7/30/2019 Earth's Rhythms, Schumann Resonances, Magnetic Field Sensor, Global Coherence Monitoring System http://slidepdf.com/reader/full/earths-rhythms-schumann-resonances-magnetic-field-sensor-global-coherence 1/4 Sayfa 1 rth's rhythms, Schumann resonances, magnetic field sensor, Global Coherence Monitoring System 24.03.2012 11:48:14 p://www.glcoherence.org/index2.php?option=com_content&Itemid=9&id=19&lang=en§ionid=5&task=view Global Coherence Initiative - earth's rhythms, Schumann resonances, magnetic field sensor, Global Coherence Monitoring System URL: http://www.glcoherence.org /index2.php?option=com_content&Itemid=9&id=19&lang=en§ionid=5&task=view Earth Rhythms This section explains examples of data obtained from the Global Coherence Monitoring System site located in Boulder Creek, Calif., at the Institute of HeartMath Research Center. The graphs include examples of time domainsignals, frequency spectrums, spectrograms and waterfall plots. The spectrum figures clearly show the various Schumann resonances and how the resonances change over time. In addition, an audio file is included so you can hear what these earth rhythms sound like when shifted into an audible range. You are able to see near real-time updates onthe changes occurring in the (click on Live Data) resonances and magnetic fields within the earth’s ionosphere. Figure 1. This graph shows about eight seconds of data from the magnetic field sensor. The toptraceis from the sensor that is positioned to detect fields arriving from the vertical direction (from above the sensor), the middle trace is from the sensor detecting fields in a north/south axis, and the bottom trace is detects fields occurring in the east/west direction. These are complex signals and contain a number of quasi-standing waves with wavelengths comparable to the planetary dimensions. These standing waves are known as the Schumannresonances. Schumann Resonances: Schumannresonances were named after the German physicist Winfried Schumann who first discovered them in 1952. Radiation from the sun ionizes part of the earth’s atmosphere and forms a conductive plasma layer, the ionosphere. The ionosphere surrounding our planetis positively charged relative to the earth’s surface, which carries a negative charge. This creates an electrical tension within the space between the earth and ionosphere. Every second, there are about 1000 lightening storms worldwide, which help to excite the Schumann resonances. Schumann resonances occur because the earth’s conductive surface and the lower boundary ofthe conductive ionosphere are separated by a cavity of nonconducting air that is acting as a wave-guide. The resonant frequencies of the earth-ionosphere cavity are in the ultralow frequency range (ULF) and extremely low frequency range (ELF). (See Figure 2) Figure 2. Schumann resonances in earth-ionosphere cavity. Seven of the Schumann resonances can be seen in Figure 3. The lowest-frequency mode ofthe Schumann resonance is at a frequency of approximately 7.83, 14, 20, 26, 33, 39and 45 Hz, with a daily variation of about ± 0.5 Hertz, which is caused by the daily increase and decreases in the ionization ofthe ionosphere because of variations in radiation from the sun. This has the effect of reducing the height of the ionosphere at noon local time. Another factor that influences these frequencies is the solar activity during solar cycles, which last nine to 14 years, This
4
Embed
Earth's Rhythms, Schumann Resonances, Magnetic Field Sensor, Global Coherence Monitoring System
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
7/30/2019 Earth's Rhythms, Schumann Resonances, Magnetic Field Sensor, Global Coherence Monitoring System
This section explains examples of data obtained from the Global Coherence Monitoring System site located in Boulder
Creek, Calif., at the Institute of HeartMath Research Center. The graphs include examples of time domain signals, frequency
spectrums, spectrograms and waterfall plots. The spectrum figures clearly show the various Schumann resonances and
how the resonances change over time. In addition, an audio file is included so you can hear what these earth rhythms sound
like when shifted into an audible range. You are able to see near real-time updates on the changes occurring in the (click on Live Data) resonances and magnetic fields within the earth’s ionosphere.
Figure 1.
This graph shows about eight seconds of data from the magnetic field sensor. The top traceis
from the sensor that is positioned to detect fields arriving from the vertical direction (from
above the sensor), the middle trace is from the sensor detecting fields in a north/south axis,
and the bottom trace is detects fields occurring in the east/west direction. These are complex
signals and contain a number of quasi-standing waves with wavelengths comparable to the
planetary dimensions. These standing waves are known as the Schumann resonances.
Schumann Resonances:
Schumann resonances were named after the German physicist Winfried Schumann who first discovered them in 1952.
Radiation from the sun ionizes part of the earth’s atmosphere and forms a conductive plasma layer, the ionosphere. The
ionosphere surrounding our planet is positively charged relative to the earth’s surface, which carries a negative charge. This
creates an electrical tension within the space between the earth and ionosphere. Every second, there are about 1000
lightening storms worldwide, which help to excite the Schumann resonances. Schumann resonances occur because the
earth’s conductive surface and the lower boundary of the conductive ionosphere are separated by a cavity of nonconducting
air that is acting as a wave-guide. The resonant frequencies of the earth-ionosphere cavity are in the ultralow frequency
range (ULF) and extremely low frequency range (ELF). (See Figure 2)
Figure 2.
Schumann resonances in earth-ionosphere cavity.
Seven of the Schumann resonances can be seen in Figure 3. The lowest-frequency mode of the Schumann resonance is at a
frequency of approximately 7.83, 14, 20, 26, 33, 39 and 45 Hz, with a daily variation of about ± 0.5 Hertz, which is caused by
the daily increase and decreases in the ionization of the ionosphere because of variations in radiation from the sun. This has
the effect of reducing the height of the ionosphere at noon local time.
Another factor that influences these frequencies is the solar activity during solar cycles, which last nine to 14 years, This
7/30/2019 Earth's Rhythms, Schumann Resonances, Magnetic Field Sensor, Global Coherence Monitoring System
Another factor that influences these frequencies is the solar activity during solar cycles, which last nine to 14 years, This
activity includes the approximately 11-year sunspot cycles, solar, coronal mass ejections and geomagnetic storms. The cavity
is widely believed to be naturally excited by energy from lightning strikes, but there may be other sources of excitation.
F gure 3.
The time domain signals shown in Figure 1 are converted to the frequency domain with the
Fourier transform. The Schumann resonances occurring over an eight-hour period can be
clearly seen at approximately 7.8, 14, 20, 26 , 33, 39, and 45 Hz.
Schumann resonances have been used for research and monitoring of the lower ionosphere and can be used to track
geomagnetic and ionospheric disturbances. A new field of interest, measuring earth’s magnetic fields, is related to short-
term earthquake prediction. Schumann resonances also have gone beyond the boundaries of physics, into medicine, where ithas raised interest in the interactions between planetary rhythms and human health and behavior (for more detail see,
http://www.glcoherence.org/monitoring-system/commentaries.html , July 7. 2009)
Although the existence of the Schumann resonances is an established scientific fact, their presence and how these important
planetary electromagnetic standing waves act as a background frequency that can influence biological oscillators such as the
heart and brain are not generally well known. GCI hopes to further understanding of these processes through its scientific
research.
Figure 4.
This graph is a waterfall plot showing one-hour spectrums over a five-day period. The first hour
is at the bottom of the graph and additional hours are plotted as you move up the graph. Thedarker areas indicate increased activity in daytime hours and showthat although the
Schumann resonances are always present, they are stronger during daytime hours.
When Schumann first published his research the similarity of the 7.8-hertz earth resonance and the rhythms of human
brainwaves was quickly realized. Herbert König, who became Schumann’s successor at Munich University, later
demonstrated a correlation between Schumann resonances and brain rhythms. Numerous studies conducted by the Halberg
Chronobiology Center at the University of Minnesota and other scientific studies have since shown that there are important
links between solar, Schumann and geomagnetic rhythms and a wide range of human and animal health and wellness
indicators. Even historical events like war, social unrest, military events and acts of terrorism can be correlated with the
solar cycles.
7/30/2019 Earth's Rhythms, Schumann Resonances, Magnetic Field Sensor, Global Coherence Monitoring System