On The AMO+PDO Dataset

I would think that a new PDO* would be useful, simply because it would be clean, and comparable to the AMO, not that they should be combined, just that having the equivalent information for the Pacific is necessary to get the fill picture. As you show in figure 10, there is information there, even if there is a lead or a lag effect.

If AMO is simply detrended SST then what support is there for calling it an “oscillation?” Shall I detrend the GISS US chart and call it the “US Multidecadal Oscillation?” just because I don’t know what caused the sine wave but wish to discount AGW claims? Can more cycles be reconstructed further back than a century?

not being an expert, but AMO and PDO are not -mutually exclusive.But there are so many other variables
combining the two in one dataset isn’t a good idea.
Bob’s right…

Request:
Graph of this [ http://i56.tinypic.com/xoibyx.jpg ] format for North Pacific [i.e. showing the variation between datasets].

Jeez, you’re awfully free with other people’s money.

While the signal produced from a combination of data sets may or may not be additive, the error components are ALWAYS additive.
db..

Its also worth pointing out that linear de-trending over century periods is of limited use if forcings were not linearly changing over the period in question, at least if you are trying to extract the unforced variability.
I blogged about this awhile back (though as Bob mentions, using different SST series can produce different results): http://rankexploits.com/musings/2011/the-atlantic-multidecadal-oscillation-and-modern-warming/

You can, indeed, form a model from two discrete datasets that are not, themselves, directly comparable or ‘addable’.
Particularly when you’re flailing around with the explicit goal of an empirical model.
If I’m studying ‘failure modes of Joe’s bookcases’ through the question “How much weight can it support?” and decide the two crucial variables are “What day of the week was it constructed on?” and “Did it get wet?”, I can, arrive at a functional predictive model. Without having the foggiest notion – or even a completely erroneous notion – of what the underlying physics or chemistry is – pretty much identically to how pre-Kepler/Copernicus models -did- actually do a decent job of predicting the locations of the planets. While being fundamentally wrong.
You can’t “add” days of the week to wetness – they’re literally completely different things. The -reasoning- behind some of the items in an empirical model might be completely hidden, like perhaps Joe buys his wood in different places on different days of the week.
The crucial test of an empirical model is through predictive tests on unexposed data.

Ric Werme (June 8, 2011 at 1:30 pm)
“Does it make sense to look at non-detrended Pacific/Atlantic data and compare that to non-detrended temperature data?”
Finally, common sense. [Note: Not all definitions of AMO include detrending. It’s easy to make a strong case against linear detrending.]
–
Bob, there’s much to discuss, but before we get started, we really do need the comparative graph of North Pacific SST across different data sources to put things in the same perspective as your AMO framing.
Best Regards.

jeez says: June 8, 2011 at 12:42 pm

Since there’s the paywall on the paper, I can’t confirm if Wyatt et al used the related SST data to create their AMO and PDO data, so the following portion of this discussion (Figures 8 and 9) is for example only.
Why not just pay the 35 dollars and make this a complete article and not leave suppositions in place? It seems a minor expense …

I case you didn’t realize it we’re not just talking about $35. This is just one example of a $35 paper for sale. From following the links in WUWT, I have encountered at least 10 or 15 pay-walled papers in the past month. Would I like to be able to read these articles, you betcha! But that would have cost me between $350 to $525. And there is still the economic downturn to contend with. Plus [self imposed long snip] expenses!
Since you seem to be so free with other peoples’ money, I can only assume that you are a liberal and have never had to manage your own limited funds.
jeez, prove me wrong by offering to pay for all of us to have access to these papers!

Bob brings up fair points. But perhaps I can offer more clarity on the WKT paper.
The figure to which Bob refers – showing NHT regressed onto predictors AMO and PDO – was used in the posters, not in the paper. A number of weighted combinations of reconstructed components of the “stadium wave” climate signal could be combined in a variety of proportions to yield similar results. This does not diminish the observation that the trend of combined AMO and PDO values aligns closely with that of NHT.
It is important to note that reconstructed components (RCs) of this multivariate data set, generated through multi-channel singular spectrum analysis (M-SSA), represent the climate signal shared by all indices involved; these RCs represent a pair of leading modes of climate variability that propagates through the set of indices. The modes, themselves, represent co-variability among the indices of the data set. The M-SSA method applied here does not involve isolating each index and smoothing it. Instead, a collection of indices are considered together. In this specific application, M-SSA identifies the signal shared among all indices. M-SSA is a type of EOF analysis. EOF analysis identifies spatial patterns that co-occur at a zero-lag. On the other hand, M-SSA identifies spatial patterns that co-occur at non-zero lags – in other words, it is useful for identifying propagating signals of spatio-temporal variability.
Normalized RCs of AMO and PDO have a high fractional variance of the signal identified in this study. The combined influences of the signals in AMO and PDO can be seen in the NHT, which also possesses a high fractional variance of the signal.
The paper makes no conclusion on global warming; the conclusion is solely regarding a multidecadally varying climate signal shared among a collection of indices, a signal that propagates across the hemisphere. A warm (cool) Atlantic triggers a cascade of polarity changes in participating teleconnections, resulting in a cooling (warming) hemispheric climate signal about 30 years later – the “stadium wave”. The periodicity of changes in the North Atlantic AMO appears to be largely governed by the Atlantic sector of the meridional overturning circulation (AMOC). As the cascade of atmospheric and lagged oceanic teleconnections converts a warm (cool)-Atlantic-born signal into a Pacific cooling (warming) signal, the AMOC is re-configuring the Atlantic SST signature. By the time the Pacific begins to cool (warm) as a result of an initially warm (cool) North Atlantic, the North Atlantic, itself, is cooling (warming). The conflated result of temperature profiles within each oceanic basin is a cooling (warming) hemisphere, poised to reverse trend as a result of the once-again-cooling (warming) North Atlantic SSTs (which will ultimately lead to a warming (cooling) climate). No conclusion on what exactly causes the NHT is given, just that it strongly coincides with the trends of combined PDO and AMO. At the paper’s end, a lengthy discussion is devoted to possible mechanisms underlying the stadium-wave dynamics, based on numerous model-based and observational studies.
While the article does not address global warming, other than to underscore the importance of discriminating between climate-change that is natural and that which is of anthropogenic origin, this article’s findings may be misconstrued to support one view over another. To interpret it in this way is to loose a very powerful message: that multidecadal climate variability, whose pace of variability is strongly governed by the AMOC, appears within an interconnected network of climate indices, the interaction of which results in a negative-feedback cascade of teleconnections. The study covers only the 20th century – the rigorous statistical methods used making it unlikely that this low-frequency alignment would appear in various regional climate time series purely at random. The authors suggest future study will address evidence of the stadium wave in past climate and in modeled scenarios.

Marcia Wyatt:

To interpret it in this way is to loose a very powerful message: that multidecadal climate variability, whose pace of variability is strongly governed by the AMOC, appears within an interconnected network of climate indices, the interaction of which results in a negative-feedback cascade of teleconnections.

Indeed. The detection of teleconnections is after all what “global climate science” is attempting to do. Noting existence is the first step to winkling out the nature of the linkage.
BUT! It’s “lose”, not “loose”, you goose!
😉 ;p

I received the sort of replies I was expecting. I hesitate to play a game of one-up-manship, but it is unfortunately called for.
I have donated to this site multiple times.
I offered to cover Anthony’s plane flight to the NCDC in 2008, but he declined.
I am in debt and have been for many years. This does not stop me from donating money or hundreds of hours to items of importance. I have a blue collar job.
I often try to get this community to step up its game, to become more solid, to be stronger, to produce better material, to be more credible. The quote I noted above was singularly unimpressive for an article written for thousands of readers. It demonstrated a lack of commitment. I called it out.
The person who above who decided to identify me as a “liberal”, (I think he means limousine liberal to be exact), demonstrates the sloppy, small-minded, thinking and knee jerk political reaction I abhor, and which greatly and I do mean greatly, diminishes the credibility of this community. You guys can do better. I want you to do better.
Bob, perhaps it doesn’t matter whether you know exactly what they used, however, the way you wrote the paragraph I quoted made it sound as if it did and gave the impression that you ran to within a foot of the goal, then wandered off for want of the price of a round of drinks.

Having noted the deficiencies noted above about the PDO, the ocean cycles explain more than half of the global temperature changes (and this happens on as little as a monthly scale – we do not need to use smoothing functions and 20 year moving averages – the global climate is impacted within a week to as much as 3 months from changes in the ocean cycles).
After accounting for the changes, there is a still a warming trend left-over which could be described as close to a linear 0.053C per decade (less than half of that predicted by global warming theory) or, more accurately, it is function of CO2 or the climate forcings as Zeke mentioned above (again it is still less than half of that predicted).
Having said that, it does look like this paper might be quite interesting. Wyatt appears to have used all kinds of different ocean cycle comparisons. We will have to wait until a free version shows up. It is taking less and less time now for pay-walled papers to be put up on the internet (I’ve been using the “QuickView” function in Google lately which is getting by many pay-walls – I’m not sure if they are aware of this – but not for this one so far).

Bob
What is the accuracy and confidence level of the PDO+AMO vs actual historical temperature data? If the accuracy is above 90% and the confidence level is +/- 0.1 degree C, we should use it!
Just because you currently don’t understand why it works, or think you know why it shouldn’t work, does not negate the value of the tool. In 18th century England, a very astute man found that grain prices varied inversely with sun spot numbers. He didn’t know why, but he was still able to benefit from that data! So should we, especially if it helps us prevent the destruction of our economies by the Eco-terrorists!
Bull

Bob
But the NPI is just the inverse PDO and some ‘noise’ http://virakkraft.com/PDO-NPI.png
So, NINO3.4 SST – PDO = NPI and PDO = -NPI means NINO3.4 SST = 0, which I guess is true on a decadal scale 🙂

Minor problem with a new PDO…the PDO is not spatially similar to the AMO. The PDO is an oscialltion with significant logitudinal shape…a warm PDO means the tropical Pacific AND EASTERN RETURN CURRENTS are above normal. Your finding that the PDO index and NPAC SST are inversely related is not remotely surprising to anyone who knows what the PDO actually looks like. A warm PDO implies COLD waters in the Gulf of Alaska and warm around that cold bubble.
And it does NOT follow that a cold bubble in the NPAC should produce cold planetary temperatures. I think you’re actually missing the point when it comes to combining the PDO’s influence on temperature with the AMO’s influence. The theory goes that a warm PDO comes accompanied with increased low cloud cover in the NPAC (insulating the polar regions from heat loss to space while simultaneously cooling the NPAC). The AMO is just a region-wide warming on a multi-decadal scale…it has no longitudinal shape…its’ influence on planetary temperatures is obvious and directly linear. The two indices are not the same…they probably shouldn’t be combined directly..but it does not follow that if a warm AMO = increased temps a cold bubble in the NPAC should cause decreased temps.
The necessary analysis would be to determine the non-linear relationship between planetary temperature and each index while holding the other index constant. Multilinear regression is the tool used by Wyatt…that’s why the different weights (you even note the exact reason…the PDO is a smaller scale oscillation…a weaker signal caused by spatial differences that don’t exist in the AMO…it would seem obvious to someone acquainted with statistics that a weaker signal will not correlate as well with a big term like planetary temperatures.
I recommend a simple test to ease the confusion here…I agree that you can’t just add the two indices together…but you can reduce each index to a unitless trending term (making detrending irrelevant BTW), and produce much the same graph that Wyatt did…it was be dAMO/dt * k1 + dPDO/dt * k2 = dTep/dt, but the fit will be just as strong.
This isn’t satisfactory to a real scientist…we need a dynamical explanation for any statistical fit…but there would be nothing wrong with that analysis as something to raise questions for future research into those dynamical explanations.

jeez says: June 9, 2011 at 4:16 am

I received the sort of replies I was expecting….

——————-
jeez, if I have misjudged you, I apologize. I have reread your first post and can see what you were trying to say. However, to me it still does read a bit cavalier with regard to Bob Tindale’s money.
I do admit that my response to your comment was focused solely on that seemingly lack of concern. This is kind of a sore point for me, as I am also in debt and will probably be so until I die. (My life insurance should be adequate to pay the debt and not leave it for my kids.) The “limousine liberals” (that is indeed what I meant) that I encounter daily have a never ending list of “good works” that need funding out of my slim wallet.
I can see your perspective and I do have to give you credit for your generosity. If your accounting is accurate (and I assume that the moderators have verified that), you are obviously a very caring person. I hope that you can understand my position as well as your own.
Sincerely,
wermet

@Paul…
I am a Ph.D. candidate in atmospheric sciences studying wave interactions in the atmosphere and their implications to the predictability of atmospheric disturbances in the medium range (3-14 day) forecasts from numerical weather prediction models…
And even I cannot understand what it is you’re saying about length-of-day variations, solar cycle influences on global atmospheric annular momentum, or the interactions between the Earth, Moon and Sun and specifically the implications to climate dynamics. You are speaking Swahili and I’m speaking (evidently” the language of DERP.
Please…we need a post from you where in you discuss absolutely ZERO complex wavelet transform theory and focus entirely on the PHYSICAL MEANING of your argument and how it applies to climate change. My brain just exploded trying to read a post of yours you linked in your reply to me. Seriously, Paul…OUCH.
Respectfully,
Matt Souders

Bob Tisdale says (June 9, 2011 9:18am): “…Marcia Wyatt noted that one could use many combinations of other variables in place of the PDO data and get similar results in that comparison graph. That confirms the AMO is the primary source of the long-term agreement between the Northern Hemisphere temperatures and the combined climate indices. That’s not news. There are numerous papers that show the AMO is responsible for much of the multidecadal variations in Northern Hemisphere surface temperature.”
Bob, you are, without doubt, correct. An AMO-relationship with multidecadal variations in NHT is not news. But while we find a strong co-variability between AMO and NHT (with NHT leading AMO by ~4 years), and do not doubt a relationship between NHT and the SST-characteristics defining the AMO, we are not stating what that exact relationship is. Generation of the NHT signature is clearly complex.
If our results and interpretation of results are correct, what is news is the propagation of a climate signal throughout the Northern Hemisphere – a sequence of atmospheric and lagged oceanic teleconnections, resulting in an NHT trend oppositely signed from the initiating source. Such network “communication” is pervasive throughout natural and manmade systems. Finding it in climate leaves one to wonder, why not? The climate signal accounts for a substantial fraction of variance in several indices: NHT, AMO, PDO, and AT and only a small fraction of variance of NINO3.4 and NAO. Despite the latter mentioned indices possessing small fractional variances, in network theory, even the weakest links have profound effects on transforming “small-world” regional/local behavior into “global” behavior. Our approach is simply an additional way to view the climate – a complement to the reductionist strategy that focuses on the “parts”. We attempt to see the parts assembled.

Careful Brian. That estimate (4 year lag) is temporally-global (not to be confused with spatially-global). There’s not really a lag; this estimate simply alerts a careful interpreter to the existence of interannual spatiotemporal variability, as revealed by more temporally-localized methods (such as cross-wavelet methods & multiscale complex correlation).
Marcia, SOI & NAO show the ‘stadium wave’ too if you break the analysis down by season and pay attention to reversals in phase-relations. Also, AIR (All India Rainfall), hurricane frequency indices, & river flows for some regions fit the ‘stadium wave’. A request: It will be helpful if you define AT (and share a link to the data if possible), as that is a variable not yet on the WUWT community radar.

Time-integrated cross-correlation algorithms have utility as initial exploratory tools, but look at the mess Charles Perry (USGS) got himself into by not recognizing the pull of temporally-global extrema on cross-correlation lags. It’s a good place to start, but complex [as in complex numbers, not as in complicated (actually quite simple once one understands)] methods with temporally-local capabilities are needed to avoid nonsensical misinterpretation of lags.

@SABR Matt (June 10, 2011 at 11:15 am)
“Apart from all other reasons, the parameters of the geoid depend on the distribution of water over the planetary surface.” — from:
Sidorenkov, N.S. (2003). Changes in the Antarctic ice sheet mass and the instability of the Earth’s rotation over the last 110 years. International Association of Geodesy Symposia 127, 339-346.
“The purpose of this paper is to call attention to a close correlation of the decade variations in the Earth rotation with the mass changes in the Antarctic ice sheets.”
“The redistribution of water masses on the Earth entails changes in the components of the Earth’s inertia tensor and causes the motion of poles and changes of the Earth’s rotation speed.”
=
What the mainstream appears to have overlooked is very simple:
Solar max interrupts the semi-annual heat pump. The frequency of pump outages controls multidecadal oscillations (via hydrology). Interannual spatiotemporal chaos makes this difficult or impossible to see using linear methods.
Graphically:
1. http://wattsupwiththat.files.wordpress.com/2010/09/scl_northpacificsst.png
2. http://wattsupwiththat.files.wordpress.com/2010/12/vaughn_lod_fig1b.png
3. http://wattsupwiththat.files.wordpress.com/2010/08/vaughn_lod_amo_sc.png
SCL’ = solar cycle deceleration
=
To develop conceptual understanding:
a) Exposition of p. 433 [pdf p.10]:
Sidorenkov, N.S. (2005). Physics of the Earth’s rotation instabilities. Astronomical and Astrophysical Transactions 24(5), 425-439.
http://images.astronet.ru/pubd/2008/09/28/0001230882/425-439.pdf
(When you have more time, the whole paper deserves careful reading.)
b) Figures 8, 11, 13, & 15 (study them comparatively VERY carefully to “spot the differences” between the pictures…):
Leroux, Marcel (1993). The Mobile Polar High: a new concept explaining present mechanisms of meridional air-mass and energy exchanges and global propagation of palaeoclimatic changes. Global and Planetary Change 7, 69-93.
http://ddata.over-blog.com/xxxyyy/2/32/25/79/Leroux-Global-and-Planetary-Change-1993.pdf
c) Semi-Annual Solar-Terrestrial Power
http://wattsupwiththat.com/2010/12/23/confirmation-of-solar-forcing-of-the-semi-annual-variation-of-length-of-day/
Seminal paper that facilitated dot connection:
Le Mouël, J.-L.; Blanter, E.; Shnirman, M.; & Courtillot, V. (2010). Solar forcing of the semi-annual variation of length-of-day. Geophysical Research Letters 37, L15307. doi:10.1029/2010GL043185.
Excerpts from the paper that should be helpful for newcomers to EOP (Earth Orientation Parameters):
a) “The zonal winds contributing to lod seasonal variations are dominantly low altitude winds.”
b) “[…] solar activity can affect the radiative equilibrium of the troposphere in an indirect way, which cannot be simply deduced from the magnitude of TSI variations.”
c) “The semi-annual oscillation extends to all latitudes and down to low altitudes, as does the annual term. But, unlike the annual term, the main part of the oscillation is symmetrical about the equator; the partial cancellation of the angular momentum of the two hemispheres, which occurs for the annual oscillation, does not happen there [Lambeck, 1980]. Thus, we have here a measure of the seasonal variation of the total angular momentum of the atmosphere of the two hemispheres at the semi-annual frequency.”
d) “When considering separately monthly averages rather than annual ones, differences in the net radiative flux distribution appear, due to the seasonal variation in insulation which is asymmetric with respect to the equator. Seasonal variations of insulation result in seasonal variations of poleward meridional transport, hence of averaged zonal wind.” [Typo: “insulation” should read “insolation”.]
e) “The argument above serves to show that the semiannual variation in lod is linked to a fundamental feature of climate: the latitudinal distribution and transport of energy and momentum.” [Pole-equator contrast drives pumping.]
f) “The solid Earth behaves as a natural spatial integrator and time filter, which makes it possible to study the evolution of the amplitude of the semi-annual variation in zonal winds over a fifty-year time span. We evidence strong modulation of the amplitude of this lod spectral line by the Schwabe cycle (Figure 1a). This shows that the Sun can (directly or undirectly) influence tropospheric zonal mean-winds over decadal to multi-decadal time scales. Zonal mean-winds constitute an important element of global atmospheric circulation. If the solar cycle can influence zonal mean-winds, then it may affect other features of global climate as well […]“ [Typos: 1) “evidence” should read “observe”. 2) “undirectly” should read “indirectly”.]

corrected links:
[…] ~1910-1920 discrepancies here [ http://i44.tinypic.com/23rk2sh.jpg ] & here [ http://i47.tinypic.com/2a4ocqu.png ] roused my suspicions […]

P.S. I forgot to include the following regarding NHT leading AMO. In our study, we found that the “stadium-wave” climate signal (leading two modes of variability) accounts for a substantial fraction of variance in the Atlantic SST dipole (Keenlyside et al. 2008). MSSA showed the SST-dipole reconstructed index (RC) to be statistically identical to that of the NHT. Both lead a same-signed AMO by about four years. The SST-dipole is considered (albeit not without controversy) to be a proxy for the Atlantic Meridional Overturning Circulation (AMOC).
Paul, I think you quite fairly invited justification of the AMOC-AMO relationship in one of your posts. Our paper discusses this, but a short version follows: As far as controversy linking AMOC to AMO (at a lag), it is true that inconsistent modeling results confuse the issue. It is noteworthy that models with periodicities and boreal-winter atmospheric projections closest to observation seem to require a deep or interactive ocean (ex: Knight et al. 2005; Msadek et al. 2010b). Viewing the matter from a paleoclimate perspective, G. bulloides abundance in the Cariaco Basin is considered to be a proxy for the dipole and for the AMOC (Black et al. 1999) and is supportive of AMO-associated changes co-varying with its abundance. Again, our climate signal accounts for a high fractional variance in the G. bulloides record and its RC coincides with the Atlantic SST dipole and the NHT in our study. Thus, an AMOC-AMO relationship is supported by several lines of evidence, but continues to be an area of active research.