Lightningmaps.org App Android: Android users can use LightningMap to see where lightning strikes have happened. Cloud data, microphysics, and other Radar Data are also provided by the application. Only Europe is now supported in a significant way, and this is entirely reliant on the number of stations in a given area. This app gathers data for informational purposes exclusively using the Lightningmaps.org service.
LightningMaps.org is a Blitzortung.org add-on service. Before contacting us with any general questions or issues, please read the FAQs, documentation, and directives for this project. Furthermore, the discussion board is an excellent place to ask any questions, and both we and the other participants will answer quickly. Please use the following email address to contact us: mail @ lightningmaps.org.
The information on Blitzortung.org is provided solely for entertainment purposes and should not be relied upon. We take no responsibility for the content on this website’s quality, accuracy, timeliness, or completeness. We disclaim all responsibility for any injury resulting from the use or reliance on the material on this website. The data on Blitzortung.org is not suitable for an insurance plausibility assessment and is not intended to protect life and property! When this happens, you should look for a commercial lightning data supplier!
Maps and data are incorporated
The great majority of the maps on LightningMaps.org are licensed under the Creative Commons Attribution-ShareAlike 4.0 License. On the footers of the maps, CC BY-SA licenses are explicitly marked. When using the map, cite Blitzortung.org and contributors for lightning data, and LightningMaps.org to reference the map itself. Example: Areas that are not CC-BY-SA mapped can nevertheless be used for private purposes. The majority of the time, these maps are combined with third-party overlays like satellite images. You are responsible for ensuring that their licenses are valid.
LightningMaps.org.com’s imprint
You may also take screenshots of our web pages, but you are solely responsible for correct attribution. For example, the underlying map for real-time lightning maps must include the following information: “Source: Lightningmaps.org” (with a link), “Lightning data by Blitzortung.org and contributors,” and “Map: Google” (and even more sources). If there isn’t enough area for all sources, lightningmaps.org or “LMaps.org” should be referenced with a direct link (e.g. on a preview image). External websites cannot use iFrames or equivalent technologies to display real-time maps or other raw lightning data.
This address should not be used for general help or questions regarding lightning strikes in your area at specific times. Thanks! The company’s privacy and cookie policies are outlined in this document. We only collect personal data that is required to accomplish the goals for which it is being collected. We will only request personal information if it is required by law or is required for a specific reason. We use collected information for supplementary and compatible reasons, such as internal reporting, and as permitted by law, in addition to replying to a query. We won’t use your information for anything else. Various Google products (Maps, AdSense) and Matomo may store third-party browser cookies (web analytics platform – opt-out).
The network includes around 500 lightning receivers as well as a few central processing computers. The flashes of lightning that we see are the source of the signals we observe. VLF (Very Low Frequency) is employed in the frequency range of 3 to 30 kHz. Receiving stations record one millisecond of each signal at a sample rate of more than 500 kHz. The arrival times of the signals are recorded down to the millisecond using GPS devices and forwarded to our central processing servers for processing through the Internet. Each data phrase includes the exact moment of arrival when a lightning discharge impulse (sferic) is received. Using data from a number of sites, the specific locations of the discharges can be identified.
Following paragraphs provide a quick overview of project:
“Blitzortung.org” is a lightning detection network that uses VLF receivers to locate electromagnetic discharges (lightning discharges) in the atmosphere using the TOA and TOGA technologies. We are a community of people who collaborate to keep the system running, including station operators, programmers, and others who assist in any manner possible in getting data to the servers. The number of people who can join is unlimited. The only people who keep the network working are volunteers. There are no fees, terms, or obligations to worry about.
If a station decides to discontinue sharing its data, the server will no longer give access to the original raw data to that station’s users. One of the project’s main goals is to create a large network of low-cost lightning detection stations. Building the gear yourself currently costs less than 300 euros. Raw access to the sferic positions is available to any users who transmit data to our servers. The raw data can be utilized by the station owners for any non-commercial purpose. In addition, our website displays lightning activity on a variety of public maps in real time. The typical delay varies from 3 to 20 seconds depending on the traffic on our servers.
We built a special detector specifically for recording the signals. This includes several amplifiers as well as a digital section for processing and forwarding data to our central processing server. To keep costs down for potential participants, it is encouraged that participants obtain as many electronic components as possible from local providers. It is primarily aimed at persons with an interest in meteorology and knowledge of electrical and computer engineering. For the construction and operation of a lightning detector, a basic understanding of the receiving technology is required.
The RED system was operational from Spring 2012 to Autumn 2014
The “System Red” detection system improved significantly thanks to the piggyback controller board with an STM32 F4 Mikrocontroller. After connecting to a router, the system may be run without any additional tracking software on a personal computer. We haven’t been supplying boards for the still-in-use System Red since the fall of 2014. Because the system’s creation took so long, we didn’t have enough time to work with the participants on it. Only in exceptional circumstances will we be able to provide Red System kits to fascinating locations and persons with sufficient knowledge of electronic device design.
Our newest detection system is known as “System Blue.” This new detecting system will take the place of “System Red. (ctlsites.uga.edu) ” The basic difference between the two systems is the way they are put together. The majority of System Red’s components are connected. SMD components make up the majority of System Blue. When it arrives, a piece of it will be pre-assembled. A new amplifier and filter system, as well as a new digital component, have been fitted. System Blue is also compact enough to fit into a small enclosure. Because of the controller board’s size and the way the connections are put up, this is conceivable.
(The GREEN system will be in place until Spring 2012)
The “System Green” detection system was our first piece of hardware to detect objects using a time measurement. The signal was only calculated when it exceeded a certain threshold. Using counter data provided by the controller, time stamps were determined with a precision of one microsecond. The time stamps were provided to our servers on a regular basis by personal PCs running a tracker program. To put it another way, the computer was always on. A/D converters were added to the system to complete development.
