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  • What determines planetary climate.

    From Gerald Kelleher@21:1/5 to All on Tue Jan 10 11:23:15 2023
    The short answer for any given planet is the relationship between the North/South poles to the orbital plane.

    The familiar 23 1/2 degrees for the Earth is replaced by 66 1/2 degrees relative to the orbital plane. The latter value determines the range and rate of change of a circumference where the Sun remains in view or out of sight, where the Arctic/Antarctic
    circles with the North/South poles at their centre represent the maximum circumference.

    All these productive graphics are out there, and I couldn't find a serious researcher with the ability to put planetary climate into a visual narrative. The rotational motion of the North and South poles relative to the Sun and the planet's divisor
    creates the expanding and contracting circumferences, with the period from the December Solstice to the March Equinox being a period of contraction of those circumferences.





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  • From a a@21:1/5 to kellehe...@gmail.com on Sat Jan 14 06:00:44 2023
    On Tuesday, 10 January 2023 at 20:23:17 UTC+1, kellehe...@gmail.com wrote:
    The short answer for any given planet is the relationship between the North/South poles to the orbital plane.

    The familiar 23 1/2 degrees for the Earth is replaced by 66 1/2 degrees relative to the orbital plane. The latter value determines the range and rate of change of a circumference where the Sun remains in view or out of sight, where the Arctic/Antarctic
    circles with the North/South poles at their centre represent the maximum circumference.

    All these productive graphics are out there, and I couldn't find a serious researcher with the ability to put planetary climate into a visual narrative. The rotational motion of the North and South poles relative to the Sun and the planet's divisor
    creates the expanding and contracting circumferences, with the period from the December Solstice to the March Equinox being a period of contraction of those circumferences.
    Earth's climate is clocked by fluctuations in solar acitivity resulting in short-term climate changes.

    This is the reason, 10,000 scientists world-wide study today space weather.

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    * Origin: fsxNet Usenet Gateway (21:1/5)
  • From Chris L Peterson@21:1/5 to All on Sat Jan 14 07:43:21 2023
    On Sat, 14 Jan 2023 06:00:44 -0800 (PST), a a <manta103g@gmail.com>
    wrote:

    On Tuesday, 10 January 2023 at 20:23:17 UTC+1, kellehe...@gmail.com wrote:
    The short answer for any given planet is the relationship between the North/South poles to the orbital plane.

    The familiar 23 1/2 degrees for the Earth is replaced by 66 1/2 degrees relative to the orbital plane. The latter value determines the range and rate of change of a circumference where the Sun remains in view or out of sight, where the Arctic/
    Antarctic circles with the North/South poles at their centre represent the maximum circumference.

    All these productive graphics are out there, and I couldn't find a serious researcher with the ability to put planetary climate into a visual narrative. The rotational motion of the North and South poles relative to the Sun and the planet's divisor
    creates the expanding and contracting circumferences, with the period from the December Solstice to the March Equinox being a period of contraction of those circumferences.
    Earth's climate is clocked by fluctuations in solar acitivity resulting in short-term climate changes.

    This is the reason, 10,000 scientists world-wide study today space weather.

    Earth's current climate change is 100% the product of global warming
    created by the human release of greenhouse gases.

    --- SoupGate-Win32 v1.05
    * Origin: fsxNet Usenet Gateway (21:1/5)
  • From Gerald Kelleher@21:1/5 to mant...@gmail.com on Sat Jan 14 06:15:42 2023
    On Saturday, January 14, 2023 at 2:00:46 PM UTC, mant...@gmail.com wrote:
    On Tuesday, 10 January 2023 at 20:23:17 UTC+1, kellehe...@gmail.com wrote:
    The short answer for any given planet is the relationship between the North/South poles to the orbital plane.

    The familiar 23 1/2 degrees for the Earth is replaced by 66 1/2 degrees relative to the orbital plane. The latter value determines the range and rate of change of a circumference where the Sun remains in view or out of sight, where the Arctic/
    Antarctic circles with the North/South poles at their centre represent the maximum circumference.

    All these productive graphics are out there, and I couldn't find a serious researcher with the ability to put planetary climate into a visual narrative. The rotational motion of the North and South poles relative to the Sun and the planet's divisor
    creates the expanding and contracting circumferences, with the period from the December Solstice to the March Equinox being a period of contraction of those circumferences.
    Earth's climate is clocked by fluctuations in solar acitivity resulting in short-term climate changes.

    This is the reason, 10,000 scientists world-wide study today space weather.


    The circumference where the Sun remains out of sight with the North pole at its centre is contracting, signifying a new approach to the seasons and from into planetary climate-

    https://www.timeanddate.com/sun/norway/hammerfest

    The contraction can be seen as the North pole turns parallel to the orbital plane and, therefore, currently shortens its radius and surrounding area to the planet's divisor and the light hemisphere of the Earth; as the radius shortens, then so does the
    surface area where the Sun remains out of sight until the March Equinox when that area disappears altogether and replaces by an expanding circumference where the Sun remains in view.

    Black are the souls of those who would have humanity live in anxiety and hysteria so they can make a living from the experimental method of theorists.

    Planetary climate is the rate of change in surface, atmospheric and oceanic conditions across latitudes determined by the relationship of the North/South poles to the orbital plane. The closer to the orbital plane the rotational inclination is, the more
    active those conditions are, and the further away to a maximum of 90 degrees, the more benign conditions are.

    It is all verified by observation-

    https://www.youtube.com/watch?v=612gSZsplpE

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  • From Gerald Kelleher@21:1/5 to All on Sat Jan 14 09:48:43 2023
    The most significant difficulty that Copernicus faced when trying to describe a helio-static system using the Ptolemaic framework was how to account for the apparent change in the position of the stars by 1 degree every 72 years, otherwise known as the
    precession of the equinoxes.

    With the older Decans framework, responsible for the calendar system based on a proportion of 365 1/4 rotations per circuit, the problem disappears as the discrepancy is a further refinement of observation that Sirius precesses by one day after the
    fourth 365 day cycle-

    ".. on account of the procession of the rising of Sirius by one day in the course of 4 years,.. therefore it shall be, that the year of 360 days and the 5 days added to their end, so one day shall be from this day after every 4 years added to the 5
    epagomenae before the new year" Canopus Decree 238 BC

    This decree was discovered in the late 19th century so its contents would have been unknown to Copernicus and his contemporaries, all they would have known is the framework of Ptolemy built on the calendar framework of the Decans.

    To be fair to Copernicus, he originally described the actual turning of the poles in a circle every orbit in the earlier Commentariolus pamphlet -

    " The third is the motion in declination. For, the axis of the daily rotation is not parallel to the Grand Orb's axis, but is inclined [to it at an angle that intercepts] a portion of a circumference, in our time about 23 1/2°. Therefore, while the
    earth's center always remains in the plane of the ecliptic, that is, in the circumference of a circle of the Grand Orb, the earth's poles rotate, both of them describing small circles about centers [lying on a line that moves] parallel to the Grand Orb's
    axis. " Copernicus

    Not only do the Earth's poles rotate parallel to the orbital plane and ecliptic, the entire surface does hence the expanding and contracting circumferences with the North/South poles at their centre. By appealing to the original framework from remote
    antiquity based on the first annual appearance of the stars in 36 seperate constellations rather than the less accurate Sun in ecliptic longitudinal motion, the Precession of the Equinoxes becomes a rotational/orbital proportion issue thereby free up
    information on the cause of the seasons and into climate.

    It is abundantly clear that few see things visually through no fault of their own, yet they prevent others who absolutely can link planetary dynamics with planetary climate, planetary biology and planetary geology.

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