Starship Asterisk*

Chris Peterson wrote: ↑Sat Jan 11, 2020 12:05 am

MarkBour wrote: ↑Fri Jan 10, 2020 11:48 pm ...
It may be that Jupiter is the most influential planet for this, but I note that in the text accompanying the table (see the last link in the APOD caption) one finds the statement:

Due of the gravitational perturbation of the Moon (and to a much lesser extent the planets), Earth's actual distance at perihelion can vary from 0.9831914 AU (147,083,346 km) to 0.9833860 AU (147,112,452 km).

That leads me to believe that the timing of the lunar orbit versus Earth's orbit is the most influential factor causing the variations.

Yes, that could be right. It makes some sense if you look at the slightly scalloped shape of Earth's orbit because of the Moon. It would be interesting to look at the path of the Earth-Moon barycenter rather than just the path of the Earth.
...

• The AstroPixels Perihelion blurb is confusing and wrong:
  1. AstroPixels average (mean) Perihelion estimate leads to confusion.
     As shown in plots, perihelion distances increase at a linear rate of 17.6 km/day (~6,400 km/century). IMO, AstroPixels' average perihelion calculation confuses the interpretation of the variation about the "mean" perihelion as well as suggesting some fundamental importance to the 2.28x multiplier of the Earth's equatorial diameter. AstroPixels chose to define the "mean" as the midpoint perihelion value (essentially the perihelion at year 2000) and, as they stated, the 2.28x multiplier applies to the 29,200-km peak-to-valley (p-v) perihelion range over 200 years from 1900 to 2100. However, from my experience, it's unusual to define a peak-to-valley (p-v) variation about a "mean" when there is a non-random (linear) component buried in the p-v values (i.e when a varying "mean" is not accounted for). Given the linear upward trend of perihelion distance, it's clear the multiplier value will depend on how long the total analysis time interval is. When the perihelion data is corrected by removing the slope of the longer-term systematic drift, the perihelion p-v range is reduced 30% from AstroPixels' data. Therefore, the more useful (and more constant) multiplier is now 1.58x.
     → The take-away is that, as presented, there is nothing special about this parameter, it's only an empirical result for the specific circumstances considered.
      
  2. The contribution from the other planets is significant (>50%). After removing the slopes, component fraction estimates are straight forward over the full 200-year analysis interval. Considering the full 200-yr range:
     • The p-v Perihelion range about the corrected mean ≈20,100 km, NOT 29,200 km
     • With the Moon's orbital component removed, the corrected p-v range in Sun to Earth-Moon Barycenter (EMB) distance
       ≈11,500 km , and
     • The p-v range variation of the Earth-Sun distance due to only the Moon's orbital motion ≈9,800km (2 times Earth-EMB distance at lunar apogee)
       → The fraction of EMB distance variation due to other Solar System bodies (primarily the Sun and Jupiter) is
       ≈11,500 km ÷ [11,500 km + 9,800 km] = 54%.
  3. → From 1900 to 2100, the Earth reaches perihelion about 1 day later roughly every 57 years,
      
  4. →The perihelion is increasing by about 6,400 km per century, and the aphelion is decreasing by the same amount

• All vertical axes are kilometers
• Unless otherwise stated, left and right plots respectively show uncorrected (raw) data and with slopes removed
• Horizons Sun-Earth distances here agree with AstroPixels' perihelia within 5 kilometers

• Horizons (200 years) and AstroPixels (100 years) data are shown.
• Left plot shows AstroPixels' 200-yr 29,204 km p-v variation and the increasing perihelion distance = 0.176 km per day
• Right plot (slope removed) shows the less confusing p-v variation = 20,132 km
  →The more time-independent multiplier = 20,132 km ÷ 12,756 km = 1.58, NOT 2.28

• Shown are the Horizons Sun-to-EMB distances → As mentioned earlier, the contribution from the moon's orbit is subtracted out in these plots.
• Left plot shows the increase distance rate = 0.177 km/day
• Right plot shows the p-v variation over 200 years = 11,503 km The distance variation of the EMB component is significant.
  →Without doubt, the other solar system bodies are driving the increasing perihelion distance over time, and the contribution to 200-yr p-v variation in perihelion distance is at least 50%

• Left plot shows component of Earth's motion, wrt the EMB. Calculated by subtracting the Sun-Earth distance from the Sun-EMB distance at the same time, it is the distance projected onto the Earth-Sun radial axis.
• The 9,800-km p-v is consistent with 2 times the Earth-to-EMB distance at lunar apogee
• Because the asynchronous lunar orbital period wrt to Earth's year, the plot is dominated by aliasing. Interestingly, the upper ~74 peaks over 200 years define an average period ~2.7 years which also happens to be the rough period between Blue Moons (using the 7-Blue Moons every 19 years rule-of-thumb).
   
• Right plot shows the perihelion date increasing about 1 day every 57 years

neufer wrote: ↑Tue Jan 14, 2020 7:55 pm

Ann wrote: ↑Tue Jan 14, 2020 5:46 pm

neufer wrote: ↑Tue Jan 14, 2020 4:25 pm

Neufer designed IR filters for NOAA's GOES Sounder

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So it GOES

Neufer designed IR filters for NOAA's GOES Sounder???

Seious????

As "Seious" as I ever get.

It was the last generation of NOAA's GOES Sounder... with just one left over the Pacific:

http://cimss.ssec.wisc.edu/goes/rt/view ... ct=gsc_b12

So it GOES

TheZuke! wrote: ↑Tue Jan 14, 2020 8:29 pm
Was it GOES-5 that had "its lights burn out"?

I recall meteorologists (early 1990's) referring to a GOES satellite lost its IR capability because a carousel of Infrared lamps (needed to calibrate the camera?) used up all of its lamps.

• They only let me work on the secondary instrument: the atmospheric sounder.

https://en.wikipedia.org/wiki/GOES_5 wrote:
<<The primary instrument carried aboard GOES-5,
the Visible Infrared Spin-Scan Radiometer or VISSR, failed in 1984.>>

https://en.wikipedia.org/wiki/Doublethink wrote:
<<Doublethink is the act of simultaneously accepting two mutually contradictory beliefs as correct, often in distinct social contexts. Doublethink is related to, but differs from, hypocrisy and neutrality. Also related is cognitive dissonance, in which contradictory beliefs cause conflict in one's mind. Doublethink is notable due to a lack of cognitive dissonance—thus the person is completely unaware of any conflict or contradiction.

George Orwell invented the word doublethink (as part of Newspeak) in his dystopian novel Nineteen Eighty-Four. In the novel, its origins within the citizenry is unclear; while it could be partly a product of Big Brother's formal brainwashing programs, the novel explicitly shows people learning doublethink and Newspeak due to peer pressure and a desire to "fit in", or gain status within the Party—to be seen as a loyal Party Member. In the novel, for someone to even recognize—let alone mention—any contradiction within the context of the Party line is akin to blasphemy, and could subject that person to disciplinary action and the instant social disapproval of fellow Party Members.>>

Ann wrote: ↑Tue Jan 14, 2020 5:46 pm

neufer wrote: ↑Tue Jan 14, 2020 4:25 pm

Neufer designed IR filters for NOAA's GOES Sounder

---

TheZuke! wrote: ↑Tue Jan 14, 2020 4:00 pm
How are things in Tralfamadore?
(Not, how were things in Tralfamadore, or how will things be in Tralfamadore.)

So it GOES

Neufer designed IR filters for NOAA's GOES Sounder???

Seious????

neufer wrote: ↑Tue Jan 14, 2020 4:25 pm

Neufer designed IR filters for NOAA's GOES Sounder

---

TheZuke! wrote: ↑Tue Jan 14, 2020 4:00 pm
How are things in Tralfamadore?
(Not, how were things in Tralfamadore, or how will things be in Tralfamadore.)

So it GOES

TheZuke! wrote: ↑Tue Jan 14, 2020 4:00 pm
How are things in Tralfamadore?
(Not, how were things in Tralfamadore, or how will things be in Tralfamadore.)

TheZuke! wrote: ↑Tue Jan 14, 2020 3:15 pm
After thinking about my previous response to neufer's response to my analemma/latest sunrise/earliest sunset question, and Chris Peterson's diagram of the Earth's elliptical orbit, I was wrong to think the elliptical orbit was responsible for the latest sunrise/earliest sunset question. The 23.5 degree tilt of the Earth's axis is (also) the answer to that question. Now, I'm thinking (dangerous, I know) the asymmetry of the analemma depends on the point of view (i.e. one's latitude of the observation). So, please correct me if I'm wrong, the analemma would be symmetrical as observed from the Equator? And larger loop (of the analemma) would be opposite in the Southern Hemisphere?

Chris Peterson wrote: ↑Sat Jan 11, 2020 1:19 pm

twymer wrote: ↑Sat Jan 11, 2020 12:40 pm
maybe it is just me but the photo shows an increase only on the northern pole and not an equal amount on the southern pole - shouldn't the apparent increase be equal on both poles?

The two images could be aligned from the bottom or from the center. Given the small difference in size, I expect the author chose the latter because it makes that difference more apparent. Aligned from the center, it might not even be seen, especially on a small screen.

http://www.marianotomatis.it/blog.php?post=blog/20110715&section=english wrote:

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14 girls

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...or 15 girls?

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Click to play embedded YouTube video.

twymer wrote: ↑Sat Jan 11, 2020 12:40 pm maybe it is just me but the photo shows an increase only on the northern pole and not an equal amount on the southern pole - shouldn't the apparent increase be equal on both poles?

MarkBour wrote: ↑Fri Jan 10, 2020 11:48 pm

Chris Peterson wrote: ↑Thu Jan 09, 2020 10:40 pm

TheOtherBruce wrote: ↑Thu Jan 09, 2020 10:37 pm
Would these variations be due to things like perturbations caused by Jupiter and Saturn? I know the planets' orbits aren't quite completely stable in the long term (millions of years or more), but I didn't realise the changes would be noticeable over really short periods like a century.

Yes. Mostly Jupiter. No naturally occurring system with more than two bodies will produce "perfect" Keplerian orbits.

It may be that Jupiter is the most influential planet for this, but I note that in the text accompanying the table (see the last link in the APOD caption) one finds the statement:

Due of the gravitational perturbation of the Moon (and to a much lesser extent the planets), Earth's actual distance at perihelion can vary from 0.9831914 AU (147,083,346 km) to 0.9833860 AU (147,112,452 km).

That leads me to believe that the timing of the lunar orbit versus Earth's orbit is the most influential factor causing the variations.

TheZuke! wrote: ↑Thu Jan 09, 2020 2:33 pm This has me wondering, although not really on topic with today's APOD.

I don't really understand how the latest sunrise, and earliest sunset are not on the day of the Winter Solstice (or so I've heard),
and conversely; the latest sunset, earliest sunrise and the Summer Solstice. (local time, Northern Hemisphere, in my case.)
Somewhere along the line, I think I read it had to do with the Earth's precession, or with the 23 degree of the Earth's axis, but I don't "see" how it all fits together.

Nor do I "get" why the annalema (sp?) has a larger loop and is not symmetrical.

Thanks to all who will enlighten (no pun intended) me on these subjects.

Chris Peterson wrote: ↑Thu Jan 09, 2020 10:40 pm

TheOtherBruce wrote: ↑Thu Jan 09, 2020 10:37 pm

Chris Peterson wrote: ↑Thu Jan 09, 2020 5:51 pm Not quite. It's not a century in either direction, it's the 21st century. That is, from 2001-2100. And you'll note it's not all that eccentric in behavior, as the variations in perihelion and aphelion distance are extremely small in comparison with the mean distances.

Would these variations be due to things like perturbations caused by Jupiter and Saturn? I know the planets' orbits aren't quite completely stable in the long term (millions of years or more), but I didn't realise the changes would be noticeable over really short periods like a century.

Yes. Mostly Jupiter. No naturally occurring system with more than two bodies will produce "perfect" Keplerian orbits.

Due of the gravitational perturbation of the Moon (and to a much lesser extent the planets), Earth's actual distance at perihelion can vary from 0.9831914 AU (147,083,346 km) to 0.9833860 AU (147,112,452 km).

Chris Peterson wrote: ↑Thu Jan 09, 2020 5:51 pm

MarkBour wrote: ↑Thu Jan 09, 2020 5:38 pm Sometimes I just have to verify the basics of what's being said ... sorry.
If I understood the caption (and the data table in the link), then a few days ago, Earth was the closest to the Sun that it will get for at least a century in either direction. And it was the farthest from the Sun that it will get for at least a century in either direction just last July 4.

So, this year, the Earth is being very eccentric in its behavior. It needs to cut back on the drinking, perhaps.

Not quite. It's not a century in either direction, it's the 21st century. That is, from 2001-2100. And you'll note it's not all that eccentric in behavior, as the variations in perihelion and aphelion distance are extremely small in comparison with the mean distances.

TheOtherBruce wrote: ↑Thu Jan 09, 2020 10:43 pm

Chris Peterson wrote: ↑Thu Jan 09, 2020 10:40 pm Yes. Mostly Jupiter. No naturally occurring system with more than two bodies will produce "perfect" Keplerian orbits.

Until someone manages to solve the general 3-body and n-body problems.

Chris Peterson wrote: ↑Thu Jan 09, 2020 10:40 pm Yes. Mostly Jupiter. No naturally occurring system with more than two bodies will produce "perfect" Keplerian orbits.

TheOtherBruce wrote: ↑Thu Jan 09, 2020 10:37 pm

Chris Peterson wrote: ↑Thu Jan 09, 2020 5:51 pm Not quite. It's not a century in either direction, it's the 21st century. That is, from 2001-2100. And you'll note it's not all that eccentric in behavior, as the variations in perihelion and aphelion distance are extremely small in comparison with the mean distances.

Would these variations be due to things like perturbations caused by Jupiter and Saturn? I know the planets' orbits aren't quite completely stable in the long term (millions of years or more), but I didn't realise the changes would be noticeable over really short periods like a century.

Chris Peterson wrote: ↑Thu Jan 09, 2020 5:51 pm Not quite. It's not a century in either direction, it's the 21st century. That is, from 2001-2100. And you'll note it's not all that eccentric in behavior, as the variations in perihelion and aphelion distance are extremely small in comparison with the mean distances.

orin stepanek wrote: ↑Thu Jan 09, 2020 8:48 pm From what I gather is that the orbit of the Earth is pretty circular! :shock:

TheZuke! wrote: ↑Thu Jan 09, 2020 2:33 pm
This has me wondering, although not really on topic with today's APOD.

I don't really understand how the latest sunrise, and earliest sunset are not on the day of the Winter Solstice (or so I've heard),
and conversely; the latest sunset, earliest sunrise and the Summer Solstice. (local time, Northern Hemisphere, in my case.)

Somewhere along the line, I think I read it had to do with the Earth's precession, or with the 23 degree of the Earth's axis, but I don't "see" how it all fits together.

Nor do I "get" why the annalema (sp?) has a larger loop and is not symmetrical.

• 1) The Earth rotates (west to east) on its axis (at a constant rate) once every 23 hours 56 minutes.
  2) The Sun "revolves" (west to east) around the Earth (at a constant rate of)
  once every 360 (24 hour) days at an angle of 23.5º.

• 1) twice a year (around the equinoxes) the Sun is moving slowly across Longitude lines
  2) twice a year (around the solstices) the Sun is moving rapidly across Longitude lines

• That extra 4 minutes allows the Earth to pass the slow equinox Sun
  such that the noontime Sun slips farther & farther to the West.
  However, that extra 4 minutes doesn't allows the Earth to catch the fast solstice Sun
  such that the noontime Sun slips farther & farther to the East.

• 1) the winter solstice Sun "revolve" extra fast
  2) and the summer solstice Sun "revolve" not quite so fast.