADph2.07.pdf

Turso~PrePEP.2025.WRADph2.07.pdf

09:45 → 10:00 Wind drift effect on radar data through analysis of individual drop trajectories using 3D+1 innovative wind product

Hydro-meteorologists and practitioners in charge of storm water management in complex areas such as cities or mountains are interested in high resolution space-time precipitation rainfall data, typically few hundreds of meters in space and few minutes in time. A crucial issue to get accurate data is the wind drift effect. Indeed, weather radars measure rainfall in altitude, and drops are advected by wind during their fall which affects the location of the measured field. This drift can be of few kilometres.

A recent study explored this issue through the simulation of individual drops trajectories in 3D space and time relying on: (i) an explicit numerical scheme to solve the non linear governing equations of rain drop’s motion which relates the acceleration to the forces of gravity and buoyancy along with the drag force; (ii) a simplistic wind simulation approach relying on 100 Hz 3D sonic anemometer and scaling laws. Universal multifractals are used to quantify retrieved results. This physically based and mathematically robust framework has been extensively used to analyse and simulate geophysical fields extremely variable over wide range of space-time scales as wind and rainfall. Implementation of this model for drop trajectories enabled to show that multifractal features of input wind are retrieved also on drop velocities with an additional fractional integration. Large drops exhibit greater level of fractional integration. Simulating the fall of drops from an altitude of 1500 m, it was possible to show that for a strong wind event, drops located within a radar gate in altitude during 5 min are spread on the ground over an area of the size of a few kilometres which corresponds to numerous radar pixels. Furthermore drops of various sizes do not reach ground at same location.

In this study, the same numerical scheme is implemented using as space-time wind input a novel 3D product of Central Weather Agency, Taiwan. It provides vector wind over voxels of size approximately 1 km in horizontal direction, 500 meter in the vertical every 10 min. In a first step, trajectories of individual drops of various size and various initial locations are simulated. Multifractal features of simulated velocities are quantified and compared against expectations. Their spread over ground level is quantified as well as its evolution during the rainfall event. In a second step, these results are used to explore and interpret rainfall patterns observed on the 3D+1 available radar data. At last, consequences of these finds on the wind drift effect on radar rainfall data are discussed.

Authors acknowledge the France-Taiwan Ra2DW project (supported by the French National Research Agency – ANR-23-CE01-0019-01 and Taiwan’s National Science and Technology Council – 113-2923-M-002-001-MY4) for partial financial support.

Speaker: Auguste Gires (Hydrologie Météorologie et Complexité, Ecole nationale des ponts et chaussées, Institut Polytechnique de Paris, Champs-sur-Marne, France)

2025_03_PrePEP_Bonn_Gires_et_al_v2.pdf

10:00 → 10:15 Melting Layer and Riming Detection from Vertically Pointing C-band Radar Observations

The German weather radar network consists of 17 dual-polarization Doppler C-band radars that are operated by the German Weather Service (DWD). These radars are evenly distributed across Germany and record data continuously. One component of the scanning cycle is a vertically looking 'birdbath' scan, which is performed every 5 minutes for a duration of 15 seconds. While the zenith configuration is common for Ka- and W-band cloud research radars, it has mostly been used to calibrate ZDR in operational weather radars so far. Despite the lower temporal resolution, comparisons between zenith observations from cloud radars and weather-radar birdbath scans in close proximity with each other reveal remarkable agreement in the recorded large-scale patterns for various weather systems. In this contribution, we present two data products that can be derived from these scans: A melting layer detection and a classification of rimed particles. Both products make use of the Doppler velocity of falling hydrometeors. The melting layer detection is based on the sharp increase in Doppler velocity in the melting region, while the riming detection algorithm is searching for continuous regions of unusually high (>1.5 m/s) Doppler velocity above the melting layer. Unlike many cloud research facilities, there is generally no additional meteorological instrumentation at the operational sites, so our products must work solely on radar data. Both algorithms are designed to work without manual support, so that they can be used operationally. We will compare the melting layer and riming products to similar implementations previously developed for cloud radars and discuss the challenges and modifications needed to apply the algorithms to the operational weather radars. One benefit of transferring research products to operational radars is the large spatial coverage of such national weather radar networks (about 150 weather radar sites with profiling capabilities across Europe).

Speaker: Paul Ockenfuß (Meteorological Institute, Ludwig Maximilians Universität München)

PaulOckenfuss_PrePEP.pdf

10:15 → 10:30 Hydrometeor partitioning ratios for polarimetric ground-based and dual-frequency space-borne and radar observations

Broadly used radar-based Hydrometeor Classification (HMC) algorithms solely identify the dominant hydrometeor class within a resolved radar volume. More recently, however, methods have been developed to estimate the proportions of individual hydrometeor types (hydrometeor partitioning ratios, HPR) within the mixture. These advanced algorithms (HMC-DP) are exploiting dual-polarization (DP) measurements of ground-based weather radars (GR), while similar algorithms for space-borne radar (SR) observations with dual-frequency (DF) capabilities are not yet available. In this study, we exploit the combination of DF SR and DP GR to develop an algorithm for HPR estimation based on satellite DF observations (HMC-DF) and to improve the HMC-DP based on GR DP observation. The evaluation of HPR retrievals, derived from either GR or SR, is challenging. However, this study also presents an evaluation of the HPR retrievals derived from HMC-DP and HMC-DF.
Therefore, the DP observations of NEXRADs WSR-88D GRs are matched with the measurements of the Dual-frequency Precipitation Radar (DPR) of the Global Precipitation Measurement (GPM) core satellite. The matched volumes, represented by averaged DF or DP measured variables, contain a few SR but several hundred GR measurement volumes, depending on the distance to the GR. This large difference in observation resolution allows the determination of quasi HPR (qHPR) per matched volume obtained from the dominant hydrometeor types (standard HMC) classified by the GR. The matched DF and DP are utilized to derive centroids and covariance matrices for each individual hydrometeor class based on the qHPR. These centroids and covariance matrices serve as the basis for the HMC-DP and HMC-DF algorithms and their HPR retrievals, which in turn are verified with the qHPR.
Results demonstrate a high degree of agreement between the HPR distributions derived with HMC-DF and HMC-DP. The HPR derived with HMC-DP show a higher correlation with the qHPR in comparison to the HPR derived with HMC-DF. This is due to the fact that DP, compared to the DF observations, provide additional information, for example, regarding the orientation, shape and homogeneity of the hydrometeors within the measurement volume. However, both HMC-DF and HMC-DP underestimate snow with biases of -5%, overestimate HPRs of graupel with biases up to 3% and show low correlations of 0.37 for DP and 0.16 for DF estimates of big drops HPR.

Speaker: Velibor Pejcic (Universität Bonn, Institut für Geowissenschaften Abteilung Meteorologie)

pejcic_2025_prepep.pptx

10:30 → 10:45 Developement of a microphyscial retrieval based on beam-aware columnar vertical profiles: Combining side-looking polarimetry with vertical radar measurements

The understanding of microphysical processes and properties in clouds plays a substantial role in the improvement of existing numerical weather models and forecasting. To gain access to these quantities deep within clouds, microphysical retrievals based on radar measurements are indispensable tools. Single-wavelength radar measurements, however, are not enough to properly constrain the microphysical properties of hydrometeors like size and shape alone and therefore need to be paired with additional observations like multi-wavelength or polarimetric quantities. While polarimetric quantities are mainly useful from an oblique perspective, multi-wavelength or doppler fall-speed observations are best made vertically and from close distance.

To tackle this observational dilemma we employ the previously developed method of beam-aware columnar vertical profiles (BA-CVPs) to combine a vertically pointing cloud radar in the Ka-band with operational measurements of two side-looking polarization Doppler weather radars in the C-band which are part of the national German radar network operated by the Deutscher Wetterdienst. In the next step a microphysical retrieval is developed incorporating existing approaches based on dual-wavelength ratio and differential reflectivity measurements to study the size and shape of hydrometeors. The measurement geometry grants the opportunity to explore the inclusion of linear depolarisation ratio and Doppler fallspeed velocity measurements in the retrieval to further constrain existing ambiguities. Retrieval results based on simple T-matrix scattering simulations are compared to results using more sophisticated discrete dipole approximation simulations weighing computational cost against accurate scattering properties of simulated hydrometeors.

The findings of this study in form of more accurate information about ice hydrometeors based on multi-frequency radar measurements can ultimately be used to improve existing numerical weather models with regards to ice growth processes and their representation within the models. Naturally, the retrieval can be applied to any other measurement geometry that combines side- and vertically-pointing radar measurements, e.g. BA-CVPs of operational weather radars along the flightpaths of airborne or satellite radar measurements.

Speaker: Christian Heske (Institut für Physik der Atmosphäre, Deutsches Zentrum für Luft- und Raumfahrt (DLR e.V.) Oberpfaffenhofen, Germany)

20250305_Bonn_PrePEP_Heske.pptx

10:45 → 11:00 What can radars tell us about snowfall microphysics? Insights from a MCMC framework

Multi-frequency and Doppler spectral radars are valuable tools to retrieve information on the microphysics of precipitation, and snowfall in particular. However, estimating ice phase microphysics from radar measurements is an ill-posed problem, meaning that different sets of microphysical properties may correspond to the same radar observations. For most retrieval approaches, the uncertainty related to this ill-posedness is difficult to quantify; furthermore, they typically rely on assumptions regarding microphysics or scattering properties, whose impact on the retrieval is usually unknown. In this work, we use simulated radar measurements and the Markov chain Monte Carlo (MCMC) framework to retrieve microphysical information from triple-frequency radar Doppler spectra, with minimal assumptions on the mathematical and physical properties of the system. While this approach is not designed for operational implementation because of its computational cost, it allows to gain insights into the sources of uncertainty and ill-posedness of this radar retrieval problem. We analyze the posterior distributions retrieved from 10 representative examples of simulated measurements. Our results show that certain microphysical variables like the effective diameter may be relatively well constrained, while others are far more uncertain, such as the shape parameter when a gamma particle size distribution (PSD) is assumed. The analysis also reveals relevant correlations in the multivariate posterior distribution, showing how microphysical descriptors are entangled in the retrieval. We then use this Bayesian framework to analyze the sensitivity of the retrieval to assumptions regarding atmospheric effects, radar vertical alignment, microphysical properties such as the mass-size relation or PSD shape, or scattering approximations. We also investigate the special case of bimodal Doppler spectra, where information regarding two hydrometeor populations is merged, and discuss to which extent this information may be recovered. With this work, we improve our understanding regarding the information content of radar Doppler spectra and the intrinsic limitations of microphysical retrievals.

Speaker: Alexis Berne (Environmental remote sensing laboratory, EPFL)

PrePEP_ABerne_v2.pptx

11:00 → 11:30 Coffee Break

11:30 → 11:45 A probabilistic AI-based merging of Commercial Microwave Link and Radar QPE

Commercial Microwave Links (CMLs) provide path-integrated attenuation estimates close to the ground which are closely related to the path-averaged rainfall intensity. Therefore, the combination of CMLs with area-wide weather radar observations, each with its strengths and weaknesses, enables us to further improve the accuracy of rainfall maps. Weather radars measure at increasing heights with increasing distance from the radar. Thus, quantitative precipitation estimation (QPE) may show biases due to for example advection, strong up- and downdrafts, size sorting or melting processes. At the same time, CMLs require extensive quality control to deliver robust QPE. QPE from both sources have benefitted from the application of AI based methods in the past.

In this study, we extend ResRadNet [1], a deep learning framework to predict rain gauge estimates on the ground based on radar-derived QPE and the measurement height, by using CML-based QPE as additional model input. Training the model using rain gauges as an accurate point-scale measurement, it is enabled to subsequently provide improved surface estimates without further gauge-adjustments. Additionally, we develop a new Continuous Ranked Probability Score (CRPS) based objective function to enable skillful ensemble predictions and estimate the uncertainty of the ground-adjustment. Using the RADOLAN-RY precipitation product, derived from the C-band radar network of the German Weather Service (DWD), and a large CML network with 3900 link paths, our results demonstrate that the use of CMLs significantly reduces the biases of ResRadNet QPE. We further present the impact of the new objective function on the prediction of extremes and how to calibrate the ensemble variance. Combined rainfall maps are presented and discussed for recent flooding events in Germany.

[1] Polz, J., Glawion, L., Gebisso, H., Altenstrasser, L., Graf, M., Kunstmann, H., Vogl, S., & Chwala, C. (2024). Temporal Super-Resolution, Ground Adjustment, and Advection Correction of Radar Rainfall Using 3-D-Convolutional Neural Networks. IEEE Transactions on Geoscience and Remote Sensing, 62, 1–10. IEEE Transactions on Geoscience and Remote Sensing. https://doi.org/10.1109/TGRS.2024.3371577

Speaker: Julius Polz (KIT/IMK-IFU&IMK-ASF)

polz_prepep2025

PrePEP_polz.pdf

PrePEP_polz.pptx

11:45 → 12:00 Hydrometeor classification based on cloud radar Doppler spectrum peaks using the PEAKO-peakTree toolkit

Microphysical processes in clouds like ice formation, riming, and ice multiplication can be investigated through cloud radar Doppler spectra: When hydrometeor types within a cloud radar observation volume have sufficiently different terminal fall velocities, they generate individual Doppler spectrum peaks. By separating these peaks, valuable information on the fall velocity, size, number, and potentially the shape of hydrometeors can be extracted. This separation depends both on radar settings and atmospheric dynamics (Vogl and Radenz et al., 2024).
Here, we are using two algorithms, PEAKO and peakTree, for analyzing Doppler spectrum peaks. PEAKO is a supervised machine learning tool, trained to optimize peak detection for specific radar settings, while peakTree organizes and interprets these peaks using parameters learned from PEAKO.
Based on the moments of each extracted sub-peak, hydrometeor types can be assigned to peaks that have properties typical of liquid cloud droplets, columnar ice and rimed ice. This novel cloud radar Doppler spectrum peak-based hydrometeor classification mask can be used for detailed case studies, e.g. for tracking hydrometeor populations through the cloud along Doppler spectrum peak-based fall-streaks. Furthermore, statistics on the occurrence of different hydrometeor types at different sites and temperature ranges can be derived.

Speaker: Teresa Vogl (Leipzig University)

PrePEP_presentation.pptx

12:00 → 12:15 Investigating the Origin of W-Band Radar KDP Signatures Inside and Below the Dendritic Growth Layer

In snow, the specific differential phase (KDP) measured by dual-polarimetric cloud radars is often considered an indicator of high concentrations of small, nonspherical particles. However, KDP also depends on other hydrometeor characteristics such as density, orientation, phase, and size. Determining the contributions of various hydrometeors to observed KDP values is challenging and typically addressed through modeling approaches.
During the winter of 2022-2023, we deployed an innovative simultaneous-transmission-simultaneous-reception (STSR) Doppler W-band cloud radar (LIMRAD94) operated at 40deg elevation angle alongside a novel video in situ snowfall sensor (VISSS) in the Colorado Rocky Mountains. These observations supplemented the extensive measurements of the Atmospheric Radiation Measurement (ARM) Surface Atmosphere Integrated Field Laboratory (SAIL) campaign, which also featured Ka-band and X-band radars. The VISSS provided valuable particle data, including size, number, shape, and complexity.
Our analysis of high-KDP fall streaks, combined with in situ data from the VISSS, revealed that similar KDP magnitudes were produced by particle populations with significantly different number concentrations and mean mass-weighted particle diameters. By analyzing additional radar variables such as spectral differential reflectivity, reflectivity, spectral width, and correlation coefficient, we aim to understand when and how small and large particles contribute to the observed KDP magnitude. Moreover, we explore the influence of external factors, such as turbulence layers and synoptic fronts on polarimetric radar measurements.

Speaker: Anton Kötsche (Leipzig University)

Investigating_KDP_Signatures_Anton_Koetsche_PrePEP_MX.pptx

12:15 → 12:30 Processing of Doppler spectra collected by an airborne cloud radar

Radar Doppler spectra from vertically-pointing cloud radars have been successfully used to derive physical and microphysical properties of clouds and precipitation, such as air motion, particle fall speed, or cloud-drop and drizzle parameters. The majority of past studies utilized spectral observations of stratiform clouds from ground-based radar systems. Doppler spectra from airborne radars are rarely used because they pose special challenges: Because of the finite beam width of radars, the horizontal wind component, which is dominated by the high speed of an aircraft, causes a broadening of the airborne spectra, even when the radar is pointing exactly vertically.
Using observations from the airborne HIAPER Cloud Radar (HCR), we developed a robust technique to correct Doppler spectra for broadening caused by aircraft motion. From the corrected spectra, we calculate high-quality higher-order moments, such as skewness and kurtosis, and other spectral parameters. The development of this processing method is the first step towards our goal of providing higher-order moments, and other spectral parameters, for all HCR observations on a routine basis. HCR has been deployed in five major field campaigns, reaching from the Southern Ocean to the Central American tropics, sampling a vast variety of cloud types. By making spectral radar products derived from clouds sampled in different climatic regions easily accessible, we aim to increase their use by the scientific community. Better utilization of spectral products in cloud research will improve our understanding of their microphysical and kinematic implications, and enhance their use in retrieval algorithms.

Speaker: Ulrike Romatschke

romatschkeEtAl_PrePEP2025_DopplerSpectra.pdf

12:30 → 12:45 Quantifying Riming by Combining the Video In Situ Snowfall Sensor with Cloud Radar Observations

We do not know the exact pathways through which ice, liquid, cloud dynamics, and aerosols are interacting in clouds while forming snowfall. Riming, the freezing of droplets onto ice crystals, is likely one of the most important snowfall formation mechanisms. This is not only because riming is an efficient particle mass growth mechanism, but also because riming is related to secondary ice processes that increase the number of ice particles. Further, riming changes the density of ice particles impacting the particle scattering properties so that implicit or explicit assumptions about riming are required when using passive or active microwave observations of snowfall. Quantifying the riming process is challenging because it requires separating riming from other particle growth mechanisms and snowfall is generally difficult to observe. Various methods based on in situ and cloud radar observations have been proposed, but uncertainties are generally high. Here, we present a method to estimate riming by combining Video In Situ Snowfall Sensor (VISSS) and W-band cloud radar observations. The VISSS was developed to determine particle shape, size, and velocity distributions. Different from other sensors, the VISSS minimizes uncertainties by using two-dimensional high-resolution images, a large measurement volume, and a design limiting the impact of wind. We will apply the retrieval to various datasets to explore the relation between riming and liquid water path and turbulence.

Speaker: Maximilian Maahn (Leipzig University)

mmaahn_202503_prepep.pptx

12:45 → 14:00 Lunch Break

14:00 → 14:15 Impact of seeder-feeder cloud interaction on precipitation formation over the Swiss plateau: a case study and statistics based on extensive remote-sensing, in situ and model data

The PolarCAP (Polarimetric Radar Signatures of Ice Formation Pathways from Controlled Aerosol Perturbations) project makes use of a large set of remote-sensing and in-situ measurement devices in an ideal natural laboratory in the center of Switzerland. Targeted scenarios are so-called Bise weather situations, when northeasterly winds advect moist near-surface air masses over the Swiss Plateau such that there is a frequent chance to observe slightly supercooled low-level stratus clouds in an environment with very low INP concentrations. PolarCAP is implemented in close collaboration with the external ERC research project CLOUDLAB of ETH Zurich. CLOUDLAB makes use of these ideal natural requirements and conducts controlled seeding experiments.

Within the PolarCAP project, the remote sensing equipment of LACROS (Leipzig Aerosol and Cloud Remote Observations System) was installed in Eriswil, Switzerland during two winter campaigns between 2022 and 2024. Techniques for Doppler peak separation, and multi-wavelength analysis, and retrievals of ice-crystal size distributions and particle habits, all based on scanning polarimetric cloud radar observations, were combined with fall-streak tracking and liquid-water retrievals to obtain a comprehensive picture of the cloud evolution. Evaluation data was obtained with ground-based in-situ VISSS (Video In Situ Snowfall Sensor) and 2DVD (two-dimensional video disdrometer). These were used to challenge the remote-sensing-based retrievals.

This presentation focuses on a seeder-feeder case study on 8 Jan 2024, when a moist warm-frontal cloud system, which was advected from southerly direction, interacted with the prevailing low-level Bise cloud deck. The PolarCAP/CLOUDLAB setup was ideal to apply several advanced remote-sensing techniques and retrieval algorithms, including fall streak tracking, Doppler peak separation, and dual-wavelength applications. Results indicated that a large portion of the ice mass was rimed, attributed to the persistent coexistence of falling ice seeds within low-level supercooled liquid water layers. Only the interaction of the seeder and feeder clouds resulted in a significant precipitation enhancement. A comparison with ICON NWP simulations revealed that seeding efficiency was underestimated in the model, whereas the model setup overestimated precipitation production in the Bise cloud. In addition to the detailed case study, we present a statistics and relevance of all seeder-feeder scenarios which were observed during the PolarCAP/CLOUDLAB winter experiments in 2022/2023 and 2023/2024.

Speaker: Kevin Ohneiser (TROPOS)

PrePEP_Ohneiser_final.pptx

14:15 → 14:30 The role of rain evaporation for the energy and radiation budget of the trades

This study investigates the role of rain evaporation in shaping cloud cover and influencing the energy and radiation budget in the trade cumulus region. Although research has advanced our understanding of shallow trade cumulus clouds, the influence of mesoscale cloud organization on cloud feedbacks and the hydrological cycle remains uncertain. Rain re-evaporation can drive mesoscale structures, generating downdrafts and cold pools that form cloud-free areas encircled by cloud arcs. Yet, the relationships between cold pool characteristics, initial rain evaporation, and their effects on cloud cover and the radiative budget are not well understood, largely due to limitations in observational data and model fidelity.

To address this gap, we will develop a long-term dataset of rain evaporation rates using measurements from the Barbados Cloud Observatory. By examining vertical differences in drop size distributions, we aim to characterize the vertical structure of rain evaporation and cooling rates. This work leverages a dual-frequency method with Ka-W band Doppler spectra, chosen for its capacity to address challenges related to attenuation, calibration, and turbulence. We will consider this dual-frequency retrieval as a "ground truth," using it to evaluate the reliability of other retrieval methods, including a single-frequency approach combined with a vertical velocity retrieval and an observationally-constrained one-dimensional rain shaft model. Observations from the ORCESTRA (Organized Convection and EarthCare Studies over the Tropical Atlantic) campaign and its SCORE (Sub-Cloud Observations of Rain Evaporation) sub-campaign will serve as intensive testing phases.

Ultimately, this dataset will enable quantification of the magnitude and vertical structure of rain evaporation, explore their dependence on ambient humidity and rain intensity, and assess the impact of evaporation profiles on boundary layer stability, cold pool dynamics, and cloudiness.

Speaker: Nina Robbins-Blanch (Universität Hamburg)

prePEP2025-NinaRobbins.pptx

14:30 → 14:45 Exploring Total Column Water Vapor retrievals from Satellite-Based Near-Infrared Measurements in Pre-Convective Environments

Satellite-based near-infrared (NIR) measurements within the water vapor absorption band at around 0.9 microns and adjacent window bands are used to retrieve total column water vapor (TCWV) in clear-sky, daytime conditions. The sensitivity of the ratio of these measurements increases towards the surface, allowing detailed observation of atmospheric moisture variability down to the boundary layer. Low-level moisture plays a crucial role in the formation of deep convection and accompanying severe weather like heavy precipitation. Monitoring local to regional changes in (boundary layer) moisture, e.g. increase of moisture in convergence zones, can serve as an early indicator of convective development before the onset of clouds and precipitation.
The predictive potential of these TCWV fields has been demonstrated for a set of cases using spatially high-resolution TCWV retrievals obtained from morning-time measurements from the Ocean and Land Colour Instrument (OLCI) aboard the polar-orbiting Sentinel-3 satellites. OLCI's TCWV fields at 300m resolution capture small-scale convective features within the boundary layer.
The OLCI TCWV retrieval retrieval framework is being adapted for the Flexible Combined Imager (FCI) on the new Meteosat Third Generation (MTG) satellite. FCI is the first geostationary instrument to include this NIR water vapor absorption band, offering an unprecedented opportunity to generate high temporal and spatial resolution TCWV datasets with large spatial coverage, enabling a more comprehensive monitoring and characterization of local to regional TCWV spatial variabilities and temporal changes, particularly in pre-convective environments. Through the assessment of these TCWV fields, their evolution and how they relate to convective development later on, we hope to offer valuable information for nowcasting methods.

Speaker: Cintia Carbajal Henken (FUB)

prepep_conference2025_bonn_carbajal_final.pptx

14:45 → 15:00 A statistical evaluation of cloud microphysics schemes in a numerical weather prediction model with polarimetric radar observations

Accurate representation of microphysical processes in clouds is crucial for reducing uncertainty in precipitation forecasts. Towards improving the prediction of convective precipitation, we developed a systematic framework for statistically evaluating cloud microphysical parameterizations in a numerical weather model using polarimetric radar observations from the German C-band radar network. Polarimetric radar observations are sensitive to cloud particle properties, such as particle shape, phase, or density, and are thus well suited for evaluating cloud microphysics. This study specifically targets high-impact weather events, such as hail and convective rain. Convective weather is particularly difficult to predict and the choice of the microphysical parameterizations significantly impacts the prediction of important characteristics of convective systems. At the same time, high-impact weather events have the potential to cause massive damage to both people and property.

The observational data for this study were collected using two polarimetric research radar systems in the Munich area of southern Germany, operating at C- and Ka-band frequencies, and a complementary polarimetric C-band radar operated by the German Meteorological Service (DWD). To evaluate the performance of cloud microphysics parameterizations in predicting high-impact weather events, a convection-permitting regional weather model setup has been developed, employing five microphysics schemes of varying complexity (double-moment, spectral bin, particle property prediction (P3)). The simulation of polarimetric radar signals consistent with the simulated cloud properties was achieved by applying a polarimetric radar forward operator. Convective cell objects are identified and tracked in both the model and radar data sets using an automated cell tracking algorithm. This facilitates Lagrangian tracking of individual convective cells, which permits the statistical assessment of simulated convective cell properties throughout their life cycles.

The resulting data set of convective cell objects is statistically analyzed in several ways. 1) Macrophysical properties, including the frequency, intensity, and area of high-impact weather situations, are compared. 2) The distribution into stratiform and convective precipitation is examined. 3) The ability of the model to reproduce statistical distributions of polarimetric signals is evaluated. 4) The results are related to the spatio-temporal development of the identified convective objects.

Speaker: Gregor Köcher (Meteorologisches Institut, Ludwig-Maximilians-Universität München, Germany)

20250320_PrePEP_Köcher.pdf

20250320_PrePEP_Köcher.pptx

15:00 → 15:15 Comparing raindrop size distributions from the two-moment microphysics scheme of the ICON-RUC model with disdrometer observations

The Rapid Update Cycle (RUC) has been developed to predict severe storms and especially-heavy rain falls over Germany. In order to forecast the precipitation more precisely, we have implemented a two-moment microphysics scheme, which predicts the number concentration of the hydrometeors in addition to their mass density. In the last two years we have found several cases where the predicted precipitation was too low, although the radar reflectivity showed realistic values. To investigate this behaviour, we started to compare more specific parameters of the model with more detailed precipitation observations.

Several stations in the Deutscher Wetterdienst measuring network include a disdrometer, which measures size and fall speed velocity of individual rain drops every minute. This enables the estimation of the drop size distribution, rain rate and mean diameter with high temporal resolution. Since all these parameters are also estimated by the two-moment microphysics scheme, a direct comparison between model and observations can provide a more specific insight into the problem. 

First, observations of case days from the 2024 summer period with stratiform and convective conditions are evaluated and compared to short-time forecasts in the RUC setup. Specific areas around the disdrometers are used for this evaluation. We try to identify systematic model biases by comparing precipitation amount, the mean diameter and the droplet size distribution in the model and the disdrometers. Our aim is to understand these differences and evaluate possible model changes that can reduce these mismatches and thus improve precipitation forecasting.

Speaker: Sophie Löbel (Deutscher Wetterdienst)

PrePEP_sloebel2.pdf

PrePEP_sloebel2.pptx

15:15 → 15:30 How important is turbulence for the formation of snow aggregation and riming in Arctic clouds?

Turbulence in clouds is known to enhance particle collision rates which has been demonstrated for warm rain formation. It was often discussed and assumed that a similar effect should also exist for ice processes but so far strong observational evidence for this assumption was missing. We will present the results of a statistical analysis of a 15-month W and Ka band cloud radar dataset which allowed us for the first time to quantify the impact of turbulence on snow aggregation and riming in Arctic low-level mixed-phase clouds. We find that increasing Eddy Dissipation Rate (EDR, derived with mean Doppler velocity time series) correlated with larger snow aggregates revealed by dual-wavelength ratios. In temperature regimes more favourable for riming, higher EDR is associated with dramatically higher particle fall velocities (for same liquid water path category) indicative of markedly higher degrees of riming. The polarimetric observations at Ka band also indicate that ice fragmentation processes are also enhanced by turbulence especially in the temperature region where dendritic particles grow.

Speaker: Stefan Kneifel (Ludwig-Maximilians-Universität München)

kneifel_PrePEP_2025.pptx

15:30 → 16:00 Coffee Break

16:00 → 16:15 A detailed climatology of quasi-vertical profiles (QVPs) under stratiform conditions with identification and analysis of different microphysical processes (MPPs)

We present a comprehensive climatology of QVPs of polarimetric variables based on the measurements of the X-band radar located in the city of Bonn in western Germany between 2013 and 2023. QVPs under stratiform conditions are selected, with particular attention paid to the signatures in the melting layer (ML) and the dendritic growth layer (DGL). Due to the unprecedented sample size and the inclusion of all seasons, this comprehensive climatology enables the verification of existing hypotheses with statistical evidence and a better understanding of MPP. Furthermore, this climatology provides a reference for the evaluation of numerical models and parameterization development. Statistical methods, e.g. correlation matrices, are used to analyze polarimetric variables in relation to the ML, DGL and the layer in between, e.g. the ML thickness or the maximum of the radar reflectivity factor (ZH) within the DGL/ML. Hypotheses from former studies are tested, e.g. the seasonality of ML thickness or the ML amplitude, and to reveal dominating MPPs. To analyze the latter more precisely, so called microphysical fingerprints are utilized, in which the gradients of the polarimetric variables are used to identify different MPPs. For this purpose, existing techniques are used, e.g. the aggregation fingerprint, showing increasing ZH with simultaneous decreasing in the specific differential phase (KDP) and the differential reflectivity (ZDR) towards the ML. Additional innovative approaches are presented, such as the inclusion of the mean Doppler velocity from the birdbath scan in order to distinguish between aggregation and riming. In order to ensure the high significance of the climatology, a sufficiently precise calibration of the radar is guaranteed. ZH is calibrated using the relationship between ZH and ZDR in light rain. This method is highly dependent on an accurate calibration of the ZDR. We highlight shortcomings that can occur when using the often preferred birdbath scan technique to correct ZDR and compare the corresponding results with an alternative calibration method that uses QVPs in light rain. The ZH offsets calculated with this technique are validated using both self-consistency relationships applying KDP and satellite information, demonstrating the suitability of this method.

Speaker: Tobias Scharbach (University of Bonn, Institute for Geosciences - Section Meteorology)

PrePEP_PRESENTATION_Tobias_Scharbach.pdf

16:15 → 16:30 Laboratory studies upon the fragmentation of ice particles due to collision

The production of secondary ice in clouds is crucial for cloud microphysical processes but remains poorly understood. Collisions between ice particles are a key process potentially responsible for producing high concentrations of ice crystals. However, limited laboratory studies on ice collisions have constrained our ability to accurately model this phenomenon. In response, we conducted laboratory experiments in a walk-in cold chamber to investigate the fragmentation of ice particles due to collisions.
Our experiments focused on collisions between graupel-graupel and graupel-snowflake particles. We collected and examined all fragments from graupel-graupel collisions under a microscope, while an in-house-developed holographic instrument captured ice fragments from graupel-snowflake collisions. From these data, we derived fragment number and size distributions, alongside their dependence on collision kinetic energy. We observed fragment counts reaching several hundreds, with size distribution peaks at 75 µm for graupel-graupel and 400 µm for graupel-snowflake collisions. Based on experimental data and theoretical frameworks, we propose new coefficients for parameterizing fragment production from ice-ice collisions.
Ultimately, our project aims to integrate laboratory findings, radar observations, and numerical modeling to improve understanding of ice multiplication due to collisions.

Speaker: Miklós Szakáll (Johannes Gutenberg University of Mainz)

Szakall_PrePEP_Fragile.pptx

16:30 → 16:45 The relationship between cloud thermodynamic structure and the properties of precipitation from cloud radar and disdrometer observations

Dominating precipitation formation processes vary in different climate regions. Cloud ice particles, which are involved in most of these processes, are usually formed at the uppermost cloud layer. As underlying formation processes strongly depend on temperatures of the ambient air, cloud top temperatures may indicate the initial formation process of precipitating hydrometeors. Therefore, several temperature regimes can be defined and assigned to dominant formation processes. Warm-rain formation, for example, can be allocated to cloud top temperatures above 0°C. Between 0°C and -25°C, freezing processes with contributing liquid water such as immersion or contact nucleation may occur additionally. Below around -30°C, deposition freezing may happen as well, and below around -40°C, cloud ice can also form homogeneously.

The goal of this study is to connect precipitation events on the ground with the ambient temperature at their area of formation at the cloud top in order to retrieve a statistical overview on the relevance of the abovementioned key ice nucleation processes for the precipitation budget. Exemplarily, a long-term dataset of cloud radar and disdrometer observations of the mobile Cloudnet station LACROS (Leipzig Aerosol and Cloud Remote Observations System) was used for this study. Temperature information were obtained from the ECMWF IFS model, provided via Cloudnet. Each precipitation event detected by the disdrometer is assigned a cloud top height from the radar measurements. For this purpose, the application of a fallstreak algorithm was applied as the cloud top height detected by radar may change between the formation of the hydrometeor and its detection on the ground. The fallstreak propagation is based on the reflectivity values of the single radar bins. The method presented in this study was applied to a multi-year dataset which allows to create statistics of dominating cloud top temperature regimes during precipitation formation over contrasting sites such as Leipzig, Germany, Limassol, Cyprus, and Punta Arenas, Chile.

The results show that precipitating clouds can be categorized into different cloud top temperature regimes which can be associated with different precipitation formation processes. If the method is applied to datasets of stations in different climate zones, potential results may reveal varying dominating formation processes. Therefore, this method may have great potential to contribute to cloud research in a global context, for example, by evaluating cloud models. Moreover, the frequency of precipitation formation events under different aerosol and dynamics conditions can be investigated, if the method is extended.

Speaker: Tom Gaudek

Gaudek_CLOPPER.pptx

16:45 → 17:00 ROTOЯ - Constraining the role of warm rain processes for cloud amount and cloud organization in the trades

Warm rain processes like rain evaporation, downdrafts, and cold pools play an important but poorly understood role in controlling cloud amount and organization in the trade-wind regions. Evaporatively-driven cold pools both enhance cloudiness by triggering arcs of new clouds at the gust front, and reduce cloudiness inside the cloud arcs by suppressing surface-forced convection. Likewise, cold pools were shown to both organize and disorganize shallow convection in high-resolution modelling studies. Unfortunately, we don’t know which of the contrasting effects of cold pools on cloud amount and organization dominates. Here we argue that these knowledge gaps are tightly linked to a lack of robust longterm rain process observations and the fact that we don’t know if state-of-the art models with their crude microphysical parameterizations have skill in simulating the rain processes.

In the ERC starting grant project ROTOЯ (Rain and cloud Organization in the Trades using ObseRvations and models) we aim to overcome these problems by (1) creating a multi-year dataset of rain evaporation, downdrafts and cold pools by applying new remote sensing techniques to observations from the Barbados Cloud Observatory and the EUREC4A and ORCESTRA field campaigns, and (2) by performing & evaluating large-eddy simulations on O(100 km) domains using Lagrangian Superdroplet microphysics. In this talk, we present our strategy and discuss initial results of the role of microphysical complexity in controlling rain evaporation rates in an observationally-constrained 1D rainshaft model.

Speaker: Raphaela Vogel (Uni Hamburg)

PrePEP_Vogel.pptx

17:00 → 17:15 Ground-Based Observations of Secondary Ice Production: A Case Study Showing Droplet Fragmentation during Refreezing Rain

The discrepancy between the concentration of ice nucleating particles and ice in the atmosphere, which can reach up to several orders of magnitude, indicates the importance of secondary ice formation and has led to the suggestion of several secondary ice processes (SIPs). Despite their recognized importance, SIPs remain insufficiently quantified and parameterized in atmospheric models. Some SIPs are entirely theoretical, while others have been demonstrated in laboratory settings. One SIP is droplet fragmentation, where the freezing of liquid droplets leads to the formation of small ice splinters as the droplets shatter. Laboratory studies indicate that this process operates effectively over a broad temperature range, particularly with larger droplets. However, like many secondary ice processes, it is challenging to observe and quantify in natural environments.

Ground-based in situ precipitation measurements provide a viable method for studying these phenomena, offering direct measurements over extended periods with minimal disruption. This approach captures a wide variety of microphysical scenarios and facilitates real-time monitoring of changes in hydrometeor characteristics.

This talk presents a case of refreezing rain recorded in Hyytiälä, Finland, which indicated secondary ice production through droplet fragmentation. An analysis using ground-based in-situ data from the third generation of the Video in Situ Snowfall sensor, combined with the spectral linear depolarization ratio from W-band cloud radar measurements supported this hypothesis. Multiple modes of droplet fragmentation that were identified through in situ imagery, accompanied by a significant increase in ice particle concentration will be shown. Further, we will quantify and characterize the hydrometeors affected by freezing and shattering, as well as SIP particles produced during the event.

Speaker: Nils Pfeifer (Leipzig Institute for Meteorology (LIM), Leipzig University, Leipzig, Germany)

talk_prepep_pfeifer.pdf

talk_prepep_pfeifer.pptx

21:40 → 21:55 DISDRODB: a global data base of raindrop size distribution observations

The drop size distribution (DSD) describes the number and size of raindrops in a volume of air. Knowledge of the DSD is key to model the propagation of microwave signals through the atmosphere (crucial for telecommunication and radar remote sensing), to improve microphysical schemes in numerical weather prediction models, and to understand rain-related land surface processes (rainfall interception, soil erosion).

Despite its importance, the spatial and temporal variability of the DSD remains poorly understood. This has motivated scientists all around the globe to deploy DSD recording instruments known as disdrometers, in order to collect DSD observations in various climatic regions. However, only a small fraction of these data is easily accessible by the research community. Data are stored in disparate formats with poor documentation, making them difficult to share, analyze, compare and re-use. Additionally, very limited software is currently publicly available for DSD processing.

This presentation introduces the DISDRODB project, which addresses these challenges by establishing a decentralized disdrometer remote data archive, a public station metadata repository hosted on GitHub, and an open-source Python software for retrieving raw station data and generating quality-controlled analysis-ready L1 and L2 products.

Disdrometer data from hundreds of public stations from various institutions (including NASA, NCAR, ARM, NCEP, NERC, INPE, EPFL, TU Delft) are used to characterize global DSD variability, derive rainfall scaling laws at short spatio-temporal scales, and simulate radar polarimetric variables across multiple frequency bands.

By consolidating and mobilizing existing data archive, the envisioned publicly-accessible global database of standardized disdrometer measurements and derived products aims to accelerate and advance precipitation research as well as foster international collaborations.

Speaker: Gionata Ghiggi (EPFL)

DISDRODB_Ghiggi_PrePEP_2025.pptx

Friday 21 March

08:45 → 09:15 Keynote 9: Making use of supplementary observations for the development of physical parameterizations

Convener: Linda Schlemmer (Deutscher Wetterdienst)

PrePEP_2025_Schlemmer.pptx

09:15 → 09:30 Linking Ice-Phase Microphysics to Raindrop Characteristics, and Extreme Rainfall in a Deep Convection Event in Eastern China

In this study, we examine the evolution of ice-phase microphysics [polarimetric radar signatures and identified graupel and hail (GH) (hereafter, GH) distributions] and raindrop characteristics [drop size distribution (DSD) and rainfall intensity] in a extreme rainfall produced by convection during the Meiyu period in Eastern China. The results showed in the convection, strong updraft favored the lifting of raindrops to the mixed-phase region to form abundant supercooled liquid water and GH. Meanwhile, raindrop characteristics are found to be deeply affected by the GH distribution condition, heavy rainfall (rain rate > 20 $\mathrm{mm}\,\mathrm{h}^{−1}$) is basically contributed by convective samples with GH identified aloft. As GH height rises, number concentration and mean size of raindrops increase accordingly, leading to the growth of rainfall intensity. Extreme rainfall (rain rate > 100 $\mathrm{mm}\,\mathrm{h}^{−1}$) is majorly induced by deep convection with hail or widespread (over 10 km level) graupel, melting of the abundant highly-rimed particles plays a dominant role in generating high concentration raindrops. By revealing the link between GH distribution conditions and raindrop characteristics, the study helps to understand the specific role of ice-phase processes to the formation of low-level raindrops in deep convection.

Speaker: Kun Zhao (Nanjing University)

PrePEP_ZHAOKUN_PrePEP.pptx

09:30 → 09:45 Study on Microphysics of Stratiform Precipitation Based on Dual-Polarization Radar and Airborne Observations

Understanding the microphysical properties of stratiform precipitation is crucial for advancing weather prediction models and deepening our understanding of atmospheric processes. This study integrates advanced techniques in dual-polarization radar and airborne observations to conduct a comprehensive analysis of stratiform precipitation microphysics.
First, a variational approach to optimize drop size distribution (DSD) retrieval, attenuation correction, and rainfall estimation using polarimetric radar measurements (horizontal reflectivity factor $Z_H$, differential reflectivity $Z_\mathrm{DR}$, and differential phase shift $\Phi_\mathrm{DP}$. Our approach employs radial B-spline filtering and azimuthal Kalman filtering to ensure the spatial continuity of rain and mitigate random errors in $Z_\mathrm{DR}$ and $\Phi_\mathrm{DP}$. Validation includes simulated experiments and real-case observations from mobile C-band and operational S-band polarimetric radars in South China, demonstrating that our method achieves more accurate attenuation correction and rainfall estimates compared to conventional methods.
Furthermore, we investigate microphysical structures and processes in precipitating stratiform clouds using joint observations from an aircraft and the optimized estimates from an X-band polarimetric radar. A case study conducted over North China on May 21, 2018, reveals enhancements in $Z_\mathrm{DR}$ and specific differential phase $K_\mathrm{DP}$ above 7 km altitude, indicating the presence of dendrites and platelike ice crystals. Above the melting layer (ML), aggregation processes increase $Z_H$ and decrease $Z_\mathrm{DR}$, as confirmed by aircraft observations showing an increase in volume-weighted mean diameter ($D_m$) and a decrease in total number concentration ($N_t$). Within the ML, melting particles exhibit complex behaviors, with aggregation dominating the upper part and breakup processes prevailing in the lower part, influencing particle size and concentration. Below the ML, microphysical processes exhibit minimal variation with altitude, indicating a near balance in nearly saturated air.
These findings significantly contribute to our understanding of stratiform precipitation microphysics and provide valuable insights for improving microphysical parameterization in numerical weather prediction models, emphasizing the integration of advanced radar techniques and airborne observations.

Speaker: Hao Huang (Nanjing University)

HaoHuang-PrePEP-snow_microphysics2.pptx

09:45 → 10:00 Can ice-ice fragmentation explain the typical radar signatures in the dendritic growth layer? An investigation combining polarimetric multi-frequency radar observations wth Lagrangian Monte-Carlo particle modeling

The dendritic growth layer (DGL), centered around -15°C, plays a key role in the formation of precipitable ice and snow particles. Particle growth by vapor deposition and subsequent aggregation are strongly enhanced in the DGL. As a result, multiple radar observables display distinct features related to the plate-like particle shapes as well as rapid formation of aggregates. Specifically, enhanced ZDR and KDP are frequently interpreted as the depositional growth of plate-like particles and the increase in DWR as aggregation. However, radars only observe the effect of ice microphysical processes (IMPs) on the observed particle distribution, not the IMPs themselves. Therefore, especially the origin of the plate-like particles which might cause enhanced ZDR and KDP are not fully understood. Common hypotheses include ice crystals which sediment into the DGL from colder temperatures, primary nucleation due to an updraft and local activation of INP and secondary ice production (SIP), possibly ice-ice collisional fragmentation.
In this contribution, we combine zenith triple-frequency (X, Ka, W-band) and slant-viewing W-band spectral polarimetric radar observations with Monte-Carlo Lagrangian particle modeling to shed light on the typical DGL radar signatures. The Monte-Carlo particle model McSnow allows us to describe and investigate IMPs on the detailed particle level. Recently, a habit prediction scheme which simulates the evolution of ice crystal shape and density has been implemented. Ice habit, particle size, density and fall velocity are core information for radar forward simulations, facilitating the comparison with radar observations and allowing to link the radar observations to specific IMPs. New laboratory studies on ice-ice collisional fragmentation allowed us to implement a fragmentation scheme in McSnow. To make full use of the rich information content of the McSnow simulations, a new radar forward operator has been developed. The forward operator is based on DDA calculations of more than 1500 ice crystals with varying habits, as well as 600 aggregates with varying degrees of riming. McSnow simulations suggest that the particles responsible for the increase in ZDR need to be produced within the DGL, either via primary or secondary ice production. The simulations further suggest that the increase in KDP at -15°C might be linked to fragmentation. Surprisingly, our study also suggests that the increase in KDP is not only caused by ice crystals, aggregates also have a significant contribution to KDP.

Speaker: Leonie von Terzi (Ludwig-Maximillians Universität München)

PrePEP_Leonie_von_Terzi.pdf

PrePEP_Leonie_von_Terzi.pptx

10:00 → 10:15 From Cloud Tops to Surface: Statistical Insights into Stratiform Microphysics over Germany and Türkiye

This study presents a statistical analysis of stratiform precipitation events across Germany and Türkiye using quasi-vertical profiles (QVPs) derived from three C-band radars in Germany and five C-band radars in Türkiye, covering the time period from 2015 to 2020. The dataset allows for an in-depth examination of microphysical processes at all height levels from the dendritic growth layer, where precipitation is generated, to the melting layer and down to the surface. Comparative analysis highlights notable regional differences in precipitation profiles and microphysics, linked to the distinct climates of Germany and Türkiye. For instance, QVPs from Türkiye show higher values of specific differential phase KDP in the dendritic growth layer with deeper and colder cloud tops compared to Germany, linked to greater ice water content in Turkish clouds. Additionally, two radars in Türkiye exhibit decreasing reflectivity ZH from the melting layer to the surface while maintaining stable differential reflectivity ZDR, indicating evaporation effects, consistent with a drier climate region. A riming detection algorithm further reveals enhanced riming frequency in Germany compared to Türkiye, with the exception of a Turkish coastal radar at low altitude. The latter shows dominant riming processes in up to 30% of the events, similar to German observations. Interestingly, we observe a correlation between increased riming frequency and lower cloud-top heights, while no relationship is found between riming frequency and melting layer thickness. This analysis provides new insights into the varying dominant microphysical processes in stratiform precipitation and different climate regimes and enables in the next step an in-depth evaluation of numerical weather prediction models.

Speaker: Julian Alberto Giles (Institute of Geosciences, Meteorology Section, University of Bonn, Germany)

79-GILES from cloud tops to surface.pdf

79-GILES from cloud tops to surface.pptx

10:15 → 10:30 Detailed spectral-bin microphysics simulations of primary ice formation in artificially seeded supercooled stratus clouds

The PolarCAP project aims to better understand the interplay between aerosol and cloud-microphysical processes by investigating the evolution of the ice phase under slightly supercooled conditions (T > −10 °C) within a thermodynamically and aerosol-controlled environment, employing radar polarimetry, holographic imagery and spectral-bin modelling. In collaboration with the CLOUDLAB project at the ETH Zurich, PolarCAP investigates the development of an artificially initiated ice phase
within supercooled stratus clouds. Utilising cloud seeding with silver iodide, CLOUDLAB initiates the freezing process of cloud droplets. The subsequent evolution is monitored using in-situ measurements and ground-based cloud remote sensing tools. The collaboration has yielded a unique dataset, incorporating observations from the Leipzig Aerosol and Cloud Remote Observations System (LACROS) and observations from CLOUDLAB in tandem with data from the cloud-resolving spectral-bin microphysics model COSMO-SPECS.

We present a comparative evaluation between observational data and simulations of the spectral-bin model COSMO-SPECS (CS) featuring an artificial particle source. A multitude of ensemble CS model runs were performed on two different mesh sizes, with horizontal resolution of ∼400 m and ∼100 m in various configurations. First, we demonstrate the CS model’s ability to reproduce observed cloud responses, providing insights into ice nucleation and growth processes, in particular the Wegener-Bergeron-Findeisen (WBF) process. During the seeding experiments, observations show simultaneous decreases in cloud droplet concentrations alongside increases in ice crystal concentrations, including periods where cloud droplets were entirely depleted. Our findings suggest that significant amounts of flare INP are required to replicate observed ice crystal concentrations and cloud droplet reductions. This could indicate that the model scheme may be unsuited for deriving immersion INP concentrations from flare particle emissions. Second, the measured ice crystal sizes and growth rates, are compared to the CS output. This comparison revealed discrepancies in ice crystal size distributions, highlighting potential model biases due to parametrizations of ice crystal growth. Furthermore, the comparison revealed insights into the importance of spatial resolution of the CS model.

Speaker: Willi Schimmel (Leibniz Institute for Tropospheric Research (TROPOS), Leipzig, Germany)

2025-prePEP-PolarCAP-WSchimmel.pptx

10:30 → 10:45 Investigation of aerosol effects on precipitation initiation processes in the alternately clean and aerosol-laden environment of New Zealand Aotearoa

Down to temperatures of -38°C the primary formation of liquid or frozen hydrometeor requires the availability of aerosol particles, which act either as cloud condensation nuclei (CCN) or ice nucleating particles (INP). An actual quantification of the influence which perturbations in the aerosol load do have on a clouds’ microphysical structure and its evolution toward precipitation is nevertheless still hardly achievable. Strong need is given to improve this lack of scientific understanding, because state-of-the-art physical representations of cloud processes show a lack of accuracy especially in regions where the aerosol load deviates from the general mean.

It is scope of the project ACADIA (Aerosol-Cloud-rADiation-interaction over Aotearoa) to conduct a unique contrast study which is about to disentangle the relationships between aerosol load, cloud and precipitation processes, and the radiation budget, based on a 1-year multi-site field campaign on the South Island of New Zealand Aotearoa. ACADIA, which is a joint project of Leibniz Institute for Tropospheric Research (TROPOS) and the Leipzig Institute for Meteorology (LIM) of the University of Leipzig, will exploit the alternation of Australian and clean Southern-Ocean dominated air masses and the transformation processes during transport over 400 km of landmass of the South Island of New Zealand to disentangle the role of aerosol load on the microphysical and radiative properties of clouds and their evolution. TROPOS and LIM will place extensive ground-based remote sensing equipment to the sites of Invercargill and Tawhaki, respectively. The key instrumentation consists of multi-wavelength cloud Doppler polarization radar and lidar systems with polarization, fluorescence and Doppler capabilities. ACADIA is scheduled to take place from August 2025 to August 2026 and will be embedded in a series of already scheduled field experiments, which are implemented under the umbrella of the goSouth-2 consortium. Those include deployments of the HALO aircraft, the research vessel Sonne, and the mobile ground-based remote sensing infrastructure LACROS of TROPOS. Contextualization with spaceborne profiling lidar and radar observations from the EarthCARE satellite and aerosol-permitting model simulations will take place, in addition.

The presentation will focus on three subjects. We will provide an overview on recent findings about the role of aerosol perturbations on precipitation initiation processes. We will motivate the location of New Zealand for aerosol perturbation studies. Finally, the ACADIA project and the partner projects which are scheduled to take place within the goSouth-2 consortium will be introduced and the possibilities for additional collaborations will be elaborated.

Speaker: Patric Seifert (Leibniz Institute for Tropospheric Research (TROPOS))

20250321-Seifert-ACADIA-PrePEP.pdf

20250321-Seifert-ACADIA-PrePEP.pptx

10:45 → 11:00 Preparing the two-moment microphysical scheme for operational forecasts using radar and satellites

The Deutscher Wetterdienst has recently introduced a new Rapid Udpate Cycle (RUC) for a seamless transition between Nowcasting (a pure radar product) and Numerical Weather Prediction (NWP). The two-moments scheme (Seifert and Beheng 2006) produces significantly more realistic reflectivities than the currently operational one-moment scheme, thus allowing for a smooth transition between Nowcasting and NWP. The challenge in the last years has been to prepare the two-moments scheme, which has been previously mostly used for research, to be employed for operational weather forecasts.

The two-moment scheme includes evolution equations for the number concentration of the different hydrometeors. This means that the mean size of each hydrometeor in the model is known, which allows for more-physical assumptions in the parameterized processes. The challenge is that many of the involved parameters, such as sticking efficiencies, ice nuclei concentrations or sedimentation velocities, are to a large degree unknown. It is not only that there have been insufficient laboratory experiments related to these processes (quite frequent), but also that the model assumptions are too simple to capture a more-complex reality. This means that many of the microphysical parameters need to be tuned.

Knowing the size of each hydrometeor in the model also provides a key advantage when considering forward operators, especially radar and satellites. For example, few very large graupel particles produce a much larger radar reflectivity than a lot of small ones, even when the summed mass is the same in both cases. This means that the simulated radar and satellite signals are sensitive to the assumptions that are made in the microphysical scheme. Given that we have fully coverage of radar and geostationary satellites in Germany, we are in an ideal situation to examine many of the physical assumptions and parameters in the model.

In this presentation we will show how we have used radar and satellite information to prepare the RUC microphysics for operational forecasts. Our objective has been not only to improve the forecast scores, but also to get “more-physical” clouds, as seen by those remote systems. We have focused on radar reflectivities and on three different radiation channels from the Meteosat-SEVIRI instrument. Those channels provide information about cloud thickness, cloud height and particle size. We will show how the information from the radar and the different channels provides a complementary view, as often variation in microphysical assumptions can be directly detected by only one observation system.

Speaker: Alberto de Lozar (Deutscher Wetterdienst)

20250321_PrePEP_adelozar.pptx

11:00 → 11:30 Coffee Break

11:30 → 11:45 Exploiting polarimetric radar observations to improve the ICON-D2 2-moment microphyiscs

Polarimetric radar operators such as EMVORADO (Efficient Modular VOlume scan RADar Operator) enable the direct comparison of numerical weather simulations with radar observations in the polarimetric observation space. Additionally, microphysical retrievals are the appropriate way to conduct a synergistic comparison in model space. Our objective is an in-depth evalutation of the 3-dimensional representation of hydrometeors in ICON-D2 employing both strategies.

ICON-D2 with the two-moment microphysical scheme from Seifert-Beheng shows, similar to other numerical weather models, a tendency towards excessive riming and an overproduction of graupel. As a consequence, also oversized drops are simulated below the melting layer. In order to converge ICON simulations and according synthetic radar variables simulated with the EMVORADO to the actual radar observations, model evaluation and model parameter adjustment has been applied in an iterative procedure. This implies several experiments with adjusted microphysical parameters of ICON (e.g. sticking efficiencies, riming efficiencies, terminal velocities, shedding parameters) together with improvements in the melting scheme of EMVORADO. Among the challenges is the development of one universal melting scheme for both large-scale stratiform precipitation and convective thunderstorms. This study investigates the representation of hydrometeors in ICON-D2 and the performance of EMVORADO in different weather situations, in different seasons and for the whole German C-band radar network.

Until now, significant improvements have been achieved, e.g. reduced graupel production and mean droplet sizes that are more consistent with the radar measurements. In convective situations, we are able to identify synthetic/simulated columns of enhanced differential reflectivity, ZDR columns, although with smaller ZDR values compared to observations. First results show too much graupel above the melting layer dominating the ZDR signal but only small raindrops are transported upwards. The opposite is true for the areas below the cores of convective storms, where the formation of too large raindrops is apparent.

Speaker: Julian Steinheuer (Institute of Geosciences, Meteorology Section, University of Bonn, Germany)

250321_presentation_Steinheuer_prePEP.pdf

11:45 → 12:00 Predicting Realistic Snow Shape for Improved Polarimetric Radar Simulations

Radar Forward Operators (RFOs) bridge the gap between the physical properties of clouds and precipitation and the observed radar quantities. A significant source of uncertainty in RFOs arises from assumptions about the scattering properties of frozen and mixed-phase hydrometeors. Polarimetric RFOs often use simplified, homogeneous shape models. These cannot reflect the multifaceted structure of snow, which, however, significantly affects the polarimetric radar properties. This study explores the use of Discrete Dipole Approximation (DDA) scattering models to incorporate realistic shapes of snow particles to overcome this limitation. However, it is well-known that snow particles appear in a vast variety of habits, and it is not straightforward to assume one shape that fits it all. Conversely, operational weather models do not provide sufficient constraints to model ice particle shapes that unambiguously represent the generic internal ice microphysical assumptions (i.e., mostly just mass-size relation). The present study uses a cascade of progressively more detailed models that explicitly predict the shapes of ice crystals and snow aggregates to be used to model their radar multi-frequency (C, X, Ka, and W-band) polarimetric signature with DDA.

The core of the modeling framework is the shape-predicting, semi-Lagrangian, cloud model McSnow that takes the ICON atmospheric state and simulates the evolution of the microphysical properties of cloud and precipitation particles (mass, size, aspect ratio, rime fraction, melted fraction) as well as the number of monomers composing snow aggregates. By tracking the sequence of aggregation events that originated each aggregate, it is possible to reconstruct the properties of each monomer. This information can be used to simulate realistic aggregate shapes using a physically based aggregation model. This model reproduces the collision process with great detail and provides snowflake shapes that match the properties of the snowflake as they are modeled by McSnow.

Key questions of the present study that enhance the process understanding of cloud microphysics include: (1) To what extent do multi-frequency and polarimetric radar signatures of snow depend on the detailed shapes of the aggregates? (2) Can DDA improve over the T-matrix and provide a reliable representation of the scattering properties of snowflakes for use in RFOs? (3) Can a snow particle model be identified that represents polarimetric radar properties of snow for most weather scenarios, and what uncertainties are inherited in such generalized assumptions?

Speaker: Soumi Dutta (University of Cologne)

PrePEP_ppt_SDutta.pdf

12:00 → 12:15 On the geometry and growth of aggregate snowflakes

It is often said that no two snowflakes are alike. This usually refers to dendritic crystals, which can develop complicated and therefore unique branches. Most snowflakes in the atmosphere are not dendrites, but aggregates of primary crystals such as plates, dendrites or needles (also called monomers). Each aggregate is unique because the size, shape, collision angles, and overlap of the monomers are random. Earlier work has shown that aggregate snowflakes show a fractal scaling behaviour for large monomer numbers (also called cluster size). Nevertheless, there is a large variability of aggregate snowflake geometry. Given a certain snowflake mass and monomer number, the observable variables such as maximum dimension, aspect ratio, and terminal fall velocity can vary greatly. To understand and parameterize snowflake geometry, we have generated several million aggregate snowflakes with an aggregation model. This dataset allows us to parameterize the joint probability distributions of maximum dimension, aspect ratio, and cross-sectional area for aggregate snowflakes.
These probability distributions have been implemented in the Monte-Carlo super-particle model McSnow as a stochastic parameterization of snowflake geometry. This allows us to investigate the effect of snowflake variability on snowflake growth. The collision kernel is affected by the geometry itself and by the variability in terminal fall velocity caused by the different geometries. Hence, by taking into account the variability in snowflake geometry two snowflakes with the same mass can indeed collide, because they end up having different terminal fall velocities. Similar to considering turbulence effects in the collision kernel, this leads to a faster growth of aggregates. McSnow can already predict the habit of primary crystals using a spheroid model. This habit information can now be propagated to the aggregates. With the new stochastic snowflake model, McSnow can distinguish between aggregates of plates, aggregates of needles, and mixture aggregates.
To investigate the impact of the stochastic snowflake model on (polarimetric) radar quantities, we need to consistently forward simulate the model output. For this we have used DDA on representative aggregates from the aggregate database, generating a large scattering database. First results indicate that contrary to previous forward simulations using soft spheroid models such as the T-matrix, aggregates contribute significantly to the specific differential phase shift KDP. Also, the variability of snowflake geometry leads to a broadening of the Doppler spectra. The latter are often too narrow in numerical cloud models with simplified snowflake assumptions.

Speaker: Axel Seifert (Deutscher Wetterdienst)

Seifert_McSnow_PrePEP_March2025.pptx

12:15 → 12:30 A gravity-driven inverse cascade controls the size distribution of raindrops

Cloud droplets grow via vapor condensation and collisional aggregation. Upon reaching approximately ≈100 μm, their inertia allows them to capture smaller droplets during descent, initiating rain. Here, we show that raindrop formation is not primarily governed by gravity or thermal diffusion, but by a critical range of drop sizes (3−30 μm) where collisions are largely ineffective and controlled by van der Waals and electrostatic interactions. We identify several pathways to rain. The coalescence pathway, which is slow, involves the broadening of the drop size distribution across the 3−30 μm low-efficiency gap through collisions, until enough large individual droplets achieving efficient collisions have formed. The turbulence pathway relies on air turbulence to bring the droplets together at an increased rate, but we show that this pathway is unlikely. For all dynamical mechanisms, we demonstrate that the initiation time for rainfall occurs at the crossover between the broadening of the drop size distribution and the emergence of individual droplets large enough to trigger the onset of the rainfall cascade. We propose a reductionist, spatially homogeneous and stationary cloud model, the theoretical treatment of which is based on an analogy with the turbulent energy cascade. We show that this cloud is not just a simple idealisation, but can be used to describe in detail observations of drop size distributions, both in clouds and in rain on the ground, and their links with the various growth mechanisms. This surprising agreement opens up new avenues for the parameterisation of cloud microphysics in atmospheric models.

Speaker: Florian Poydenot (Universität Hamburg)

Poydenot_prepep_bonn_final.pdf

12:30 → 12:45 Simulation of convective precipitation in idealized and realistic supercell cases with the P3 cloud microphysics scheme in ICON

Many uncertainties exist in the parameterization of microphysical processes in bulk schemes. The Predicted Particle Properties (P3) bulk scheme lets ice particles seamlessly evolve in a more natural way without the necessity of conversion between pre-defined ice-phase categories. Therefore microphysical processes like riming, which is the key process in hail production, can be formulated more realistically. In this study the P3 scheme was coupled to the Icosahedral Nonhydrostatic model (ICON) via the new Community Interface ComIn. The recent version 5 of P3 (Cholette et al., J.A.M.E.S, 2023) is able to run with three moments and multiple categories for the ice phase, allowing the simulation of hail without numerically diluting it in areas of new ice nucleation. The correct physics-dynamics coupling behavior was tested comparing P3 with ICON’s traditional 2-moment bulk scheme in an idealized splitting supercells testcase. The different approaches in handling the condensation of both schemes were explored, including their impacts for different cloud condensation nuclei (CCN) concentrations. Further, a realistic case study of isolated supercells on 10 Nov 2018 in Central Argentina from the RELAMPAGO-CACTI campaign was set up with ICON and both schemes at storm-resolving resolutions. A custom CCN parameterization was developed using aerosol measurements of CACTI to constrain this sensitivity pathway. Finally a forward operator is used to compare polarimetric simulated fields to polarimetric radar measurements of RELAMPAGO. Sensitivities to perturbations of microphysical parameters in the P3 scheme will be shown.

Speaker: Marco Wurth (IMKTRO - KIT)

PrePEP2025_marcowurth.pdf

PrePEP2025_marcowurth.pptx

12:45 → 13:00 Closing Ceremony