With many thanks from Victor Herrero-Arrieta to the Teams at Juno Waves, NASA Planetary Data System, STEREO A, WIND, and the Tax Payers of the United States of America.
With many thanks, Victor Herrero-Arrieta acknowledges the Nançay Radio Observatory / Unité Scientifique de Nançay of the Observatoire de Paris (USR 704-CNRS, supported by Université d’Orléans, OSUC, and Région Centre in France) for providing access to NDA observations accessible online at http://www.obs-nancay.fr
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Introductory Radio Astronomy links:
http://herrero-radio-
Jupiter:
https://en.wikipedia.org/wiki/
Magnetosphere of Jupiter:
https://en.wikipedia.org/wiki/
Kurth et al. 2017, "The Juno Waves Investigation" 46 page pdf:
https://link.springer.com/
Connerney et al. 2017, "The Juno Magnetic Field Investigation" 100 page pdf:
https://link.springer.com/
"Properties of Decameter IIIb-III Pairs" Melnik et al. 2018 18 page pdf:
https://arxiv.org/pdf/1802.
"Solar Type IV bursts at frequencies 10-30 MHz" Melnik et al. 2018 51 page pdf :
https://arxiv.org/pdf/1802.
Links to many Sun Earth Jupiter posts:
http://herrero-radio-
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Jupiter events at Juno Waves and other observatories :
http://herrero-radio-astronomy.blogspot.com/2017/09/jupiter-events-1-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2017/09/jupiter-events-2-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2017/09/jupiter-events-3-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2017/09/jupiter-events-4-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2017/10/jupiter-events-5-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2017/10/jupiter-events-6-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2017/11/jupiter-events-7-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2018/01/jupiter-events-8-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2018/01/jupiter-events-9-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2018/02/jupiter-events-10-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2018/02/jupiter-events-11-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2018/03/jupiter-events-12-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2018/04/jupiter-events-15-at-juno-waves-and.html
http://herrero-radio-astronomy.blogspot.com/2018/04/jupiter-events-16-at-juno-waves-and.html
Jupiter events at the University of Iowa Space Physics LWA1 Data Project :
http://herrero-radio- astronomy.blogspot.com/2017/ 08/jupiter-events-1-at- university-of-iowa.html
http://herrero-radio- astronomy.blogspot.com/2017/ 08/jupiter-events-2-at- university-of-iowa.html
http://herrero-radio- astronomy.blogspot.com/2017/ 09/jupiter-events-3-at- university-of-iowa.html
http://herrero-radio- astronomy.blogspot.com/2017/ 09/jupiter-events-4-at- university-of-iowa.html
http://herrero-radio- astronomy.blogspot.com/2017/ 09/jupiter-events-5-at- university-of-iowa.html
http://herrero-radio- astronomy.blogspot.com/2017/ 09/jupiter-events-6-at- university-of-iowa.html
http://herrero-radio- astronomy.blogspot.com/2017/ 09/jupiter-events-7-at- university-of-iowa.html
http://herrero-radio- astronomy.blogspot.com/2017/ 11/jupiter-events-8-at- university-of-iowa.html
Examples of Jupiter events observed by Juno Waves :
http://herrero-radio- astronomy.blogspot.com/2017/ 05/examples-of-jupiter-events- observed-by.html
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Flux computation example , Nancay Decametric Array :
http://herrero-radio-
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http://herrero-radio-
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Examples of Jupiter events observed by Juno Waves :
http://herrero-radio-
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Flux computation example , Nancay Decametric Array :
25 MHz , 100 data units , source in beam axis
calibrated with 50.71 dB 300 kelvin calibrator , ~ 165 data units
Flux = NoiseTemperature*Boltzman/ Bandwidth/EffectiveArea
NoiseTemperature = 10^(DataUnits*0.046) kelvin
Boltzman = 1.38E-23 joule/kelvin
Bandwidth = 1E5 hertz
EffectiveArea at 25MHz ~ 3.3E3 meter^2
area is proportional to cosine^2(angle from line of sight to antenna axis) , antenna axis point to 20 degrees south of zenith
Flux = 3.98E4*1.38E-23/1E5/3.3E3 = 1.66E-27 watt/hertz/meter^2
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calibrated with 50.71 dB 300 kelvin calibrator , ~ 165 data units
Flux = NoiseTemperature*Boltzman/
NoiseTemperature = 10^(DataUnits*0.046) kelvin
Boltzman = 1.38E-23 joule/kelvin
Bandwidth = 1E5 hertz
EffectiveArea at 25MHz ~ 3.3E3 meter^2
area is proportional to cosine^2(angle from line of sight to antenna axis) , antenna axis point to 20 degrees south of zenith
Flux = 3.98E4*1.38E-23/1E5/3.3E3 = 1.66E-27 watt/hertz/meter^2
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