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content/project/2024-06-20-sferics/index.de.md
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title = "Übersetzung: Sferics"
description = "On a hunt for the Voice of the out there"
title = "Sferics"
description = "Auf der Jagd nach der Stimme von Blitzen aus tausenden Kilometern Entfernung"
date = 2024-06-20
authors = ["Aron Petau"]
[taxonomies]
tags = [
"antenna",
"electronics",
"magnetism",
"fm",
"geosensing",
"lightning",
"radio",
"sferics",
"vlf",
"university of the arts berlin"
]
@ -21,39 +21,91 @@ show_copyright = true
show_shares = true
+++
## What the hell are Sferics?
## Was zum Teufel sind Sferics?
>A radio atmospheric signal or sferic (sometimes also spelled "spheric") is a broadband electromagnetic impulse that occurs as a result of natural atmospheric lightning discharges. Sferics may propagate from their lightning source without major attenuation in the Earthionosphere waveguide, and can be received thousands of kilometres from their source.
> Ein atmosphärisches Funksignal oder Sferics (manchmal auch "Spherics"
> geschrieben) ist ein breitbandiger elektromagnetischer Impuls, der durch
> natürliche atmosphärische Blitzentladungen entsteht. Sferics können sich
> von ihrer Blitzquelle ohne wesentliche Dämpfung im Wellenleiter zwischen
> Erde und Ionosphäre ausbreiten und tausende Kilometer von ihrer Quelle
> entfernt empfangen werden.
- [Wikipedia](https://en.wikipedia.org/wiki/Radio_atmospheric_signal)
*Quelle: [Wikipedia](https://en.wikipedia.org/wiki/Radio_atmospheric_signal)*
## Why catch them?
## Warum einfangen?
[Microsferics](microsferics.com) is a nice reference Project, which is a network of Sferics antennas, which are used to detect lightning strikes. Through triangulation not unlike the Maths happening in GPS, the (more or less) exact location of the strike can be determined. This is useful for weather prediction, but also for the detection of forest fires, which are often caused by lightning strikes.
[Microsferics](https://microsferics.com) ist ein faszinierendes
Referenzprojekt—ein Netzwerk von Sferics-Antennen zur Detektion von
Blitzeinschlägen. Durch Triangulation (ähnlich wie bei GPS-Mathematik)
können sie den mehr oder weniger genauen Ort jedes Einschlags bestimmen.
Das ist nützlich für Wettervorhersagen und die Erkennung von Waldbränden,
die oft durch Blitze verursacht werden.
Because the Frequency of the Sferics is, when converted to audio, still in the audible range, it is possible to listen to the strikes. This usually sounds a bit like a crackling noise, but can also be quite melodic. I was a bit reminded by a Geiger Counter.
Wenn man Sferics-Frequenzen in Audio umwandelt, liegen sie im hörbaren
Bereich, sodass man Blitzeinschläge tatsächlich *hören* kann. Der Klang ist
normalerweise ein Knistern, manchmal aber überraschend melodisch—erinnert an
einen Geigerzähler.
Sferics are in the VLF (Very Low Frequency) range, sitting roughly at 10kHz, which is a bit of a problem for most radios, as they are not designed to pick up such low frequencies. This is why we built our own antenna.
At 10kHz, we are talking about insanely large waves. a single wavelength there is roughly 30 Kilometers. This is why the antenna needs to be quite large. A special property of waves this large is, that they get easily reflected by the Ionosphere and the Earth's surface. Effectively, a wave like this can bounce around the globe several times before it is absorbed by the ground. This is why we can pick up Sferics from all over the world and even listen to Australian Lightning strikes. Of course, without the maths, we cannot attribute directions, but the so called "Tweeks" we picked up, usually come from at least 2000km distance.
### Die technische Herausforderung
## The Build
Sferics befinden sich im VLF-Bereich (Very Low Frequency), um die 10 kHz—
ein Problem für die meisten Radios, die nicht für so niedrige Frequenzen
ausgelegt sind. Deshalb haben wir unsere eigene Antenne gebaut.
We built several so-called "Long-Loop" antennas, which are essentially a coil of wire with a capacitor at the end. Further, a specific balun is needed, depending on the length of the wire. this can then directly output an electric signal on an XLR cable.
Bei 10 kHz haben wir es mit *wahnsinnig* großen Wellen zu tun: Eine einzelne
Wellenlänge erstreckt sich über etwa 30 Kilometer. Diese Größenordnung
erfordert eine beträchtliche Antenne. Eine besondere Eigenschaft solcher
massiven Wellen ist ihre Tendenz, zwischen Ionosphäre und Erdoberfläche zu
reflektieren—sie springen praktisch mehrmals um den Globus, bevor sie
absorbiert werden. Das bedeutet, wir können Sferics aus der ganzen Welt
empfangen, sogar australische Blitzeinschläge!
Loosely based on instructions from [Calvin R. Graf](https://archive.org/details/exploringlightra00graf), We built a 26m long antenna, looped several times around a wooden frame.
Ohne richtige Triangulations-Mathematik können wir keine genauen Richtungen
bestimmen, aber die "Tweeks", die wir aufgenommen haben, stammen
typischerweise aus mindestens 2.000 km Entfernung.
## The Result
## Der Bau
We have several hour-long recordings of the Sferics, which we are currently investigating for further potential.
Wir konstruierten mehrere "Long-Loop"-Antennen—im Grunde eine Drahtspule
mit einem Kondensator am Ende. Je nach Drahtlänge wird ein spezifischer
Balun benötigt, um ein elektrisches Signal über ein XLR-Kabel auszugeben.
Have a listen to a recording of the Sferics here:
Lose basierend auf Anleitungen von
[Calvin R. Graf](https://archive.org/details/exploringlightra00graf), bauten
wir eine 26 Meter lange Antenne, die mehrfach um einen Holzrahmen gewickelt
wurde.
## Das Ergebnis
Wir haben mehrere Stunden Sferics-Aufnahmen gemacht, die wir derzeit auf
weiteres Potenzial untersuchen.
### Hör dem Blitz zu
{{ youtube(id="2YYPg_K3dI4") }}
As you can hear, there is quite a bit of 60 hz ground buzz in the recording.
This is either due to the fact that the antenna was not properly grounded or we simply were still too close to the bustling city.
I think it is already surprising that we got such a clear impression so close to Berlin. Let's see what we can get in the countryside!
Wie man hören kann, gibt es ein merkliches 60-Hz-Brummen in der Aufnahme.
Das liegt wahrscheinlich an unzureichender Erdung oder unserer Nähe zur
geschäftigen Stadt. Trotzdem ist es überraschend, dass wir so klare
Ergebnisse so nah an Berlin erzielt haben. Mal sehen, was die Landschaft
ergibt!
![Listening at night](sferics1.jpeg)
![The Drachenberg](sferics2.jpeg)
![The Antenna](sferics3.jpeg)
{% gallery() %}
[
{
"file": "./sferics1.jpg",
"alt": "Nachts Sferics lauschen",
"title": "Nächtliche Session zum Erfassen atmosphärischer Signale"
},
{
"file": "./sferics2.jpg",
"alt": "Der Drachenberg-Standort",
"title": "Aufnahmeort am Drachenberg"
},
{
"file": "./sferics3.jpg",
"alt": "Die Long-Loop-Antenne",
"title": "Unser 26-Meter VLF-Antennenaufbau"
}
]
{% end %}

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content/project/2024-06-20-sferics/index.md
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title = "Sferics"
description = "On a hunt for the Voice of the out there"
description = "Hunting for the voice of lightning from thousands of kilometers away"
date = 2024-06-20
authors = ["Aron Petau"]
[taxonomies]
tags = [
"antenna",
"electronics",
"magnetism",
"fm",
"geosensing",
"lightning",
"radio",
"sferics",
"vlf",
"university of the arts berlin"
]
@ -21,39 +21,85 @@ show_copyright = true
show_shares = true
+++
## What the hell are Sferics?
## What the Hell are Sferics?
>A radio atmospheric signal or sferic (sometimes also spelled "spheric") is a broadband electromagnetic impulse that occurs as a result of natural atmospheric lightning discharges. Sferics may propagate from their lightning source without major attenuation in the Earthionosphere waveguide, and can be received thousands of kilometres from their source.
> A radio atmospheric signal or sferic (sometimes also spelled "spheric") is
> a broadband electromagnetic impulse that occurs as a result of natural
> atmospheric lightning discharges. Sferics may propagate from their lightning
> source without major attenuation in the Earthionosphere waveguide, and can
> be received thousands of kilometres from their source.
- [Wikipedia](https://en.wikipedia.org/wiki/Radio_atmospheric_signal)
*Source: [Wikipedia](https://en.wikipedia.org/wiki/Radio_atmospheric_signal)*
## Why catch them?
## Why Catch Them?
[Microsferics](microsferics.com) is a nice reference Project, which is a network of Sferics antennas, which are used to detect lightning strikes. Through triangulation not unlike the Maths happening in GPS, the (more or less) exact location of the strike can be determined. This is useful for weather prediction, but also for the detection of forest fires, which are often caused by lightning strikes.
[Microsferics](https://microsferics.com) is a fascinating reference project—a
network of sferics antennas used to detect lightning strikes. Through
triangulation (not unlike GPS mathematics), they can determine the
more-or-less exact location of each strike. This proves useful for weather
prediction and detecting forest fires, which are often caused by lightning.
Because the Frequency of the Sferics is, when converted to audio, still in the audible range, it is possible to listen to the strikes. This usually sounds a bit like a crackling noise, but can also be quite melodic. I was a bit reminded by a Geiger Counter.
When converted to audio, sferics frequencies fall within the audible range,
making it possible to actually *listen* to lightning strikes. The sound is
usually a crackling noise, though sometimes surprisingly melodic—reminiscent
of a Geiger counter.
Sferics are in the VLF (Very Low Frequency) range, sitting roughly at 10kHz, which is a bit of a problem for most radios, as they are not designed to pick up such low frequencies. This is why we built our own antenna.
At 10kHz, we are talking about insanely large waves. a single wavelength there is roughly 30 Kilometers. This is why the antenna needs to be quite large. A special property of waves this large is, that they get easily reflected by the Ionosphere and the Earth's surface. Effectively, a wave like this can bounce around the globe several times before it is absorbed by the ground. This is why we can pick up Sferics from all over the world and even listen to Australian Lightning strikes. Of course, without the maths, we cannot attribute directions, but the so called "Tweeks" we picked up, usually come from at least 2000km distance.
### The Technical Challenge
Sferics live in the VLF (Very Low Frequency) range, around 10 kHz—a problem
for most radios not designed for such low frequencies. That's why we built our
own antenna.
At 10 kHz, we're dealing with *insanely* large waves: a single wavelength
stretches roughly 30 kilometers. This scale demands a sizable antenna. A
special property of such massive waves is their tendency to reflect between
the ionosphere and Earth's surface—effectively bouncing around the globe
several times before absorption. This means we can pick up sferics from all
over the world, even Australian lightning strikes!
Without proper triangulation math, we can't determine exact directions, but
the "tweeks" we captured typically originate from at least 2,000 km away.
## The Build
We built several so-called "Long-Loop" antennas, which are essentially a coil of wire with a capacitor at the end. Further, a specific balun is needed, depending on the length of the wire. this can then directly output an electric signal on an XLR cable.
We constructed several "long-loop" antennas—essentially a coil of wire with a
capacitor at the end. A specific balun is needed (depending on wire length) to
output an electrical signal via XLR cable.
Loosely based on instructions from [Calvin R. Graf](https://archive.org/details/exploringlightra00graf), We built a 26m long antenna, looped several times around a wooden frame.
Loosely following instructions from
[Calvin R. Graf](https://archive.org/details/exploringlightra00graf), we built
a 26-meter antenna looped multiple times around a wooden frame.
## The Result
We have several hour-long recordings of the Sferics, which we are currently investigating for further potential.
We captured several hours of sferics recordings, which we're currently
investigating for further potential.
Have a listen to a recording of the Sferics here:
### Listen to the Lightning
{{ youtube(id="2YYPg_K3dI4") }}
As you can hear, there is quite a bit of 60 hz ground buzz in the recording.
This is either due to the fact that the antenna was not properly grounded or we simply were still too close to the bustling city.
I think it is already surprising that we got such a clear impression so close to Berlin. Let's see what we can get in the countryside!
As you can hear, there's a noticeable 60 Hz ground buzz in the recording.
This likely stems from improper grounding or our proximity to the bustling
city. Still, it's surprising we achieved such clear results so close to
Berlin. Let's see what the countryside yields!
![Listening at night](sferics1.jpeg)
![The Drachenberg](sferics2.jpeg)
![The Antenna](sferics3.jpeg)
{% gallery() %}
[
{
"file": "./sferics1.jpg",
"alt": "Listening to sferics at night",
"title": "Night session capturing atmospheric signals"
},
{
"file": "./sferics2.jpg",
"alt": "The Drachenberg location",
"title": "Recording location at Drachenberg"
},
{
"file": "./sferics3.jpg",
"alt": "The long-loop antenna",
"title": "Our 26-meter VLF antenna setup"
}
]
{% end %}