SuPeRBE Wiki: Difference between revisions

DHMZ activities include:

• Establishing the infrastructure and measurements systems, as well as planning and maintenance of various national meteorological, hydrological and air quality monitoring stations
• Development and maintenance of various databases (meteorological, hydrological, air quality)
• Providing the information on meteorology, hydrology and air quality to users. DHMZ issues warnings and produces analyses, forecasts and studies. This is achieved by applying advanced scientific methods in using sophisticated software including numerical prediction models using supercomputers
• Applied scientific research and development of methods designed to enhance the quality of information and products DHMZ provides to its users
• Operational implementation of hail suppression

DHMZ products/services are used as support in the following areas:

• Protection of lives
• civil protection
• healthcare
• water resource management
• environment and nature protection
• agriculture
• traffic
• public information services
• strategic, regional and urban planning
• architecture, design and construction
• generation, distribution and supply of electricity
• sport and recreation.

The purpose of the portal is to monitor and forecast the weather and inform the public about current meteorological conditions and climatological data. Šibenik meteo portal is responsible for installation and networking of automatic meteorological stations in the area of Šibenik and northern Dalmatia, as well as creating a network of weather watchers on a volunteer basis, and taking care of their work.

The portal includes three future climate scenarios (RCP 2.6, RCP 4.5, and RCP 8.5), based on different levels of greenhouse gas emissions for the period 2011-2100. These scenarios help visualize how varying levels of emissions might affect different regions and sectors in Germany

• Flood Notification Service
• Low Water Information Service
• Avalanche Warning Service
• naturgefahren.bayern.de (Natural Hazards Bavaria)
• Alpine Natural Hazards
• Earthquake Service Bavaria
• Georisks Information Service Bavaria
• Severe Weather Warnings from the German Weather Service (DWD)
• Air Pollutants
• Ozone Levels

Users can set up to three locations (e.g., home, workplace, vacation spot) and select specific hazard warnings or environmental information for each. Once the locations and hazard preferences are set, users will receive a notification on their smartphone in case of severe or extreme weather or natural hazards. A warning will also appear on the app’s homepage, where real-time environmental information is displayed based on the user’s preferences.

The free version of the WarnWetter app offers the following features:

• Current warning situation in Germany, down to the municipal level
• Detailed information on the warning situation
• Configurable warning elements and warning levels
• Configurable alert function (push notifications)
• Warnings about natural hazards (floods, storm surges, avalanches)
• Predicted storm cell tracks
• Coastal and inland sea warnings (for Bavarian lakes and Lake Constance)
• Video updates during significant weather events

• Earthquakes
• Floods
• Landslides
• Avalanches
• Volcanic eruptions
• Tsunamis
• Fires

• Rainfall
• Visibility
• Temperature
• Winds
• Seas

Home page

• Personalized home page with the ability to enter up to four favorite locations
• Geolocated forecasts based on the location of the device
• Hourly forecasts of the most important weather parameters - sky state, precipitation, humidity, pressure and wind

Satellite

• Different types of satellite imagery and post-processing of high-definition satellite data
• Combining satellite data with the Air Force lightning detection network

Intense phenomena

• Indication of the availability of reports of intense phenomena
• Ability to enable notifications for reports of intense phenomena

Map

• Forecast map for Italy with animations on the evolution of different atmospheric parameters in time and space (precipitation, wind, cloud cover, etc.)
• Point-of-concept forecasts throughout the country

• Weather radar with the evolution of the last hour rainfall
• Map of Piedmont of dangers in real time
• Map of Piedmont of the alert in the foreground and with a slightly lower color the alert of northern Italy.

From the Piedmont real-time hazard map, citizens can select a municipality and go to the nearest detection stations to the selected municipality. Hydrological stations have an order of priority over rain stations.

It is suitable for use on all sizes and types of boats. Navtex is one of the main elements of the Global Maritime Safety System (GMDSS) developed by the International Maritime Organization (IMO) and included in the 1988 amendments to the International Convention for the Safety of Life at Sea (SOLAS) from 1974. The messages are broadcasted in English, on the operating frequency 518 kHz, through the maritime radio service operated by Plovput on behalf of Croatia. The Maritime Meteorological Center of DHMZ prepares the meteorological part of messages, warnings, reports and forecasts.

Energy renovation projects include elementary schools and cultural institutions. The implementation of the projects results in savings in primary energy consumption as well as greenhouse gas emissions.

For the unpaved areas, the project emphasizes soil protection and the prevention of soil compaction. This includes clearly marked lawned areas that are off-limits to foot traffic (protected by a low fence), as well as designated recreational areas and dog meadows.

Heatwaves

Air polution

Droughts

Green infrastructure

Wellbeing

The value of the project is €326,980.32, and the Fund's co-financing is 40%. The project's main objective is to increase the capacity for the production of solar energy and the production and use of energy from renewable sources.

Waste management

In addition to the production of the biostabilized fraction, recyclable materials (metals, glass, paper, plastic) and solid fuel are separated from the waste. This fulfills the main criteria of municipal waste disposal as prescribed by the Law on Sustainable Waste Management in Croatia:

• reduction of the total amount of waste disposed of landfills
• reduction of harmful components of disposed waste and especially the content of biodegradable components in it
• utilization of useful components of waste, including its energy value.

It identifies a series of short and long-term adaptation measures by defining a series of actions (overall about 80) aimed at reducing the impacts caused mainly by heat waves and floods, which represent the main risks associated with climate change to which the city is exposed to. The Resilience Plan also contains indicators for monitoring each of the proposed actions.

The Annex 6 of the document describes many “Solutions to contrast climate vulnerabilities” ANNEX

• Exposure: Identifying spatial variations in natural hazard impacts, such as urban heat islands for heatwaves and topographical depressions for heavy rainfall.
• Susceptibility: Analysing factors like age, health, and socio-economic conditions.
• Coping Capacity: Evaluating resources and strategies available to mitigate negative impacts.

The method is limited to measure vulnerability of the Population and the Critical Infrastructure.

• Preparation (goal setting, data collection, and defining scope),
• Execution (screening, data gathering, and impact evaluation), and
• Communication (result interpretation and adaptation planning).

The method involves:

• Screening for potential climate impacts, using a broad evaluation of various risks (e.g., heat, floods, droughts) to identify priority areas for deeper analysis.
• Developing impact chains, where cause-and-effect relationships between climate hazards and their impacts on specific systems (e.g., how heat stress affects vulnerable populations) are visualized.
• Quantitative and qualitative data gathering, including local expert interviews and climate models, to analyze both current and future vulnerabilities.
• Scenario-based assessments to model different climate futures (e.g., optimistic or pessimistic scenarios based on IPCC’s RCP pathways).
• This integrated approach helps municipalities to prioritize risks and allocate resources effectively, leading to actionable climate adaptation plans.

The method encourages a participatory approach, involving local stakeholders, and provides practical recommendations for municipalities to plan and implement climate adaptation strategies

• Storm (hazard and monetary risk in the present and future)
• Hail (hazard and monetary risk in the present and future)
• Heat (hazard and qualitative risk in the present and future)
• Heavy rainfall (hazard and qualitative risk in the present and future)
• Earthquake (hazard)
• Lightning strike (hazard)
• Snow load (hazard)
• Forest fire (hazard in the present and future)

Key Features:

• Climate and Natural Hazard Assessment: Users input building-specific data (e.g., location, construction year, number of floors, roof type, building materials, and energy system) to evaluate risk levels for a variety of climate hazards.
• Quantitative Risk for Hail: The tool calculates annual expected monetary losses from hail damage using a risk model that factors in location, building vulnerability, and building value.
• Qualitative Risk for Other Hazards: Climate risks such as heat, wind, and heavy precipitation are assessed qualitatively by plotting hazard probabilities against the building’s resilience.
• Natural Hazard Probability: For hazards like earthquakes, floods, and snow loads, the tool provides probability estimates for the given location.
• Timeframe Flexibility: The tool allows users to select either current or future weather projections (up to 2100) for risk assessment, based on data from the German Weather Service (DWD) for current conditions and from the Karlsruhe Institute of Technology (KIT) for future climate projections.

• Wind (e.g., storms, tornadoes),
• Water (e.g., floods, heavy rainfall),
• Fire (e.g., wildfires), and
• Geo-seismic risks (e.g., earthquakes)

Key Features:

• Resilience Rating System: The BRI evaluates building resilience using a 5-point scale ranging from A+ to R, with higher ratings signifying lower probable maximum loss (PML). This rating system is based on the "Weakest Link Principle," meaning that a building’s overall rating is determined by its lowest score across four key hazard categories: Wind (e.g., storms, tornadoes), Water (e.g., floods, heavy rainfall), Fire (e.g., wildfires), and geo-seismic risks (e.g., earthquakes).
• Hazard Categorization: The BRI groups risks into two families:

1. Physical Integrity Risks: Hazards that threaten the building’s structural integrity, such as storms, floods, fires, and earthquakes.
2. Operational Continuity Risks: Hazards that affect the building’s operations but not its physical structure, such as heatwaves, cold waves, and droughts.

• Resilience Definition: The BRI defines a resilient building as one that can withstand natural hazards specific to its location and ideally continue operations without disruption after a hazard event.
• Adaptation Measures: For each hazard in the physical integrity family, the BRI provides a list of recommended mitigation measures, categorized according to the building’s rating (A+ to C). These measures are aimed at enhancing resilience and reducing the risk of structural damage.
• Focus on Risk Reduction: The BRI’s primary goal is to help buildings reduce structural risk relative to similar properties rather than compare them to an absolute standard of performance

• Monitors the environmental conditions of a city, district, or building, including temperature, heat waves, rainfall, drought, and extreme weather events, using ten indicators.
• Assesses the city's vulnerability to climate change through 16 indicators, evaluating its sensitivity and adaptive capacity, focusing on its readiness and the specific characteristics of local systems.
• Uses 14 indicators to measure the area's contribution to greenhouse gas emissions, determining the city's responsibility for climate change in both direct and indirect emissions.
• Employs 16 indicators to assess the preparedness of city, district, or building owners to implement adaptation and mitigation measures, and their impact on daily life.

The evaluation results are summarized with a Climate Label.

• Risk Maps: Visual representations of drought risk areas
• Indicators: metrics to assess vulnerability and exposure
• Methodologies: guidelines for conducting risk assessment
• Data Sources: access to relevant datasets for accurate analysis