Readers may recall Pat Franks’s excellent essay on uncertainty in the temperature record. He emailed me about this new essay he posted on the Air Vent, with suggestions I cover it at WUWT, I regret it got lost in my firehose of daily email. Here it is now. – Anthony
Future Perfect
By Pat Frank
In my recent “New Science of Climate Change” post here on Jeff’s tAV, the cosine fits to differences among the various GISS surface air temperature anomaly data sets were intriguing. So, I decided to see what, if anything, cosines might tell us about the surface air temperature anomaly trends themselves. It turned out they have a lot to reveal.
As a qualifier, regular tAV readers know that I’ve published on the amazing neglect of the systematic instrumental error present in the surface air temperature record It seems certain that surface air temperatures are so contaminated with systematic error – at least (+/-)0.5 C — that the global air temperature anomaly trends have no climatological meaning. I’ve done further work on this issue and, although the analysis is incomplete, so far it looks like the systematic instrumental error may be worse than we thought. J But that’s for another time.
Systematic error is funny business. In surface air temperatures it’s not necessarily a constant offset but is a variable error. That means it not only biases the mean of a data set, but it is likely to have an asymmetric distribution in the data. Systematic error of that sort in a temperature series may enhance a time-wise trend or diminish it, or switch back-and-forth in some unpredictable way between these two effects. Since the systematic error arises from the effects of weather on the temperature sensors, the systematic error will vary continuously with the weather. The mean error bias will be different for every data set and so with the distribution envelope of the systematic error.
For right now, though, I’d like to put all that aside and proceed with an analysis that accepts the air temperature context as found within the IPCC ballpark. That is, for the purposes of this analysis I’m assuming that the global average surface air temperature anomaly trends are real and meaningful.
I have the GISS and the CRU annual surface air temperature anomaly data sets out to 2010. In order to make the analyses comparable, I used the GISS start time of 1880. Figure 1 shows what happened when I fit these data with a combined cosine function plus a linear trend. Both data sets were well-fit.
The unfit residuals are shown below the main plots. A linear fit to the residuals tracked exactly along the zero line, to 1 part in ~10^5. This shows that both sets of anomaly data are very well represented by a cosine-like oscillation plus a rising linear trend. The linear parts of the fitted trends were: GISS, 0.057 C/decade and CRU, 0.058 C/decade.
Figure 1. Upper: Trends for the annual surface air temperature anomalies, showing the OLS fits with a combined cosine function plus a linear trend. Lower: The (data minus fit) residual. The colored lines along the zero axis are linear fits to the respective residual. These show the unfit residuals have no net trend. Part a, GISS data; part b, CRU data.Removing the oscillations from the global anomaly trends should leave only the linear parts of the trends. What does that look like? Figure 2 shows this: the linear trends remaining in the GISS and CRU anomaly data sets after the cosine is subtracted away. The pure subtracted cosines are displayed below each plot.
Each of the plots showing the linearized trends also includes two straight lines. One of them is the line from the cosine plus linear fits of Figure 1. The other straight line is a linear least squares fit to the linearized trends. The linear fits had slopes of: GISS, 0.058 C/decade and CRU, 0.058 C/decade, which may as well be identical to the line slopes from the fits in Figure 1.
Figure 1 and Figure 2 show that to a high degree of certainty, and apart from year-to-year temperature variability, the entire trend in global air temperatures since 1880 can be explained by a linear trend plus an oscillation.
Figure 3 shows that the GISS cosine and the CRU cosine are very similar – probably identical given the quality of the data. They show a period of about 60 years, and an intensity of about (+/-)0.1 C. These oscillations are clearly responsible for the visually arresting slope changes in the anomaly trends after 1915 and after 1975.
Figure 2. Upper: The linear part of the annual surface average air temperature anomaly trends, obtained by subtracting the fitted cosines from the entire trends. The two straight lines in each plot are: OLS fits to the linear trends and, the linear parts of the fits shown in Figure 1. The two lines overlay. Lower: The subtracted cosine functions.The surface air temperature data sets consist of land surface temperatures plus the SSTs. It seems reasonable that the oscillation represented by the cosine stems from a net heating-cooling cycle of the world ocean.
Figure 3: Comparison of the GISS and CRU fitted cosines.The major oceanic cycles include the PDO, the AMO, and the Indian Ocean oscillation. Joe D’aleo has a nice summary of these here (pdf download).
The combined PDO+AMO is a rough oscillation and has a period of about 55 years, with a 20th century maximum near 1937 and a minimum near 1972 (D’Aleo Figure 11). The combined ocean cycle appears to be close to another maximum near 2002 (although the PDO has turned south). The period and phase of the PDO+AMO correspond very well with the fitted GISS and CRU cosines, and so it appears we’ve found a net world ocean thermal signature in the air temperature anomaly data sets.
In the “New Science” post we saw a weak oscillation appear in the GISS surface anomaly difference data after 1999, when the SSTs were added in. Prior and up to 1999, the GISS surface anomaly data included only the land surface temperatures.
So, I checked the GISS 1999 land surface anomaly data set to see whether it, too, could be represented by a cosine-like oscillation plus a linear trend. And so it could. The oscillation had a period of 63 years and an intensity of (+/-)0.1 C. The linear trend was 0.047 C/decade; pretty much the same oscillation but a slower warming trend by 0.1 C/decade. So, it appears that the net world ocean thermal oscillation is teleconnected into the global land surface air temperatures.
But that’s not the analysis that interested me. Figure 2 appears to show that the entire 130 years between 1880 and 2010 has had a steady warming trend of about 0.058 C/decade. This seems to explain the almost rock-steady 20th century rise in sea level, doesn’t it.
The argument has always been that the climate of the first 40-50 years of the 20th century was unaffected by human-produced GHGs. After 1960 or so, certainly after 1975, the GHG effect kicked in, and the thermal trend of the global air temperatures began to show a human influence. So the story goes.
Isn’t that claim refuted if the late 20th century warmed at the same rate as the early 20th century? That seems to be the message of Figure 2.
But the analysis can be carried further. The early and late air temperature anomaly trends can be assessed separately, and then compared. That’s what was done for Figure 4, again using the GISS and CRU data sets. In each data set, I fit the anomalies separately over 1880-1940, and over 1960-2010. In the “New Science of Climate Change” post, I showed that these linear fits can be badly biased by the choice of starting points. The anomaly profile at 1960 is similar to the profile at 1880, and so these two starting points seem to impart no obvious bias. Visually, the slope of the anomaly temperatures after 1960 seems pretty steady, especially in the GISS data set.
Figure 4 shows the results of these separate fits, yielding the linear warming trend for the early and late parts of the last 130 years.
Figure 4: The Figure 2 linearized trends from the GISS and CRU surface air temperature anomalies showing separate OLS linear fits to the 1880-1940 and 1960-2010 sections.The fit results of the early and later temperature anomaly trends are in Table 1.
Table 1: Decadal Warming Rates for the Early and Late Periods.
| Data Set |
C/d (1880-1940) |
C/d (1960-2010) |
(late minus early) |
| GISS |
0.056 |
0.087 |
0.031 |
| CRU |
0.044 |
0.073 |
0.029 |
“C/d” is the slope of the fitted lines in Celsius per decade.
So there we have it. Both data sets show the later period warmed more quickly than the earlier period. Although the GISS and CRU rates differ by about 12%, the changes in rate (data column 3) are identical.
If we accept the IPCC/AGW paradigm and grant the climatological purity of the early 20th century, then the natural recovery rate from the LIA averages about 0.05 C/decade. To proceed, we have to assume that the natural rate of 0.05 C/decade was fated to remain unchanged for the entire 130 years, through to 2010.
Assuming that, then the increased slope of 0.03 C/decade after 1960 is due to the malign influences from the unnatural and impure human-produced GHGs.
Granting all that, we now have a handle on the most climatologically elusive quantity of all: the climate sensitivity to GHGs.
I still have all the atmospheric forcings for CO2, methane, and nitrous oxide that I calculated up for my http://www.skeptic.com/reading_room/a-climate-of-belief/”>Skeptic paper. Together, these constitute the great bulk of new GHG forcing since 1880. Total chlorofluorocarbons add another 10% or so, but that’s not a large impact so they were ignored.
All we need do now is plot the progressive trend in recent GHG forcing against the balefully apparent human-caused 0.03 C/decade trend, all between the years 1960-2010, and the slope gives us the climate sensitivity in C/(W-m^-2). That plot is in Figure 5.
Figure 5. Blue line: the 1960-2010 excess warming, 0.03 C/decade, plotted against the net GHG forcing trend due to increasing CO2, CH4, and N2O. Red line: the OLS linear fit to the forcing-temperature curve (r^2=0.991). Inset: the same lines extended through to the year 2100.There’s a surprise: the trend line shows a curved dependence. More on that later. The red line in Figure 5 is a linear fit to the blue line. It yielded a slope of 0.090 C/W-m^-2.
So there it is: every Watt per meter squared of additional GHG forcing, during the last 50 years, has increased the global average surface air temperature by 0.09 C.
Spread the word: the Earth climate sensitivity is 0.090 C/W-m^-2.
The IPCC says that the increased forcing due to doubled CO2, the bug-bear of climate alarm, is about 3.8 W/m^2. The consequent increase in global average air temperature is mid-ranged at 3 Celsius. So, the IPCC officially says that Earth’s climate sensitivity is 0.79 C/W-m^-2. That’s 8.8x larger than what Earth says it is.
Our empirical sensitivity says doubled CO2 alone will cause an average air temperature rise of 0.34 C above any natural increase. This value is 4.4x -13x smaller than the range projected by the IPCC.
The total increased forcing due to doubled CO2, plus projected increases in atmospheric methane and nitrous oxide, is 5 W/m^2. The linear model says this will lead to a projected average air temperature rise of 0.45 C. This is about the rise in temperature we’ve experienced since 1980. Is that scary, or what?
But back to the negative curvature of the sensitivity plot. The change in air temperature is supposed to be linear with forcing. But here we see that for 50 years average air temperature has been negatively curved with forcing. Something is happening. In proper AGW climatology fashion, I could suppose that the data are wrong because models are always right.
But in my own scientific practice (and the practice of everyone else I know), data are the measure of theory and not vice versa. Kevin, Michael, and Gavin may criticize me for that because climatology is different and unique and Ravetzian, but I’ll go with the primary standard of science anyway.
So, what does negative curvature mean? If it’s real, that is. It means that the sensitivity of climate to GHG forcing has been decreasing all the while the GHG forcing itself has been increasing.
If I didn’t know better, I’d say the data are telling us that something in the climate system is adjusting to the GHG forcing. It’s imposing a progressively negative feedback.
It couldn’t be the negative feedback of Roy Spencer’s clouds, could it?
The climate, in other words, is showing stability in the face of a perturbation. As the perturbation is increasing, the negative compensation by the climate is increasing as well.
Let’s suppose the last 50 years are an indication of how the climate system will respond to the next 100 years of a continued increase in GHG forcing.
The inset of Figure 5 shows how the climate might respond to a steadily increased GHG forcing right up to the year 2100. That’s up through a quadrupling of atmospheric CO2.
The red line indicates the projected increase in temperature if the 0.03 C/decade linear fit model was true. Alternatively, the blue line shows how global average air temperature might respond, if the empirical negative feedback response is true.
If the climate continues to respond as it has already done, by 2100 the increase in temperature will be fully 50% less than it would be if the linear response model was true. And the linear response model produces a much smaller temperature increase than the IPCC climate model, umm, model.
Semi-empirical linear model: 0.84 C warmer by 2100.
Fully empirical negative feedback model: 0.42 C warmer by 2100.
And that’s with 10 W/m^2 of additional GHG forcing and an atmospheric CO2 level of 1274 ppmv. By way of comparison, the IPCC A2 model assumed a year 2100 atmosphere with 1250 ppmv of CO2 and a global average air temperature increase of 3.6 C.
So let’s add that: Official IPCC A2 model: 3.6 C warmer by 2100.
The semi-empirical linear model alone, empirically grounded in 50 years of actual data, says the temperature will have increased only 0.23 of the IPCC’s A2 model prediction of 3.6 C.
And if we go with the empirical negative feedback inference provided by Earth, the year 2100 temperature increase will be 0.12 of the IPCC projection.
So, there’s a nice lesson for the IPCC and the AGW modelers, about GCM projections: they are contradicted by the data of Earth itself. Interestingly enough, Earth contradicted the same crew, big time, at the hands Demetris Koutsoyiannis, too.
So, is all of this physically real? Let’s put it this way: it’s all empirically grounded in real temperature numbers. That, at least, makes this analysis far more physically real than any paleo-temperature reconstruction that attaches a temperature label to tree ring metrics or to principal components.
Clearly, though, since unknown amounts of systematic error are attached to global temperatures, we don’t know if any of this is physically real.
But we can say this to anyone who assigns physical reality to the global average surface air temperature record, or who insists that the anomaly record is climatologically meaningful: The surface air temperatures themselves say that Earth’s climate has a very low sensitivity to GHG forcing.
The major assumption used for this analysis, that the climate of the early part of the 20th century was free of human influence, is common throughout the AGW literature. The second assumption, that the natural underlying warming trend continued through the second half of the last 130 years, is also reasonable given the typical views expressed about a constant natural variability. The rest of the analysis automatically follows.
In the context of the IPCC’s very own ballpark, Earth itself is telling us there’s nothing to worry about in doubled, or even quadrupled, atmospheric CO2.
Bart says:
June 19, 2011 at 9:01 pm
The underlying process is 20 and 23.6 years for the interval from the mid-1700s to today.
Many people have tried various numerology on this. One frequent [past] commenter here is Vukcevic, pushing a SSN formula that provides a generally poor but at least approximate fit to the observed SSN. His formula goes something like this [it is hard to quote correctly, because it has been a moving target], SSN = 100 abs (cos(pi/2+ 2pi (t-1941)/A) + cos(2pi(t-1941)/B)), where t is time in years. The two constants A and B are A = 23.7 and B = 19.9 years, which are respectively (A), twice Jupiter’s orbital period and (B) the time between conjunctions of Jupiter and Saturn ( http://www.astrofuturetrends.com/id69.html ). This combination with A and B crops up from time to time in fringe studies and does provide a crude fit to the SSN the past 2-3 centuries, so can be said to provide an approximate numerological description of the cycle. All our observations of the real sun and the understanding we have gained of how it works show, however, that the fit is spurious. There are no physical processes in the sun that work that way [the Sun is not an oscillator]. And as I pointed out, the real length of the solar cycle is about 17 years.
Leif Svalgaard says:
June 19, 2011 at 9:55 pm
“Sorry to say, but there are no such underlying cycles.”
These are NOT cycles except in loose parlance. They are modal excitations.
Once again, you have gone out on a limb, and are completely, obviously, and utterly wrong. You ought to look up the meaning of the term I used: hidebound. This definition at dictionary.com is particularly aptly metaphoric:
“3. (of trees) having a very tight bark that impairs growth ”
You have developed an attitude that you know everything, but in the realm of Fourier analysis, your insights and prejudices have been demonstrated to be consistently inadequate, and it is impairing your growth.
“…the fit is spurious.”
The reasons may or may not be spurious, but the effect is clearly there. You’re telling me something doesn’t exist while I’m looking right at it.
Vukcevic’s formula is the right form, but suffers from the assumption of steady state sinusoidal oscillation. This is a modal oscillation driven by a random input. I see time constants of most likely somewhere between 80 and 100 years, based on the width of the lobes. Nailing down the model is the greater part of the Kalman Filter effort.
“…the Sun is not an oscillator…”
I have not said it is. A more apt analogy is a glob of jelly sitting on the table of a railway dining car, which jiggles fitfully at a frequency determined by the surface tension due to random wideband acceleration excitations of the vehicle. (Please do not go off on a tangent about surface tension having nothing to do with the solar cycle – I am making an analogy, not elucidating principles of solar dynamics.)
“And as I pointed out, the real length of the solar cycle is about 17 years.”
Your waveform crosses zero at about 1968, 1990, and looks likely to cross again about 2012 – 22 years each time. Where are you getting this 17?
For any who may be interested, treating the Sun Spot Number as proportional to the magnitude of the sum of processes at 20 and 23.6 years, rather than the squared magnitude as I did previously, gives a better correspondence of the model with the data. I updated my plot here accordingly.
Bart says:
June 20, 2011 at 8:42 am
They are modal excitations.Which are just damped oscillations. Here is a tutorial for you on modal excitations: http://www.sem.org/PDF/IMAC2008_Modal_Excitation_Tutorial_revF.pdf
You need a force to drive the excitations and we have not detected any such forces with the periods you find. Vuk [and others] believes the forcing is Jupiter and Saturn, but the energy and coupling mechanisms are not there, so this is not taken seriously. Just another example of spurious correlation.
<i<This is a modal oscillation driven by a random input
Oscillation again. Or just another loose term?
“…the fit is spurious.” The reasons may or may not be spurious, but the effect is clearly there.
You have this backwards. The effect is spurious because the reasons are not there.
“And as I pointed out, the real length of the solar cycle is about 17 years.”
Your waveform crosses zero at about 1968, 1990, and looks likely to cross again about 2012 – 22 years each time.
It crosses every ten years in 1968, 1980, 1990, 2000, 2012. And it is not a ‘waveform’. There is no wave, just polar fields that come and go every ten years, driven by movements of small-scale magnetic flux from dead sunspots drifting towards the poles.
Where are you getting this 17?
http://www.nature.com/nature/journal/v333/n6175/abs/333748a0.html
ftp://ftp.nso.edu/outgoing/users/altrock/ESC24.pdf [section 4]
http://iopscience.iop.org/0004-637X/685/2/1291/74871.text.html [section 2]
etc
I see time constants of most likely somewhere between 80 and 100 years, based on the width of the lobes.
There is general acceptance of the existence of an approximately 11-yr solar ‘cycle’ with an amplitude modulation of 80-100 years. There is a large body of literature with various physical theories accounting for this.
“You need a force to drive the excitations and we have not detected any such forces with the periods you find. “
Wideband noise will do it. A two mode model such as this will generate the observed behavior with the proper phasing. A Kalman Filter run backwards and forwards on the data set will properly initialize the states, and a projection forward with error bounds from the propagated covariance can easily be generated (but, it takes time, and I have a job and a life).
“Vuk [and others] believes the forcing is Jupiter and Saturn, but the energy and coupling mechanisms are not there…”
I believe you. But, it is a misapprehension to believe that you need a driver at a specific frequency. All you need is an input to energize the mode.
“Oscillation again. Or just another loose term?”
Definition 2:
oscillate os·cil·late (ŏs’ə-lāt’)
v. os·cil·lat·ed , os·cil·lat·ing , os·cil·lates
1. To swing back and forth with a steady, uninterrupted rhythm.
2. To vary between alternate extremes, usually within a definable period of time.
“You have this backwards.”
I do not.
“It crosses every ten years in 1968, 1980, 1990, 2000, 2012.”
But, it crosses with the same +/- slope every 22 years. You pick out the period the same as you would for a sine wave.
“There is no wave, just polar fields that come and go every ten years…”
wave-form
[weyv-fawrm]
–noun Physics .
the shape of a wave, a graph obtained by plotting the instantaneous values of a periodic quantity against the time.
“There is general acceptance of the existence of an approximately 11-yr solar ‘cycle’ with an amplitude modulation of 80-100 years.”
Time constants are not periods. At the link I gave above, the time constant of the first block is 1/(zeta1*omega1), and similarly for the second block. These indicate the time associated with a decay of 63% in the amplitude of the damped sinusoid which would ensure if you took away all excitations.
“All you need is an input to energize the mode.”
All you need is an input which will energize the mode. Wideband noise is sufficient.
“…of the damped sinusoid which would ensue if you took away all excitations.”
Here is what I am talking about. This run of the model just happened to be randomly initialized such that it gave a result eerily similar to the real SSN data.
Bart says:
June 20, 2011 at 8:42 am
They are modal excitations.
Here I explain why they are not: http://www.leif.org/research/Toy-Solar-Cycles.pdf
Leif Svalgaard says:
June 20, 2011 at 10:51 pm
Awful. Just, awful.
Bart says:
June 21, 2011 at 8:53 am
Awful. Just, awful.
I guess you didn’t like the smackdown…
The period of the green sinusoidal curve in panel two of figure one does not match the period of the orange curve in panel two of figure two. Which figure is in error?