Spencer’s posited 1-2% cloud cover variation found

Bill says:
April 4, 2012 at 2:24 pm
“Sounds very interesting. As with most climate studies, the error bars are probably huge. -1.6% +/- what?”
They use the word “significant” several times; meaning, what they observe is unlikely to happen by chance given the expected error distribution.

Hardly surprising: pressures have been steadily rising over the Gobi Desert in China since 1960 and temperatures have been decreasing there during the same period figure 14.47 page 382 Leroux, Dynamic Analysis of Weather and Climate 2010 Springer/Praxis. This confirms once again the insightful analysis by the late French climatologist and of course shows the increase in Mobile Polar Highs reaching deeper southward, hardly a signature of global warming…

Just curious, but which measure of “solar activity” are you using to make that statement Leif? And when you state the lack of any cosmic ray trend, which measurement are you referring to? Those aren’t loaded questions, I honestly don’t know the answers and would like to be able to look at the data you are referring to. My reason for asking is because I always thought that cosmic rays were more affected by variations in the strength of the solar wind than by sunspot activity, and I wasn’t sure if there was a good dataset or set of proxies for solar wind going back that far. I also don’t know if the solar wind directly tracks sunspot activity or whether it deviates from direct correlation. With regard to cosmic ray trends, is there a long enough data set from multiple latitudes to determine if there is a difference in trend between higher and lower latitudes?

These analyses do not
support the speculation that the decreasing trend of cloud cover in regions with higher AOD should be larger than that in mildly polluted regions due to stronger aerosol obscuring effect on ground observation of cloud cover and stronger radiative effect in polluted regions.
A peculiar hypothesis. Its well established that aerosols seed clouds (and its a large effect) so one would expect higher cloud cover levels where AOD is high. I’d be surprised if the obscuring ground observation effect of aerosols was larger.
Otherwise its unfortunate that they do not relate cloud cover changes to aerosol changes. I would not make the assumption that high aerosol areas are areas where aerosol levels have increased over the period of the study. Aerosol level changes in China is a complex picture with likely decreasing particulates and black carbon, while SO2/NO2 has increased.
The aerosol picture in most of the rest of the world is very different to China. So I wouldn’t draw any global conclusions from this.

Leif Svalgaard says: April 4, 2012 at 2:40 pm
“Solar activity was largest in the middle of the 20th century and has since basically decreased”
As usually, Leif trys to mislead the readers of this blog.
The truth is that there is a debate about what the sun did during the last 50 years. There is an agreement that the sun dereased its activity from 1940-1950 to 1970. From 1970 to 2000 solar acticity is claimed by PMODto have been remained constant or slighly decreased.
However the ACRIM group claims otherwise and the solar irradiance increased from 1970 to 2000, and now is decreasing.
Everything is clearly explained here
http://acrim.com/TSI%20Monitoring.htm
Leif knows very well that there exists a controversy about this issue, but he is not interested in fairly present the issues. Leif also forget to mention that PMOD composite is based on a manipulation of some satellite records. See here
http://climatechange.thinkaboutit.eu/scripts/tinymce/jscripts/tiny_mce/plugins/imagemanager/files/Kremlik/Hoyt.jpg
The above finding about a cloud cover decreasing from 1970 to 2000 due to a 60-year astronomical/solar during its warming phase is perfectly consistent with the findings of my papers where also the cloud connection is discussed. For example
N. Scafetta, “A shared frequency set between the historical mid-latitude aurora records and the global surface temperature” Journal of Atmospheric and Solar-Terrestrial Physics 74, 145-163 (2011). DOI: 10.1016/j.jastp.2011.10.013.
N. Scafetta, “Multi-scale harmonic model for solar and climate cyclical variation throughout the Holocene based on Jupiter-Saturn tidal frequencies plus the 11-year solar dynamo cycle.” Journal of Atmospheric and Solar-Terrestrial Physics in press (2012).
So, we have more data contraddicting AGW advocates and Leif.

Time to revisit this:
http://wattsupwiththat.com/2007/10/17/earths-albedo-tells-a-interesting-story/
This was 2007. It has further increased or remained about the same (from what I’ve found) in the meantime. The figure is key — note the relative forcing compared to the combined GHG forcing (whatever “forcing” ultimately means in a detailed balance equation). Personally, I prefer the variation in the greybody temperature, which takes into account albedo.
To Leif:
IIRC, both the solar magnetic field and the Earth’s magnetic field fluctuate, and both affect cosmic ray counts. Polar stations e.g. Oulu do show significant increases in neutron counts since e.g. the early 80’s (~25%), do they not (which is more likely to be associated with solar fields). But as the Earth’s magnetic pole wanders and the Earth’s field fluctuates, might that not modulate cosmic ray counts as well, quite possibly in tropical regions with a differential impact on climate?
Either way, whatever the cause the Earth’s albedo appears to have significantly increased over the last 15 years. Given a baseline albedo in the ballpark of 0.3, 7% is around 0.02 variation from 1997 to the present. That corresponds to roughly 2 degrees K variation in the baseline greybody temperature before the GHE goes into effect to raise it. Note also that the decrease in albedo from 1985-1986 to 1997 almost precisely corresponds to the timeframe (and, lagged, the magnitude) of the “unexplained” temperature increase of that period, the part that was attributed to climate sensitivity on top of the GHE increase (which by itself is much smaller).
This explains — or “can” explain — why even serious climate scientists might have been mistaken about climate sensitivity. The very period where the IPCC was “stimulated” by Mann’s hockey stick in 1998 on began right at the end of a period where the albedo had dropped by 10 percent! over fifteen or twenty years, a drop that was interpreted (correctly or not) as being due to climate sensitivity — an increase in atmospheric humidity and decrease in cloud cover due to increase greenhouse forcing. According to this, however, this process should continue unabated as long as GHGs increase, leading to egregious estimates of the feedback. Note that 10% corresponds to almost 3K increased forcing all by itself (but we didn’t see all of it because it is lagged by years to decades).
However, the subsequent increase in albedo by 7% (which we can also expect to be lagged by years to decades in its effect on mean temperature) is completely unexplainable in terms of this forcing model. It directly confounds the actual physical basis of the presumed high climate sensitivity, and worse — suggests that by far the majority of the late 20th century warming was due to modulation of albedo, not modulation of CO_2.
Svensmark provides an appealing hypothesis to explain why there appears to be some connection between solar state and global temperature. However, one does not need to engage in this debate to look at the albedo data and connect it to expected global temperature. Whatever the mechanism responsible for the modulation, the modulation exists, behold it. It is not only significant, it is many times larger than the expected effect resulting from anthropogenic modulation of CO_2. It is, in fact, one of the relatively few mechanisms proposed (aside from chaos and self-organization of major heat transport mechanisms) that can explain the observed variability of global temperatures over the Holocene.
In a sane Universe, physicists and climatologists would be busting their butts to understand the 10% variability in albedo, given its primary role in thermoregulation. Instead it happens, and then everybody forgets it. It is the omitted variable — one cannot even argue that it should or shouldn’t be present, and using a constant value over decadal timescales is manifestly a mistake. Garbage in, garbage out.
rgb

Leif says “… In spite of this, the cosmic ray intensity has not shown any trend since reliable measurements began in the early 1950s …”
Any trend is a large and unknown list. Is is just that no one has been able to find a trend so far? Has someone looked for a trend of CRI integrated over solar cycles?

Dr. Spencer, if you haven’t seen this, you should check it out. Damped summer warming accompanied with cloud cover increase over Eurasia from 1982 to 2009 It’s a new paper out in Environmental Research Letters……
I just finished reading it and posting on my blog, when I popped my head up and see your conversation. It’s really a pretty lame paper……. they do make a huge finding though…… the areas where clouds are in the summertime correlates well with “dampened warming”. And, it seems things get hotter without them as well!!! This study was only conducted in Eurasia…… no word about how clouds would effect the rest of the world’s summertime temps. …….

Robert Brown says:
April 4, 2012 at 4:36 pm
Time to revisit this:
http://wattsupwiththat.com/2007/10/17/earths-albedo-tells-a-interesting-story/
The Earthshine project continues. This link has a graph up to 2008 which shows the albedo increase from around 1997 continues.
http://www.bbso.njit.edu/Research/EarthShine/
The pre-1997 decline in albedo can be explained by decreasing global anthropogenic aerosol levels (clouds seeded by them), but the post 1997 rise is something of a puzzle. A possible explanation is that while global aerosol levels were steady during this period. They increased over tropical and subtropical Asia, while decreasing at higher latitudes. Resulting in more tropical and subtropical clouds and more reflected sunlight from lower latitudes.

I think the theory expects a decrease in cloud cover.
The sunlight reflecting nature of cloud cover Albedo (about -53.0 W/m2) outweighs the back-radiation greenhouse effect of clouds (about +32.0 W/m2).
The theory is based on a feedback effect of +1.0 W/m2 per 1.0C increase in temperatures (signalling that cloud cover will decline by up to 5% given its net impact of -21.0 W/m2 even though humidity is expected to increase by 7.0% per 1.0C increase in temperatures and the climate modelers sometimes say they expect a 2.0% increase in cloud cover.
In reality, cloud cover is the make or break feedback effect. Humidity is based on the reasonably solid Classius Clayperon relation while cloud cover is just a guess at best.
If the cloud cover feedback is -1.0 W/m2/1.0C rather than +1.0 W/m2/C, then the CO2 sensitivity falls to 1.5C or so per doubling. The multiplier effect. Technically, I’ve always assumed this feedback effect has been tuned to deliver 3.0C per doubling since the climate models cannot actually determine what feedback clouds will deliver. +/- 1.0 W/m2/1.0C is a make or break factor. They picked 3.0C long ago and they are sticking with it.
(And humidity is not actually increasing according to the Classius Clayperon equations either. It is as flat as a board over the long term with the ENSO running its +/- level apparently).
http://img577.imageshack.us/img577/4600/watervapouripccvsreanal.png
http://img52.imageshack.us/img52/5716/ensotempsvstcwvnov11.png

Robert Brown wrote (April 4, 2012 at 4:36 pm): “In a sane Universe, physicists and climatologists would be busting their butts to understand the 10% variability in albedo, given its primary role in thermoregulation. Instead it happens, and then everybody forgets it. It is the omitted variable — one cannot even argue that it should or shouldn’t be present, and using a constant value over decadal timescales is manifestly a mistake. Garbage in, garbage out.”
Piers Corbyn (late 2011 in Germany):

Bill Illis’ (April 4, 2012 at 6:21 pm) water vapor / ENSO graph:
http://img52.imageshack.us/img52/5716/ensotempsvstcwvnov11.png
Thanks for relentlessly reminding everyone Bill.
“Apart from all other reasons, the parameters of the geoid depend on the distribution of water over the planetary surface.” — N.S. Sidorenkov

To many:
http://www.leif.org/research/The%20long-term%20variation%20of%20solar%20activity.pdf slide 18 [the oval] shows solar activity. Slide 29 shows that PMOD was too low lately and that there is no difference between minima in TSI. The solar microwave flux shows the same: http://www.leif.org/research/Solar-Microwaves-at-23-24-Minimum.pdf . http://www.leif.org/research/Neutron-Monitors-Real-Time.htm [last slide] look at Hermanus [the red curve] shows that there has been no trend in cosmic rays.

@angelpbj: Thanks.
A good reading that helps understand the various observations:
http://ddata.over-blog.com/xxxyyy/2/32/25/79/Leroux-Global-and-Planetary-Change-1993.pdf

“This finding is in direct contradiction to the theory of man-made global warming which presumes that warming allegedly from CO2 ‘should’ cause an increase in water vapor and cloudiness. ”
Based on this ridiculous assertion alone one can only assume you didn’t bother reading the paper or perhaps you just decided to be a little bit deceitful and ignore the section that mentioned that while cloud cover decreased over China, cloud cover increased over, hang on, I’ll just cut and paste directly so there’s no mistake…”These studies have suggested total cloud cover has increased over Europe (Henderson-Sellers, 1986), Australia (Jones and Henderson-Sellers, 1992), Canada (Milewska, 2004), the United States (Sun and Groisman, 2004; Dai et al., 2006), the Former Soviet Union (Sun and Groisman, 2000), and the northern Indian Ocean (Norris, 2001).”
Hmmm, thats a fair chunk of the rest of the world.

Last month’s flurry of the solar CMEs resulting in a 14% Forbush decrease, appears to confirm the Svensmark’s hypothesis, with a short term fall in the cloudiness approaching 7%.
http://www.vukcevic.talktalk.net/Ap-Cl.htm

Robert Brown says: “
To Leif:
IIRC, both the solar magnetic field and the Earth’s magnetic field fluctuate, and both affect cosmic ray counts. Polar stations e.g. Oulu do show significant increases in neutron counts since e.g. the early 80′s (~25%), do they not (which is more likely to be associated with solar fields). But as the Earth’s magnetic pole wanders and the Earth’s field fluctuates, might that not modulate cosmic ray counts as well, quite possibly in tropical regions with a differential impact on climate?
Robert – an interesting suggestion that fits with the comments and graphics of Vukcivic on this subject. These cover the fluctuating bands of plasma that follow the magnetic field lines where the magnetic and geographic equators cross – resulting from an interaction of the sub-tropical jets with the equatorial magnetic field. http://www.vukcevic.talktalk.net/LFC20.htm At places brighter spots of plasma are concentrated, most of which are associated with thunderstorms but their positions vary with GMF flux. As vukcevic states:
“As intensity of the GMF changes with time, so it will position of the magnetic Equator (and importantly) with it location of the plasma bands. One measure of this movement is the location of equatorial crossing. The equatorial crossing has moved east-wards during the last four centuries. “
My question is whether these differences in plasma concentration along the magnetic/geographic equator offer an explanation for the differences between the studies of Lindzen and Lin concerning the “iris effect” and could this be by variable modulation of cosmic rays by this plasma belt?
http://www-eaps.mit.edu/faculty/lindzen/236-Lindzen-Choi-2011.pdf
http://trmm.chpc.utah.edu/paper/liuietiali2008ijgr.pdf

u.k.(us) says:
April 4, 2012 at 5:36 pm
” Don’t forget the early spring in the U.S. midwest; the trees, shrubs and plants are nearly in full bloom, one month early.
With all that shade, the ground warms slower.”
Sure, but where do you start? With all that shade the preceding winter, the ground cools slower too. The nights especially are much warmer under a cloud cover.

peter azlac says:
April 5, 2012 at 1:28 am
………….
Thanks for highlighting my effots.
Geomagnetic equator’s position is determined by magnetic strength of two poles and their geographic location. The ‘south’ pole is relatively strait forward, its strength is falling off at a steady rate and its movement is simple.
Variability in the North hemisphere is more complex; there is a bifurcation of the field with the ‘apparent pole’ wandering around, as the balance between two extremities changes. There is strong possibility that this balance is altered by impact of the geomagnetic storms due to the solar coronal mass ejections – the CMEs and not related to GCRs. http://www.vukcevic.talktalk.net/Tromso.htm result: the ‘north’ magnetic field intensity correlates well with the long term changes in the solar activity.
‘Speculative’ info at: http://www.vukcevic.talktalk.net/MF.htm

The standardized method of temperature measurement (Stevenson screen) is quite sensitive to ground radiation (as readers of this site would know). One therefore needs to ask the question; would the same temperature rise be evident if the measurements were taken higher above the ground? (ie 10 or 20m). I am not implying that there’s no connection between CC and LT temperature, merely pointing out the limitations of ground based measurements.

I think that this paper could possibly prove the ACRIM composite to be right, and the PMOD composite to be wrong.
This paper published in 2001 shows a significant link between direct solar variations and cloud cover changes.
http://www.agu.org/pubs/crossref/2001/2000GL012659.shtml
So if Cloud Cover is decreasing, and the trend is statistically significant, couldn’t this verify the ACRIM composite which shows a statistically significant trend upward between Solar Cycle minimas over the last 30 years?

Tom_R says:
April 4, 2012 at 9:47 pm
Leif, IIRC, it was only one class of cosmic radiation that was supposed to promote cloud formation. Does the neutron monitor discriminate between different types of cosmic rays?
No, but the Earth’s magnetic field does: The low energy GCRs that are not supposed to be active do not reach lower latitudes. The high-energy GCRs are much less modulated by solar activity.
Crispin in Johannesburg says:
April 5, 2012 at 12:58 am
The demonstration of the CR effect is I think undisputed, right? No one is claiming anymore that the physics are not real.
The efficiency of the process seems much too low to have any effect. More importantly, the claimed correlations do not hold up.
The heliosphere is the diverter of GCR. You mentioned CR, not GCR. Solar CR and GCR are not the same thing.
When speaking about cosmic rays one always mean the galactic ones. The solar ones are called Solar Energetic Particles and are of much lower energy and abundance [thus should have no climate effect].
Does the heliosphere size match the ‘solar activity’ and on what basis is this connect/disconnect made? In other words what constitutes ‘solar activity’.
Short answer is ‘yes’. Solar activity is the occurrence of magnetic fields and their various side effects.
It is going to be pretty tough for someone to prove that CR and GCR are not causing cloud formation as the evidence is pretty clear they do
That is wishful thinking. The evidence is too weak to be taken seriously.
peter azlac says:
April 5, 2012 at 1:28 am
But as the Earth’s magnetic pole wanders and the Earth’s field fluctuates, might that not modulate cosmic ray counts as well, quite possibly in tropical regions with a differential impact on climate?
Yes, and that modulation is much larger than the solar modulation.
As vukcevic states:
Most of what he says is pure nonsense. [and he is proud of it…]
tallbloke says:
April 5, 2012 at 2:41 am
it’s easy to see that solar activity was cumulatively increasing above the long term average since 1749 all the way from ~1934 to ~2003.
Slide 2 of http://www.leif.org/research/SHINE-2011-The-Forgotten-Sun.pdf shows solar activity since 1840 [sunspot number, geomagnetic activity, and the magnetic field in the Heliosphere]. As you can see, activity was low broadly around 1900 and 2010 and high in between. If the Sun modulates climate in any significant way, the climate now should resemble that of the early 1900s. Does it?

The decrease in Cloud Cover that this new paper found is even more dramatic than Dr. Spencer’s 1-2% variations in Cloud Cover figure. It finds a decrease in Cloud Cover that is -1.6% PER DECADE for about 5 decades, which suggests that Cloud Cover may have an even larger role on Climate Change than even Dr. Spencer suggests, taking this study verbatim.
This could have significant implications for Climate Change, if the study’s results are to be correct.
Just wanted to throw that out there.

Snowlover123 says:
April 5, 2012 at 5:52 am
So if Cloud Cover is decreasing, and the trend is statistically significant, couldn’t this verify the ACRIM composite which shows a statistically significant trend upward between Solar Cycle minimas over the last 30 years?
You are putting the cart in front of the horse here. There is no such trend.
http://lasp.colorado.edu/sorce/news/2011ScienceMeeting/docs/presentations/1g_Schmutz_SORCE_13.9.11.pdf slides 31 and 33:
“Observed data do not support a measureable TSI trend between the minima in 1996 and 2008 !”

Snowlover123 says:
April 5, 2012 at 5:52 am
ACRIM composite which shows a statistically significant trend upward between Solar Cycle minimas over the last 30 years?
Slide 17 of http://lasp.colorado.edu/sorce/news/2011ScienceMeeting/docs/presentations/1d_Willson_LASP_TRF%20diagnostic_for_ACRIM3_implications_TSI%20database.pdf
There is no such trend.

If the Sun modulates climate in any significant way, the climate now should resemble that of the early 1900s. Does it?
Or rather, since the Ocean is a buffer with timescales that are decades to centuries long, the climate should barely have started changing back to what it looked like in the late 1800s. And perhaps it has. We won’t know for sure for up to 1-3 more solar cycles, will we?
It’s not like temperatures instantly spiked up in association with solar state, is it? Decadal lapses, or even longer, are absolutely to be expected when the small variations in net insolation have to heat up a kilometer or so of the ocean that covers 70% of the planet to make a significant secular change in average temperature.
rgb

Leif Svalgaard says:
April 5, 2012 at 8:32 am
And that energy is extremely small [like 1000 trillion times smaller]
should be a million times smaller. sorry for my error. [too many zeroes 🙂 ]

Leif Svalgaard says:
If the Sun modulates climate in any significant way, the climate now should resemble that of the early 1900s.
Absolute nonsense. That is like saying that if day length modulates climate in any significant way, then March temperatures should resemble those of September. It isn’t just (one of the many) instantaneous inputs to the system that define a system’s state, it is also the initial conditions.
Leif understands this. For him to make these silly arguments belies a distinct lack of … well, lets just leave it at “objectivity.”

Robert Brown says:
April 5, 2012 at 8:06 am
the climate should barely have started changing back to what it looked like in the late 1800s.
And in the late 1800s it had barely started changing back to what it looked like in the late 1700s at which time it had just barely started changing back to what it looked like in the late 1600s, at which time it had barely…

Leif Svalgaard says:
April 5, 2012 at 7:00 am
You are putting the cart in front of the horse here. There is no such trend.
slides 31 and 33:
“Observed data do not support a measureable TSI trend between the minima in 1996 and 2008 !”
———————————————————————–
That’s interesting, considering the new paper stops in 2005, and you have data continuing all the way to 2008, to try and somehow disprove the data that ended in 2005.

Snowlover123 says:
April 5, 2012 at 10:30 am
That’s interesting, considering the new paper stops in 2005, and you have data continuing all the way to 2008, to try and somehow disprove the data that ended in 2005.
———————–
That was terrible wording on my part.
The new paper’s Cloud data stops in 2005, and you have TSI data going all the way to 2008 to somehow disprove the solar connection with the Cloud Cover decrease.

Snowlover123 says:
April 5, 2012 at 10:36 am
The new paper’s Cloud data stops in 2005, and you have TSI data going all the way to 2008 to somehow disprove the solar connection with the Cloud Cover decrease.
No, I have solar data going all the way back three hundred years showing no convincing solar connection with climate. Now, you may want to respond to people who claim that there is a decade/century long time lag between the sun and climate. Or are you one of those who believe there is no lag?

Despite last month’s Forbush confirming Svensmark’s hypothesis (Dr. Svalgaard failed to notice it, accidentally of course)
http://www.vukcevic.talktalk.net/Ap-Cl.htm
GCRs may not be sufficiently potent to explain major temperature oscillations (Roman WP = RWP, MWP, LIA and 20th century WP = TCWP).
The alternative idea as condensed in here
http://www.vukcevic.talktalk.net/GTCa.htm
will get some traction when all the alternatives are thoroughly and systematically trashed by experts from the opposing camps.

Leif Svalgaard says:
April 5, 2012 at 10:56 am
“there is no observational evidence for any persistent trend in TSI at mimina.”
Does minimal Sun Spot number correlate with Northern hemispherical minimum temperatures?

Leif says… No, I have solar data going all the way back three hundred years showing no convincing solar connection with climate.
————————————————————–
That’s interesting, considering the sun is the reason why the temperature rises during the day, and it is the energy supply of everything on Earth, so I would assume it would have something to do with the climate of Earth.

vukcevic says:
April 5, 2012 at 11:38 am
I suppose that forbidden word has it’s roll to play too…
_______________________________
You might like to look at the discussion of Dr. Nicola Scafetta’s work http://wattsupwiththat.com/tag/nicola-scafetta/

According to William Gray, PhD, Professor Emeritus of Atmospheric Sciences, CSU:
“GCMs assume that an increase in atmospheric CO2 will cause weak global warming and an
increase in global precipitation that will lead to a large increase in upper-level water vapor
and cloudiness. They simulate that this increase in water vapor and cloudiness will block
large amounts of infrared radiation emitted to space. New observations by satellite and
reanalysis data, however, do not support these GCM assumptions. The global warming that
has occurred since the mid-1970s has been associated with a modest decrease of global
upper tropospheric water vapor and an increase of Outgoing Longwave Radiation (OLR).
These measurements contradict model predictions.”
http://heartland.org/sites/all/modules/custom/heartland_migration/files/pdfs/24891.pdf
Leif:
Could change in solar activity account for Mars warming 4 times faster than Earth over the past 20 years?
http://hockeyschtick.blogspot.com/2010/05/whoopsmars-has-warmed-4-times-more-than.html
Or warming on Jupiter, Pluto, Neptune, Triton, etc.?

barry says:
April 5, 2012 at 8:29 pm
barry don’t be an ass.

Basically what I have suggested is in line with procedures used In detecting extrasolar planets orbiting stars. Anyone who believes that planets do not have an effect on the star they orbit are missing out on a lot of progress made recently in astronomy. At the moment I do think that the solar cycle is caused by the outer planets orbiting the sun, I think the math is there, I think the suns variability does indeed have an effect on the earths temperature. And more importantly I think that it would be a useful tool for meteorologists to understand this process and tie this Solar cycle down.
Even the fact that the term ‘solar cycle’ should be a clue to it’s mathematical nature, The heliocentric configuration of the outer planets are causing the solar cycle, when the solar cycle is high over successive decades this produces overall a higher energy budget reaching the inner planets. And when the solar cycle is lower over successive decades it produces a lower overall energy budget reaching the inner planets. the interesting thing about the outer planets is that we can very accurately predict their future positions and therefor will be able to predict future heliocentric configuration and it’s effect on the sun. it means the solar cycle can be predicted with incredible accuracy decades into the future. wouldn’t this be important?
Some so-called scientists need to put down that latest book they’re promoting and do some work.

Happy easter, Sparks.
As a purely mathematic exercise, the ‘harmonics’ of orbital patterns throughout the solar system offer so much variety that there will probably be more than one set of frequencies that fit with the solar cycle/s. How would you distinguish the *true* frequencies from other candidates?

barry says:
April 6, 2012 at 11:55 am
“As a purely [mathematical] exercise, the ‘harmonics’ of orbital patterns throughout the solar system offer so much variety”
barry, This is called eccentricity! where The orbital eccentricity of an astronomical body is the amount by which its orbit deviates from a perfect circle. It is also a measurable mathematical property. I wouldn’t go down the road of statistically Analysing planetary orbital deviations.(and it is not what I was suggesting)
“…that there will probably be more than one set of frequencies that fit with the solar cycle/s. How would you distinguish the *true* frequencies from other candidates?”
I would begin by observing the heliocentric configuration of the outer planetary orbital mass. I don’t understand what ‘frequencies’ you are referring to or in what context you mean.