On Foster and Rahmstorf 2011 – Global temperature evolution 1979–2010
Guest post by Bob Tisdale
Note (May 23, 2013): Update 3 appeared in the cross post at my blog but not here at WUWT. I’ve added it here.
UPDATE 3 (January 14, 2012): I displayed my very limited understanding of statistics in this post. This was pointed out to me a great number times by many different people in numerous comments received in the WattsUpWithThat cross post.The errors in that initial portion of the post were so many and so great that they detracted from the bulk of the post, which was about the El Niño-Southern Oscillation. Please disregard this post and the WUWT cross post, and any other cross posts that may exist.
I have reissued the ENSO-related portion of the post herewith a number of additions. If Anthony Watts cross posts the new version at WattsUpWithThat, I’ll provide a link here.
Originally, when I wrote the post about Foster and Rahmstorf (2011), I had not included my error-filled discussion about their regression analysis. That was a last minute addition. Lesson learned.
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UPDATE 2 (January 5, 2012): PLEASE READ. Three things: First, I did not understand that a “linear time trend” used by Foster and Rahmstorf (2011) is different than a “linear trend”. My confusion also led to confusion for many bloggers who read my post and who commented on the WattsUpWithThat cross post. My apologies. For those interested, the “linear time trend” is discussed under the heading of “Data as trend plus noise” on the Wikipedia Trend Estimationwebpage.
Second, in addition to MEI, AOD, and TSI as independent variables, I mistakenly used the values of the linear trend, which EXCEL calculated with its LINEST function from the monthly GISS data, as the fourth independent variable. And this added to the confusion of those who were interpreting the equations. In retrospect, I should not have included the equations. I should have included a table that listed the coefficients instead.
Third, in my haste to publish this post, I failed to explain the steps I used to process the data, and it may have been confusing to those who were looking at equations and graphs. I performed the regression analyses with the “raw” monthly data; then using the resulting coefficients, I made the adjustments to the monthly data. (I had prepared a graph using monthly data, similar to F&R’s Figure 4, with 1979-2010 as base years. But I felt my version was an unintelligible spaghetti graph with little value, so I didn’t include it.) I then converted the adjusted data to annual data; and last, changed the base years to 1979-2010.
The bottom line: Although I mistook a linear trend for a linear time trend, and although I did not include all of the additional data refinements used by Foster and Rahmstorf (2011), it’s difficult to see any difference between my Figure 7 and their Figure 5. There were other bloggers commenting on the thread of the WUWT cross post who got similar results using different methods. Does this mean the results of Foster and Rahmstorf (2011) are robust as some comments on the WUWT tread claimed? No. ENSO is a process, not an index, and it can’t be account for using linear regression analysis. This was illustrated clearly and discussed in detail under the heading of ENSO IS NOT AN EXOGENOUS FACTOR.
UPDATE 1 (January 3, 2012): Under the heading of ENSO IS NOT AN EXOGENOUS FACTOR, I changed the wording of a sentence, crossing out “create” and replacing it with “recharge”.—Thanks, Steve Allen.
OVERVIEW
This post examines a curious aspect of the multiple linear regression analysis performed by Foster and Rahmstorf in their 2011 paper “Global Temperature Evolution 1979–2010”. I find it very odd that a factor upon which the paper appears to rest was not presented in detail in it. Please understand right from the start, for this portion of the post, I am not implying that there is something wrong with this specific aspect of the paper; but I’m also not agreeing with it. I’m presenting it for discussion.
The second part of this post is a discussion of one of the exogenous factors that Foster and Rahmstorf (2011) has attempted to remove. The problem: it is not an exogenous factor. And there is a third discussion about a dataset that’s present in the spreadsheet provided by the lead author Grant Foster (aka Tamino) but, curiously, not mentioned in the paper.
Not surprisingly, Foster and Rahmstorf (2011) made the rounds at the blogs of the proponents of anthropogenic global warming. Joe Romm praised it with the post Sorry, Deniers, Study of “True Global Warming Signal” Finds “Remarkably Steady” Rate of Manmade Warming Since 1979. SkepticalScience covered the paper in their post Foster and Rahmstorf Measure the Global Warming Signal. And RealClimate gave it an honorable mention by including it as one of the topics in its Global Temperature News post.
INTRODUCTION
Foster and Rahmstorf (2011) attempted to remove from 5 global temperature datasets the linear effects of 3 factors that are known to cause variations in global temperature.
They covered the period of 1979 to 2010. The obvious intent of the paper is to show that anthropogenic global warming continues unabated in all of those datasets. The independent variables listed in the abstract of Foster and Rahmstorf (2011) are El Niño-Southern Oscillation, volcanic aerosols, and solar variations. Foster and Rahmstorf (2011) appears to be a much clarified version of Tamino’s (Grant Foster’s) January 20, 2011 post How Fast is Earth Warming? After publication of the paper, Tamino discussed it in his post The Real Global Warming Signal and was kind enough to provide the source data and code in his post Data and Code for Foster & Rahmstorf 2011. The data Tamino provided is available here. It is a .zip file that Tamino has renamed a .xls file, as he explains, “in order to fool the wordpress software into believing that it’s an Excel file.” You will need to “Right Click and Save As” and then change the file name back to a .zip file in order to open it.
As noted above, in the abstract, Foster and Rahmstorf (2011) list the exogenous factors that are used as independent variables in the multiple regression analysis as “El Niño/southern oscillation, volcanic aerosols and solar variability.” Curiously, three paragraphs later, when they list the factors included in the multiple regression analysis again, Foster and Rahmstorf (2011) have added a fourth variable: linear trend. The last sentence of the third paragraph under the heading of “Introduction” reads:
“The influence of exogenous factors will be approximated by multiple regression of temperature against ENSO, volcanic influence, total solar irradiance (TSI) and a linear time trend to approximate the global warming that has occurred during the 32 years subject to analysis.”
But one of the bases for the paper is to illustrate how similar the trends are after the adjustments for ENSO, Total Solar Irradiance, and Volcanic Aerosols have been made, so including the linear trends of those datasets in the regression analysis seems odd. As a result, I went in search of another reason why Foster and Rahmstorf (2011) would have needed to include the linear trend in their regression analyses. As I note in the following, I’m using commercially available add-on software for EXCEL to perform the multiple regression analyses. Since I have no other means to verify the results, other than reproducing the results of one of their graphs, I’ll request that you confirm the following results if you have that capability.
WHY DID FOSTER & RAHMSTORF NEED TO INCLUDE A LINEAR TREND IN THE MULTIPLE REGRESSION ANALYSIS?
The only reason that I can see that Foster and Rahmstorf (2011) needed to include the trend in the multiple regression analysis is, the adjustment factor for the solar data is the wrong sign when the multiple regression analysis uses only ENSO, Solar, and Volcanic Aerosol data as independent variables. Let me explain in more detail. But again, please understand, for this portion of the post, I am not implying that there is something wrong with this specific aspect of the paper; and again, I’m also not agreeing with it. I found this interesting.
With the data provided by Tamino, I used Analyse-It for EXCEL software to perform a multiple regression analysis. (For those with EXCEL who have no means to perform a multiple linear regression analysis and want to verify my results, Analyse-It is available free on a 30-day trial basis.) My initial analysis included Tamino’s favorite global Surface Temperature dataset GISS as the dependent variable and the Multivariate ENSO Index (MEI), the Total Solar Irradiance (PMOD), and the Volcanic Aerosol Optical Depth data (AOD) as the independent variables. I lagged the MEI data by four months, the PMOD data by one month, and the AOD data by seven months, in agreement with Table 1 of Foster and Rahmstorf (2011), which is also Table 1 in this post. And in this analysis, I did not include the GISTEMP linear trend as an independent variable.
Table 1
The multiple regression analysis using only the ENSO (MEI), Solar (PMOD), and Volcanic Aerosol (AOD) data resulted in Equation 1:
EQUATION 1:
GISS = 123.6 + 0.06769MEI(4m lag) – 0.09025TSI.PMOD(1m lag)– 3.837AOD (7m lag)
I highlighted the solar variable scaling factor in boldface to emphasize the fact that the sign is negative. It would need to be positive to reproduce the results of Foster and Rahmstorf (2011). The signs of the ENSO and volcanic aerosol factors are what one would expect, Figure 1. It’s only the sign of the solar coefficient that is the opposite of what Foster and Rahmstorf (2011) present, Figure 2 (which is their Figure 7).
Figure 1
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Figure 2
And that makes a monumental difference to the outcome of Foster and Rahmstorf (2011). If we adjust the GISS surface temperature data with the factors presented in Equation 1, then the rise is not continuous. Refer to Figure 3. The peak year for the adjusted GISS-based global Surface Temperature data is 2002.
Figure 3
To confirm the results of Foster and Rahmstorf (2011), I added the 0.167 deg C/Decade linear trend of the GISS global surface temperature anomaly data to the independent variables. The lags of the ENSO (MEI), Solar (PMOD), and Volcanic Aerosol (AOD) data remained the same as above.
The multiple regression analysis using the ENSO (MEI), Solar (PMOD), and Volcanic Aerosol (AOD) data and the linear trend resulted in Equation 2:
EQUATION 2:
GISS = -91.43 + 1.024Trend + 0.0761MEI(4m lag) + 0.06694TSI.PMOD(1m lag)– 2.334AOD (7m lag)
The sign of the Total Solar Irradiance coefficient now agrees with what Foster and Rahmstorf (2011) presented, as shown in Figure 4. Note that including the trend as an independent variable also influenced the scaling of the ENSO (MEI) and Volcanic Aerosol (AOD) data. It increased the scaling factor of the ENSO data a little, but decreased the scaling factor of Volcanic Aerosol significantly. Of course, the inclusion of the trend as an independent variable, with the change in sign of the Solar influence, also gives the adjusted GISS data results that Foster and Rahmstorf (2011) wanted, Figure 5, with the rise in temperature relatively steady over the 32 year period. And note that the trend of 0.172 deg C per decade is comparable to the findings of Foster and Rahmstorf (2011) shown in Table 1 for GISS data.
Figure 4
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Figure 5
Of course, I did not include [and Foster and Rahmstorf (2011) could not have included] the trend adjustment from Equation 2 when the corrected data was presented in Figure 5. If the trend adjustment was included, the corrected data would have no trend. That means, it appears Foster and Rahmstorf (2011) needed to include the trend of the GISTEMP data in the regression analysis only to assure the sign of the solar influence they sought.
Foster and Rahmstorf (2011) would have gotten similar scaling factors for the ENSO (MEI), Solar (PMOD), and Volcanic Aerosol (AOD) data if they had simply detrended the GISS Global Surface Temperature data.
EQUATION 3:
Detrended GISS = -86.31 + 0.0759MEI(4m lag) + 0.0632TSI.PMOD(1m lag) – 2.37AOD (7m lag)
REVERSED SIGN OF SOLAR INFLUENCE IS COMMON TO ALL GLOBAL TEMPERATURE DATASETS
Someone is bound to ask whether the GISS Global Surface Temperature dataset is the only dataset with these results. The answer is no. If the linear trend is not included in the multiple linear regression analyses, the sign of the solar coefficient is the opposite of what Foster and Rahmstorf (2011) would had to have used for the NCDC and HADCRUT global land plus sea surface temperature datasets and for the RSS and UAH global Lower Troposphere Temperature data. The resulting equations from the linear regression analyses of the other datasets are presented in equations 4 through 7. The lags for the independent variables are as listed in Table 1 above:
EQUATION 4 (NCDC Land Plus Ocean Surface Temperature):
NCDC = 109.1 + 0.05495MEI(2m lag) – 0.0796TSI.PMOD(1m lag)– 3.113AOD (5m lag)
EQUATION 5 (Hadley Centre HADCRUT Global Surface Temperature Anomalies):
HadCRUT3v = 92.21 + 0.06421MEI(3m lag) – 0.0673TSI.PMOD(1m lag)– 3.293AOD (6m lag)
EQUATION 6 (RSS MSU Lower Troposphere Temperature Anomalies):
RSS33 = 61.44 + 0.1285MEI(5m lag) – 0.04489TSI.PMOD(0m lag)– 4.863AOD (5m lag)
EQUATION 7 (UAH MSU Lower Troposphere Temperature Anomalies):
UAH = 72.94 + 0.1332MEI(5m lag) – 0.05338TSI.PMOD(0m lag)– 5.139AOD (6m lag)
If we use those coefficients, the five datasets do not produce the nice continuous rise in Global Temperatures that Foster and Rahmstorf (2011) wanted to present, as shown in Figure 6. For the three Surface Temperature anomaly datasets (GISS, HADCRUT, NCDC) 2002 has the highest temperature. It’s only the two Lower Troposphere Temperature anomaly datasets that have 2010 as the warmest year.
Figure 6
And as one would expect, if the linear trends of the other global temperature datasets are included in the independent variables, the signs of the solar coefficients are positive. Refer to equations 8 through 11.
EQUATION 8 (NCDC Land Plus Ocean Surface Temperature, with trend):
NCDC = -106.7 + 1.085Trend + 0.06832MEI(2m lag) + 0.07813TSI.PMOD(1m lag)– 1.68AOD (5m lag)
EQUATION 9 (Hadley Centre HADCRUT Global Surface Temperature Anomalies, with trend):
HadCRUT3v = -119.2 + 1.093Trend + 0.07519MEI(3m lag) + 0.08723TSI.PMOD(1m lag)– 1.858AOD (6m lag)
EQUATION 10 (RSS MSU Lower Troposphere Temperature Anomalies, with trend):
RSS33 = -135.5 + 1.05Trend + 0.1342MEI(5m lag) + 0.09923TSI.PMOD(0m lag)– 3.479AOD (5m lag)
EQUATION 11 (UAH MSU Lower Troposphere Temperature Anomalies, with trend):
UAH = -105.7 + 0.9953Trend + 0.1381MEI(5m lag) + 0.07742TSI.PMOD(0m lag)– 3.871AOD (6m lag)
With the linear trend included in the multiple regression analyses, the coefficients in the equations above provide the adjustments that Foster and Rahmstorf (2011) presented, Figure 7. I’ve included their Figure 5 as my Figure 8 as a reference.
Figure 7
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Figure 8
THE ASSUMPTION ABOUT THE LINEAR TREND
I’m sure some will attempt to argue that including the trend in the regression analyses is necessary since computer model-based studies have shown the rise in global surface temperature is caused by anthropogenic forcings during the period of 1979 to 2010. But of course, that argument assumes climate models can be used for determining the cause of the rise in Global Surface Temperatures during any period. We have recently illustrated and discussed that the climate models used by the IPCC in their 4th Assessment report have shown no skill at reproducing the global surface temperatures over any period during the 20th Century. Refer to the summary post ON THE IPCC’s UNDUE CONFIDENCE IN COUPLED OCEAN-ATMOSPHERE CLIMATE MODELS – A SUMMARY OF RECENT POSTS. The second problem with their assumption is that the global oceans, which cover about 70% of the surface area of the globe, show no signs of the influence of anthropogenic global warming during the satellite era. And that brings us to…
ENSO IS NOT AN EXOGENOUS FACTOR
Foster and Rahmstorf (2011) included ENSO as one of the exogenous factors they attempted to remove from the instrument temperature record. But ENSO is not an exogenous factor. ENSO is a coupled ocean-atmosphere process that periodically discharges heat to the atmosphere during an El Niño. The El Niño causes changes in atmospheric circulation patterns, which cause temperatures outside of the eastern tropical Pacific to vary, some warming, some cooling, but in total, the areas that warm exceed those that cool and global surface temperatures rise in response to an El Niño. The patterns of warming and cooling during a La Niña are similar to an El Niño, but the signs are reversed. And that’s really all that a paper such as Foster and Rahmstorf (2011) could hope to account for including ENSO in the regression analysis. But there is much more to ENSO.
ENSO is also a process that redistributes the warm water that was leftover from the El Niño itself and enhances the redistribution of the warm water that was created by the El Niño outside of the eastern tropical Pacific. The redistribution carries that warm water poleward and into adjoining ocean basins during the La Niña that follows an El Niño. La Niña events also recharge part of the warm water that was released during the El Niño. Sometimes La Niña events “overcharge” the tropical Pacific, inasmuch as they create recharge more tropical Pacific ocean heat than was discharged during the El Niño that came before it. That was the case during the 1973/74/75/76 and 1995/96 La Niña events. Refer to Figure 9. The 1973/94/75/76 La Niña provided the initial “fuel” for the 1982/83 Super El Niño and the multi-year 1986/87/88 El Niño. And the 1997/98 “El Niño of the Century” was fueled by the 1995/96 La Niña. The process of ENSO cannot be accounted for through linear regression on an index. This was illustrated and discussed at an introductory level in the post ENSO Indices Do Not Represent The Process Of ENSO Or Its Impact On Global Temperature.
Figure 9
Foster and Rahmstorf (2011) cited Trenberth et al (2002) Evolution of El Nino–Southern Oscillation and global atmospheric surface temperatures” as one of their ENSO references. But Trenberth et al (2002) include the following disclaimer in the second paragraph of their Conclusions, (their paragraph 52, my boldface):
The main tool used in this study is correlation and regression analysis that, through least squares fitting, tends to emphasize the larger events. This seems appropriate as it is in those events that the signal is clearly larger than the noise. Moreover, the method properly weights each event (unlike many composite analyses). Although it is possible to use regression to eliminate the linear portion of the global mean temperature signal associated with ENSO, the processes that contribute regionally to the global mean differ considerably, and the linear approach likely leaves an ENSO residual.
The ENSO “residuals” are a significant contributor to the rise in Global Sea Surface Temperatures during the satellite era as we shall see. Did Foster and Rahmstorf (2011) consider these residuals in their analysis? Nope. They assumed the rise was caused by anthropogenic forcing, and they assumed a linear trend represented it.
A more recent paper was overlooked by Foster and Rahmstorf (2011). Compo and Sardeshmukh (2010) “Removing ENSO-Related Variations from the Climate Record” seems to be a step in the right direction. They write (my boldface):
An important question in assessing twentieth-century climate is to what extent have ENSO-related variations contributed to the observed trends. Isolating such contributions is challenging for several reasons, including ambiguities arising from how ENSO is defined. In particular, defining ENSO in terms of a single index and ENSO-related variations in terms of regressions on that index, as done in many previous studies, can lead to wrong conclusions. This paper argues that ENSO is best viewed not as a number but as an evolving dynamical process for this purpose.
And as Compo and Sardeshmukh have suggested, Foster and Rahmstorf (2011) have reached the wrong conclusion.
Note: Compo and Sardeshmukh missed a very important aspect of ENSO. They overlooked the significance of the huge volume of warm water that is left over from El Niño events and they failed to account for its contribution to the rise in global Sea Surface Temperature anomalies since about 1976.
Let’s not forget the much-heralded Thompson et al (2008) paper “Identifying signatures of natural climate variability in time series of global-mean surface temperature: Methodology and Insights.” Thompson et al (2008) is the basis for the new and improved HADSST3 global sea surface temperature anomaly dataset from the Hadley Centre. Thompson et al (2008), like Foster and Rahmstorf (2011), is flawed because they attempt to remove the ENSO signal from the Global Surface Temperature record and claim the remainder of the rise in surface temperature is caused by anthropogenic forcings. In the Introduction, Thompson et al (2008) write (my boldface):
In this study we exploit a series of novel methodologies to identify and filter out of the unsmoothed monthly mean time series of global-mean land and ocean temperatures the variance associated with ENSO, dynamically induced atmospheric variability, and volcanic eruptions. The impacts of ENSO and volcanic eruptions on global-mean temperature are estimated using a simple thermodynamic model of the global atmospheric–oceanic mixed layer response to anomalous heating. In the case of ENSO, the heating is assumed to be proportional to the sea surface temperature anomalies over the eastern Pacific…”
That is a monumental assumption, and it’s the same flawed assumption made by Foster and Rahmstorf (2011).
But it was that specific language in Thompson et al (2008) that caused me to divide the Sea Surface Temperature anomalies of the Global Oceans into the two subsets, and those were the East Pacific from pole to pole (90S-90N, 180-80W) and of the Rest-Of-World (Atlantic-Indian-West Pacific) from pole to pole (90S-90N, 80W-180). And by coincidence, I used the Sea Surface Temperature dataset (Reynolds OI.v2) that’s used in the GISS Land-Ocean Temperature Index, which is Tamino’s favorite global Surface Temperature anomaly dataset. I first presented the Sea Surface Temperature for those two subsets in the March 3, 2011 post Sea Surface Temperature Anomalies – East Pacific Versus The Rest Of The World. (For those who are interested, there are about a dozen additional posts that discuss ENSO and the multiyear aftereffects of specific ENSO events linked at the end of that post.)
The East Pacific Sea Surface Temperature anomalies from pole to pole, Figure 10, are dominated by the variations in tropical Pacific caused by ENSO, and as a result, the variations in the East Pacific Sea Surface Temperature anomalies mimic ENSO, represented by the scaled NINO3.4 Sea Surface Temperature anomalies. The trend of the East Pacific Sea Surface Temperature anomalies is relatively flat at 0.011 deg C/Decade.
Figure 10
The reason the trend is so flat: warm water from the surface and below the surface of the western Pacific Warm Pool is carried eastward during an El Niño and spread across the surface of the eastern tropical Pacific, raising sea surface temperatures there. And during the La Niña events that follow El Niño events, the leftover warm water is returned to the western tropical Pacific. Due to the increased strength of the trade winds during the La Nina, there is an increase in upwelling of cool subsurface waters in the eastern equatorial Pacific, so the Sea Surface Temperatures there drop. In other words, the East Pacific is simply a temporary staging area for the warm water of an El Niño event. Warm water sloshes into this dataset from the western tropical Pacific and releases heat, and then the warm water sloshes back out.
But the warm waters released from below the surface of the West Pacific Warm Pool during the El Niño are not done impacting Sea Surface Temperatures throughout the global oceans, and they cannot be accounted for by an ENSO index. That leftover warm water is returned to the West Pacific during a La Niña event that follows an El Niño, much of it remaining on the surface. The Sea Surface Temperature in the western Pacific rises as a result. At approximately 10N latitude, a slow-moving Rossby wave also carries leftover warm water from the eastern tropical Pacific back to the western Pacific during the La Niña. Ocean currents carry the warm water poleward to the Kuroshio-Oyashio Extension (KOE) east of Japan and to the South Pacific Convergence Zone (SPCZ) east of Australia, and the Indonesian Throughflow (an ocean current) carries the warm water into the tropical Indian Ocean. And as noted above, due to the increased strength of the trade winds during the La Nina, there is an increase in upwelling of cool subsurface waters in the eastern equatorial Pacific, so the Sea Surface Temperatures there drop. But that cooler-than-normal water is quickly warmed during the La Niña as it is carried west by the stronger-than-normal ocean currents that are caused by the stronger-than-normal trade winds. And the reason that water warms so quickly as it is carried west is because the stronger-than-normal trade winds reduce cloud cover, and this allows more downward shortwave radiation (visible sunlight) to warm the ocean to depth. This additional warm water helps to maintain the Sea Surface Temperatures in the West Pacific and East Indian Oceans at elevated levels during the La Niña and it also recharges the West Pacific Warm Pool for the next El Niño event. Refer again to Figure 9, but keep in mind that it presents the Ocean Heat Content for the entire tropical Pacific, not just the Pacific Warm Pool.
And what happens when a major El Niño event is followed by a La Niña event? The Sea Surface Temperature anomalies for the Atlantic, Indian, and West Pacific Oceans (the Rest-Of-The-World outside of the East Pacific) first rise in response to the El Niño; the 1986/87/88 and 1997/98 El Niño events. Then the Sea Surface Temperatures of the Atlantic, Indian, and West Pacific Oceans are maintained at elevated levels by the La Niña; the 1988/89 and 1998/99/00/01 La Niña events. The results are the apparent upward shifts in the Sea Surface Temperature anomalies of the Atlantic, Indian, and West Pacific Oceans from pole to pole (90S-90N, 80W-180), as illustrated in Figure 11.
Figure 11
The dip and rebound starting in 1991 is caused by the volcanic aerosols emitted by the explosive volcanic eruption of Mount Pinatubo. And the reason the Rest-Of-The-World Sea Surface Temperature anomalies respond so little to the 1982/83 Super El Niño is because that El Niño was counteracted by the eruption of El Chichon in 1982.
To assure readers that the upward shifts in Rest-Of-The-World Sea Surface Temperature anomalies coincide with the 1986/87/88 and 1997/98 El Niño events, I’ve included an ENSO index, NINO3.4 Sea Surface Temperature anomalies, in Figure 12. The NINO3.4 Sea Surface Temperature anomalies have been scaled (multiplied by a factor of 0.12) to allow for a better visual comparison and shifted back in time by 6 months to account for the time lag between the variations in NINO3.4 Sea Surface Temperature anomalies and the response of the Rest-Of-The-World data.
Figure 12
But the ENSO Index data is visually noisy and it detracts from the upward shifts, so in Figure 13 I’ve isolated the data between the significant El Niño events. To accomplish this, I used the NOAA Oceanic Nino Index (ONI) to determine the official months of those El Niño events. There is a 6-month lag between NINO3.4 SST anomalies and the response of the Rest-Of-The-World SST anomalies during the evolution phase of the 1997/98 El Niño. So the ONI data was lagged by six months, and the Rest-Of-The-World SST data that corresponded to the 1982/83, 1986/87/88, 1998/98, and 2009/10 El Niño events was excluded—left as black dashed lines. All other months of data remain.
Figure 13
And to help further highlight the upward shifts, the average Sea Surface Temperature anomalies between the major El Niño events are added in Figure 14.
Figure 14
Based on past posts where I’ve presented the same dataset, some comments suggest the period average temperatures are misleading and request that I illustrate the linear trends. Figure 15 illustrates how flat the trends are between the 1986/87/88 and 1997/98 El Niño events and between the 1997/98 and 2009/10 El Niño events.
Figure 15
Back to the East Pacific data: If we adjust the East Pacific Sea Surface Temperature anomalies for the effects of volcanic aerosols, Figure 16, the linear trend is slightly negative. In other words, for approximately 33% of the surface area of the global oceans, Sea Surface Temperature anomalies have not risen in 30 years.
Figure 16
Note: The method used to adjust for the volcanic eruptions is described in the post Sea Surface Temperature Anomalies – East Pacific Versus The Rest Of The World, under the heading of ACCOUNTING FOR THE IMPACTS OF VOLCANIC ERUPTIONS.
And if we adjust the Rest-Of-The-World Sea Surface Temperature anomalies for volcanic aerosols, Figure 17, we reduce the effects of the dip and rebound caused by the 1991 eruption of Mount Pinatubo. And the trend of the Rest-Of-The-World data between the 1986/87/88 and 1997/98 El Niño drops slightly compared to the unadjusted data (Figure 15), making it even flatter and slightly negative.
Figure 17
In summary, ENSO is a coupled ocean-atmosphere process and its effects on Global Surface Temperatures cannot be accounted for with linear regression of an ENSO index as attempted by Foster and Rahmstorf (2011)–and others before them. We can simply add Foster and Rahmstorf (2011) to the list of numerous papers that make the same error. Examples:
Lean and Rind (2009) How Will Earth’s Surface Temperature Change in Future Decades?
And:
Lean and Rind (2008) How Natural and Anthropogenic Influences Alter Global and Regional Surface Temperatures: 1889 to 2006
And:
Santer et al (2001), Accounting for the effects of volcanoes and ENSO in comparisons of modeled and observed temperature trends
And:
Thompson et al (2008), Identifying signatures of natural climate variability in time series of global-mean surface temperature: Methodology and Insights
And:
Trenberth et al (2002) Evolution of El Nino–Southern Oscillation and global atmospheric surface temperatures
And:
Wigley, T. M. L. (2000), ENSO, volcanoes, and record-breaking temperatures
Additionally, Foster and Rahmstorf (2011) assumed that the global warming signal is linear and that it is caused by anthropogenic forcings, but those assumptions are not supported by the satellite-era Sea Surface Temperature record as shown above. The global warming signal is not linear, and the El Niño events of 1986/87/88 and 1997/98 are shown to be the cause of the rise in sea surface temperatures, not anthropogenic greenhouse gases.
THE ATLANTIC MULTIDECADAL OSCILLATION
Those who have downloaded Tamino’s allfit2.xls file here (and changed it back to a .zip file) will notice that the data in Column AA is identified as “AMO”. And yes, that is Atlantic Multidecadal Oscillation data from the NOAA Earth System Research Laboratory (ESRL) AMO website.
Note: The current AMO data and the data listed in Tamino’s file are slightly different. The reason: The ESRL AMO data is constantly evolving. Each month, when the new North Atlantic (0-70N, 80W-0) Sea Surface Temperature data are added, the data is detrended with the new data.
One could only speculate why Tamino included the AMO data in the spreadsheet–and why the data in the spreadsheet extends back to 1950, when the paper only deals with the period of 1979 to 2010. And one can also wonder why Tamino would include the ESRL AMO data, which is based on Kaplan North Atlantic Sea Surface Temperature anomaly data, when no surface temperature datasets (GISS, HADCRUT or NCDC) use Kaplan SST. It’s like subtracting the Hadley Centre’s CRUTEMP land surface temperature data from GISS LOTI data to determine the Sea Surface Temperature portion of GISTEMP LOTI data. The datasets are not the same. I’ve already pointed this error out to Tamino and his disciples in the post Comments On Tamino’s AMO Post.
But for example, let’s satisfy your curiosity. Let’s assume you were wondering what the results would be if you were to account for the impact of the AMO on Northern Hemisphere surface temperatures, using a linear regression analysis with the ESRL AMO data as the independent variable and with GISS Northern Hemisphere Surface Temperature data as the dependent variable. We’ll confine the example to the Foster and Rahmstorf (2011) time period of 1979 to 2010. Refer to Figure 18. The AMO-adjusted Northern Hemisphere surface Temperature has a linear trend that is only 41% of the unadjusted Northern Hemisphere data. Hmm. That would mean the AMO was responsible for 59% of the rise in Northern Hemisphere surface temperatures based on linear regression analysis.
Figure 18
And that’s in line with generalization made by Tamino’s associates at RealClimate in their Atlantic Multidecadal Oscillation (“AMO”)webpage. There they write that the AMO is:
A multidecadal (50-80 year timescale) pattern of North Atlantic ocean-atmosphere variability whose existence has been argued for based on statistical analyses of observational and proxy climate data, and coupled Atmosphere-Ocean General Circulation Model (“AOGCM”) simulations. This pattern is believed to describe some of the observed early 20th century (1920s-1930s) high-latitude Northern Hemisphere warming and some, but not all, of the high-latitude warming observed in the late 20th century. The term was introduced in a summary by Kerr (2000) of a study by Delworth and Mann (2000).
59% is definitely “some, but not all”.
Tamino continues to complain that one can’t make adjustments for the AMO because it includes a global warming component. For example, in a response to a December 22, 2011 at 6:11 pm comment by Colin Aldridge,Tamino writes:
As for AMO, unlike ENSO (or PDO for that matter) it IS temperature. Pure and simple, nothing more nothing less. Attributing temperature change to temperature change seems kinda stupid.
Hmm. I believe Tamino misses the point that the AMO is a mode of additionalvariability and that it is detrended over the entire term of the data.
Further to this end, I discussed and illustrated for Tamino that we can subtract the “warming signal” of the Global Sea Surface Temperature anomalies excluding the North Atlantic from the North Atlantic Sea Surface Temperature anomalies. That way we’re left with only the additional variability of North Atlantic Sea Surface Temperature anomalies caused by the AMO. And that’s really how the AMO should be expressed. We’ll call the difference the North Atlantic Residual. The North Atlantic Residual has, approximately, the same trend as the AMO for the 1979 to 2010 period of Foster and Rahmstorf (2011), as shown in Figure 19.
Figure 19
Note: The North Atlantic Residual data presented in Figure 16 is based on the combination of HADISST data for the years 1979 to November 1981 and Reynolds OI.v2 SST data from December 1981 to present in agreement with the GISS recipe listed on their GISS Surface Temperature Analysis webpage. To remove the North Atlantic Sea Surface Temperature data from the Global data, the North Atlantic surface area for the coordinates of 0-70N, 80W-0 was determined to represent 11% of the surface area of the global oceans.
And as an additional check of the sign of the solar correction, I performed multiple linear regression analyses with GISS Northern Hemisphere Surface Temperature data as the dependent variable and using the AMO data as an independent variable in one instance and the North Atlantic Residual data in a second. The analyses also included the ENSO (MEI), Solar (PMOD), and Volcanic Aerosols (AOD.NH) as independent variables with the same lags as the global data. In both instances, the sign of the solar correction was the opposite of what Foster and Rahmstorf (2011) were looking for, as shown in equations 12 and 13:
EQUATION 12:
GISS.NH = 62.25 + 0.001696MEI (4m lag) – 0.04528TSI.PMOD(1m lag)– 1.683AOD.NH (7m lag) + 0.866AMO (0m lag)
EQUATION 13:
GISS.NH = 72.12 + 0.04751MEI (4m lag) – 0.05258TSI.PMOD(1m lag)– 2.413AOD.NH (7m lag) + 0.72N. Atl. Residual (0m lag)
A closing AMO note: For an additional discussion on how the North Atlantic impacts the Sea Surface Temperatures of the periods between the upward shifts caused by the 1986/87/88 and 1997/98 El Niño events, refer to the post Supplement To “ENSO Indices Do Not Represent The Process Of ENSO Or Its Impact On Global Temperature”.
CLOSING COMMENTS
I found the inclusion of a linear trend in the regression analyses performed by Foster and Rahmstorf (2011) to be very interesting. It appears the linear trends were included simply to cause a solar correction that was the sign the authors wanted for their adjustments. One might think, if the basic results of the paper were dependent on whether a linear trend was included in the multiple regression analyses, this would have been discussed in the paper. And again, if you have the capability, and if you’re not satisfied with the similarities between my results and the Foster and Rahmstorf (2011) results (Figures 7 and 8), please confirm the multiple regression analyses results presented above with and without the linear trend.
This post also illustrated and discussed the error in their assumption that regression analysis can be used to remove the impacts of ENSO on Global Surface Temperature. ENSO is a process that is not fully represented by ENSO Indices. In other words, the ENSO indices only represent a small portion of the impacts of ENSO on Global Surface Temperatures. Attempting to use an ENSO index as Foster and Rahmstorf (2011) have done is like trying to provide the play-by-play for a baseball game solely from an overhead view of home plate.
The assumption made by Foster and Rahmstorf (2011) that a linear trend provides an approximate “global warming” signal was shown to be erroneous using Sea Surface Temperature data. When broken down into two logical subsets of the East Pacific and the Atlantic-Indian-West Pacific Oceans, Satellite-era Sea Surface Temperature data shows no evidence of an anthropogenic global warming signal. It only shows upward shifts associated with strong ENSO events. This would seem to complicate any attempt to justify the inclusion of the linear trend to reverse the sign of the solar adjustment.
And thanks to Tamino for including the Atlantic Multidecadal Oscillation data in his spreadsheet. It allowed me to illustrate the significant impact the AMO can have on Northern Hemisphere surface temperatures.
Happy New Year to all.
ABOUT: Bob Tisdale – Climate Observations
SOURCES
The spreadsheet that served as the source of the data for the regression analyses was linked to Tamino’s (Grant Foster’s) post Data and Code for Foster & Rahmstorf 2011.
To save you some time, here’s a copy of the file that contains the spreadsheet from Tamino’s blog that I’ve uploaded to mine, allfit2 as of 12-21-11. Again, you’ll have to download the file and change it to a .zip file in order to open it.
The Reynolds OI.v2 Sea Surface Temperature data used in the ENSO discussion is available through the NOAA NOMADS website here.
The Aerosol Optical Thickness data used in the volcano adjustments of the Sea Surface Temperature data in Figures 13 and 14 is available from GISS the Stratospheric Aerosol Optical Thickness webpage here.
ferd berple says:
January 4, 2012 at 8:34 am
the decay seemed to vary with the seasons, with the rate a little faster in the winter and a little slower in the summer.
So radium atoms know about winter in the Northern Hemisphere or do they change their decay rate when they cross the equator…
So I took the moderator’s advice and looked up the other contributions by “A physicist”. After wasting 15 minutes of my life that I will never get back, I am forced to sadly conclude that he is nothing more than a concern troll. He has one pet issue which is to comment, generally sarcastically, on the concept of “rational skepticism” on this site. Substantive contributions by our friend are a rarity. He is also conveniently blinkered and appears to have never questioned any aspect of “mainstream” AGW theory. This thread is a good example where he is quick to proclaim support for the “overall methodology of the F&R article” but somehow completely ignores BT’s primary argument that ENSO is incorrectly treated.
It is a testimony to the tolerance of the administrators here that “A physicist” is still allowed to post. He would have been banned from RealClimate or Open Mind in the proverbial heartbeat.
Wayne2, regarding your well-worded and well-structured comment at January 4, 2012 at 7:29 am:
Thanks for the clarification and summation from your point of view.
Regards
@Fred: No, the coefficient for tau is not nearly 1.
Wayne2 writes,
“@Fred: No, the coefficient for tau is not nearly 1.”
I wondered that too. The whole point of F&R is that the coefficient on time (i.e., that linear trend) is about 0.017 (or 0.17 degrees C/decade), which is in the same ballpark as all other estimates of the recent trend. Yet Tisdale’s equation 2 above gives a coefficient on time of 1.024, as Berple has repeatedly mentioned:
“GISS = -91.43 + 1.024Trend + 0.0761MEI(4m lag) + 0.06694TSI.PMOD(1m lag)- 2.334AOD (7m lag)”
If 1.024 really were the coefficient on time, it would imply a 1.024 degrees C/year rate of warming, which nobody anywhere has claimed. What’s going on with Tisdale’s equation? It can’t be what it seems.
Actually, the WUWT moderators have created a special queue for my posts, and a pretty fair fraction of them are not allowed to see the light of day.
Particularly likely to be censored (in my experience) are posts that link to survey articles — meaning, articles that broadly survey and summarize the existing scientific evidence — and that invite WUWT readers to read-and-reflect upon those articles.
No other scientific and/or skeptical forum (that is known to me) practices a brand of selective censorship that seeks to discourage citizens from reading the scientific literature (although many political forums do this, obviously).
And it is troubling that some WUWT readers may not even realize that this censorship is routinely imposed upon them.
WUWT, indeed?
REPLY: Dr. Sidles, you have 188 approved comments here, so your claims of “censorship” are baseless. Since you have had a long history of thread bombing, off topic rants, and a tendency to denigrate not only other commenters, but also the moderators and the host on a regular basis, you indeed have been assigned “troll bin status”. That means every one of your posts goes into the moderation que to receive an extra level of attention for consideration of approval. A good number of your posts don’t meet the criteria for publication here (though your ego will no doubt say they are all valid) so they simply are culled for not meeting policy. You are not singled out, commenters on both sides of the issue find their comments snipped for failure to adhere to policy, as is my right.
As I say in my policy page, this is my home on the Internet, and generally I expect people to act like they are talking to me in my living room. You have on occasion made comments that if you were in my living room, I’d kick your butt out the door. OTOH you have on occasion made some rational arguments, so you live in limbo.
This situation is of your own making, and it has do to with your attitude, condescension, and off topic thread bombing. You can improve the situation by improving your attitude and learn to respect others. If you don’t wish to change, then consider this an invitation to leave, permanently – Anthony
P.S. Whining about this won’t become another off-topic discussion
@A Physicist: I’m not sure your summary is quite right. I think many of us are arguing the F&R is statistically reasonable, but that doesn’t mean that their model isn’t flawed by lumping into a single linear trend a bunch of unidentifiable stuff it labels as “AGW”. The causal/physical aspects of the F&R model are more problematic than BT’s statistical objections.
Their summary says, “Perhaps most important, it enables us to remove an estimate of their influence, thereby isolating the global warming signal. The resultant adjusted data show clearly, both visually and when subjected to statistical analysis, that the rate of global warming due to other factors (most likely these are exclusively anthropogenic) has been remarkably steady during the 32 years from 1979 through 2010.”
First, they don’t establish that there are no other factors that are stronger than those they considered. Second, they don’t prove that a linear trend is physically appropriate, nor that it is superior to alternatives (i.e. non-linear trends). Third, they assume but don’t prove that the warming trend is “exclusively” man-made (I guess this is similar to my first objection). In short, they have a nice model that passes various diagnostics, but there’s no proof that their model is actually explanatory or realistic. My several postings have been to tell Bob that he needs to focus his assault on their assumptions rather than leading with a probably-mistaken attack on their statistical methods. (Though I imagine he would not view it this way.)
@Gneiss: It appears to me that Bob’s units for time is 60 years. Tau doesn’t appear in the .cvs files, but rather in the R files, and I imagine Bob just made tau range from 0 to 1 over the length of the .csv file. That’d make it about 60 times what F&R (and mine): 0.01710741 * 60 = 1.026445.
Please let me do so by thanking you for your sustained hard work (and the sustained hard work of the moderators too) in making WUWT a forum where skeptic and non-skeptic engage one another — vigorously of course! — upon a basis of reason and mutual respect.
It is very important that such forums exist, and so the above appreciation is extended with complete sincerity and gratitude, in which (IMHO) pretty much everyone who posts here is joined.
Wayne2, thanks for the explanation, odd though it is. Tisdale can perhaps explain why he chose to rescale time instead of keeping years for the units, as F&R and everyone else does.
A couple of thoughts on your comments:
“First, they don’t establish that there are no other factors that are stronger than those they considered.”
You know that’s not possible, right? What is possible is to suggest other factors that you think might be stronger, test whether they are, then interpret and write up the results for discussion, replication, discussion, and close scrutiny just as F&R did.
“Second, they don’t prove that a linear trend is physically appropriate, nor that it is superior to alternatives (i.e. non-linear trends).”
Linearity is always a simplifying assumption. So are all kinds of nonlinear curves, though they become increasingly un-simple until eventually they fit perfectly, being just as complicated as the data. With more parameters a curve will fit better, so the question is not whether linearity is superior, but whether the curve (given its greater complexity) is superior. But yes, they did test simple nonlinear (quadratic) alternatives, and found them no better. Quoting F&R:
Only one of the data sets, the UAH series, showed a statistically significant quadratic term (p-value 0.03). It indicates acceleration of the warming trend at a rate of 0.006 C/decade/yr. However, we regard this acceleration with skepticism because it shows in no other data set, not even the other satellite record.
“Third, they assume but don’t prove that the warming trend is “exclusively” man-made (I guess this is similar to my first objection).”
You keep saying “prove” but that word doesn’t appear in their article. What F&R do is demonstrate empirically that three natural factors well known to influence global temperature cannot account for the observed warming trend, using any of the 5 indexes.
Think they left something out? Suggest your own factors, do the math, and show the world what you get. People surely are working on that right now.
This thread has probably done its dash but a couple more comments to help some of the recalcitrant ones who think data mining is a substitute for science.
Gneiss @ur momisugly January 4, 2012 at 6:52 am
“This [Tisdale’s effort] is not a ‘technocrat’ issue but a really basic, first-year student mistake that undermines the whole post. “
I went looking for some resources that might help you understand some of the subtleties at play here and found “The role of causal reasoning in understanding Simpson’s paradox, Lord’s paradox, and the suppression effect: covariate selection in the analysis of observational studies” Onyebuchi A Arah, Emerg Themes Epidemiol. 2008; 5: 5. You’ll have to read the paper being commented on – Tu Y-K, Gunnell DJ, Gilthorpe MS. “Simpson’s paradox, Lord’s paradox, and suppression effects are the same phenomenon – the reversal paradox” Emerg Themes Epidemiol. 2008;5:2
“F&R are not data mining”
If you go back and look at the F&R code quoted by SRJ @ur momisugly January 3, 2012 at 1:59 am, just how many times did they go around that loop? How much data did they hold out? What are the odds of a good result regardless?
“The F&R paper is grounded both in statistical competence (statistician F’s specialty) and in physical understanding (oceanographer R’s specialty).”
Statisticians and oceanographers can make good data miners I’m sure.
“F&R is the kind of paper that will invite replication, improvement, or challenge from other scientists who also understand the tools and the substance.”
It would be a pity if too much effort goes into replicating simple linear models of global climate temperature such as this and the earlier Lean and Rind contributions. We need (and science can deliver) better hypotheses to test than GISS is a linear function of time, MEI, TSI and AOD (with an adjustment for a residue annual cycle in the data). As I said useful for the chartists, perhaps good for the politics of climate change, but hardly something that will carry forward the science.
I would finally note the appropriate outcomes from a fishing expedition like this are hypotheses for testing, not conclusions.
Wayne2 @ur momisugly January 4, 2012 at 7:29 am reinforces my point about the separation between causal and statistical models, but I’d further make the point (in line with the discussion by Arah mentioned above) that the statistical model is subservient to the causal model in these circumstances. Therefore it is generous of Wayne2 to conclude “F&R’s statistics seem reasonable to me, given their assumptions, and arguing with tau or arguing sign flips, etc, is questionable and weak”. As I’ve noted the flipped sign and the inclusion of time tells you we have a potentially poorly specified casual model, and hence any subsequent statistical analysis is hand waving.
I hope that last comment also clarifies the question asked by Wayne2 @ur momisugly January 4, 2012 at 7:36 am. I think the issue may be just semantic – it is on the face of it an “illogical model of GISS”. While in this case we can easily reject it as a physical model I can imagine universes where it made perfect physical sense.
Finally in respect of Wayne2 @ur momisugly January 4, 2012 at 11:19 am “they don’t prove that a linear trend is physically appropriate, nor that it is superior to alternatives” the fact that Ln(YEAR) is virtually as good in GISS is perhaps An Inconvenient Truth.
A physicist @ur momisugly January 4, 2012 at 7:47 am while indulging in similar back scratching of Gneiss extols the virtues of rational scepticism, and adds: “Rational skepticism has to approve the F&R style of predictive, testable, independently-verifiable science.”
Model building not grounded in the body of empirical science hardly seems to pass muster as rational scepticism – but that aside at least as A physicist says, the forecasts are testable. But they are limited in their testability to their performance as a forecast tool. If the forecast is wrong we have no physical underpinnings to refer back to help tell us what went wrong.
I should perhaps note that I am not arguing against stochastic model building per se (in fact I think GCMs are at the point of diminishing returns, and stochastic modelling is required to move them forward). I am saying however that doing data mining on a limited dataset and a very limited model with no reference to the body of scientific knowledge we have of the system in question is a doubtful use of bandwidth.
I’m also surprised at the lack of willingness for many to put their brains in gear on this issue. I say it is the fault of all these damn computers. If you’d had to invert all those matrices by hand we wouldn’t have this over fitting nonsense, throwing everything at everything.
We’d hopefully have people thinking about what is actually going on out there.
A physicist says: “It’s a good thing that so many WUWT posters have replicated the F&R calculations for themselves. Moreover, it’s a good thing that the majority of WUWT posters (Bob Tisdale being the main exception) approve of the overall methodology of the F&R article.”
I have not counted the number of bloggers here who have expressed approval of F&R’s methods, nor do I intend to. But I will note that those who have approved, like you, have apparently failed to understand the significance of the second portion of my post. That part plainly illustrates and discusses how the impacts of ENSO on Global Temperatures cannot be removed through regression analyses using an ENSO index as an independent variable. Some on this thread have argued quite well for the benefits of the F&R model with great understanding of its content, but the basic fact is, ENSO cannot be accounted for as F&R has attempted to do, and that voids all of their arguments.
Have a nice day.
HAS writes,
“How much data did they hold out? What are the odds of a good result regardless?”
The fact that I and others have so easily replicated their basic conclusion, using varied and generally simpler approaches, confirm what F&R said: their results are robust. The iterative methods for chosing lags made marginal improvements but are not needed for the main conclusions. Some alternative but substantively less definitive measures of solar, volcanic and ENSO effects were tested and again reached essentially the same conclusions. None of this is what “data mining” means.
“fact that Ln(YEAR) is virtually as good in GISS is perhaps An Inconvenient Truth.”
It’s obvious and nothing of the kind. Since a nonlinear trend offers no improvement, Occam votes for linear.
Wayne2 says: “It appears to me that Bob’s units for time is 60 years.”
And Gneiss says: “Wayne2, thanks for the explanation, odd though it is. Tisdale can perhaps explain why he chose to rescale time instead of keeping years for the units, as F&R and everyone else does.”
My dependent and independent variables include only 384 months of data. When I included a linear trend as an independent variable, I used the monthly values of the trend that EXCEL determined for the dependent variable.
Bob Tisdale writes,
“My dependent and independent variables include only 384 months of data. When I included a linear trend as an independent variable, I used the monthly values of the trend that EXCEL determined for the dependent variable.”
OK, maybe now I get it. Do you mean that you regressed GISS on MEI, AOD, TSI and — as your fourth predictor — on on the predicted values from a simple regression of GISS on year?
@ur momisugly fred berple says:
By including Trend(GISS) as an independent variable they have eliminated GISS. [etc.]
Thanks! I’ve just read Bob’s most excellent analysis and was almost surprised myself by F&R’s need for a “Trend” to allegedly explain or reveal a trend, but recovered quickly enough – given that it is, after all, the “methods” of genuine Climate “Science” that we are witnessing before us.
JPeden writes,
“@ur momisugly fred berple says:
By including Trend(GISS) as an independent variable they have eliminated GISS. [etc.]
Thanks! I’ve just read Bob’s most excellent analysis and was almost surprised myself by F&R’s need for a “Trend” to allegedly explain or reveal a trend, but recovered quickly enough – given that it is, after all, the “methods” of genuine Climate “Science” that we are witnessing before us.”
No, F&R didn’t do it that way, Tisdale did. He thought that “including a trend” meant literally that you used predicted values calculated from that trend as one of your predictor variables. So on the left hand side of Tisdale’s equation he has GISS, and on the right hand side as one of the predictors of GISS he has GISS predicted from time.
Hence the strange near-1 coefficient that confused berple several times above, and the strange way Tisdale talked about “trend” that confused me and others.
Gneiss says:
January 4, 2012 at 3:55 pm
No, F&R didn’t do it that way, Tisdale did.
No , Bob Tisdale is saying that including the mentioned but not discussed trend is either one of the ways, or maybe even the only way F&R can get the results they want, once they’ve also decided to make the solar forcing sign negative. For example, Bob says and quotes:
Foster and Rahmstorf (2011) have added a fourth variable: linear trend. The last sentence of the third paragraph under the heading of “Introduction” reads:
“The influence of exogenous factors will be approximated by multiple regression of temperature against ENSO, volcanic influence, total solar irradiance (TSI) and a linear time trend to approximate the global warming that has occurred during the 32 years subject to analysis”
Etc., etc..
Wake me up when Climate Science gets anything of a relevant nature to the alleged hypotheses involving “CO2 = CAGW” right. Especially empirical predictions.
Leif Svalgaard says:
January 4, 2012 at 9:16 am
So radium atoms know about winter in the Northern Hemisphere or do they change their decay rate when they cross the equator…
According to GR, time passes slowest during the NH winter.
“JPeden says:
January 4, 2012 at 5:08 pm
a linear time trend to approximate the global warming that has occurred during the 32 years subject to analysis”
Which has the effect of removing the trend from GISS, so that the other time dependent factors such as PDO will appear to have no effect.
solve
GISS (t) = b + delta(GISS(t)) / delta(t) + PDO(t)
The solution is
-b = PDO(t)
Therefore PDO(t) is constant, therefore PDO has no effect on temperature.
correction:
Therefore PDO(t) is constant, therefore PDO has no effect on temperature CHANGE over time.
Leif Svalgaard says:
January 4, 2012 at 4:21 am
That is a false argument, as I specifically object to your unfounded claim that EUV is the major driver of climate. Baldwin does not mention EUV at all, as the QBO does not extend above the mesosphere. And, BTW, the chemistry is controlled more by the QBO than the other way around.
The claim is not unfounded and the main point is the chemical solar connection to climate that is not being addressed in this whole exercise. Any study that tries to isolate climate drivers without looking at the solar chemical connection is unfounded. But glad to see you finally admit this connection even if you wrongly think there is only a small effect on temperature.
Baldwin talks about UV processes that occur in the mesosphere that contribute to ozone. What you are missing is that this process happens above 120 km where an O2 molecule is split by strong UV radiation. Only UV in the band lower than 242 nm is capable of this process that makes available single oxygen molecules for later production of ozone. This firmly puts EUV in the important class. EUV is not the major driver but it and others forms of UV make up one aspect of the natural climate drivers.
Gneiss says: “OK, maybe now I get it. Do you mean that you regressed GISS on MEI, AOD, TSI and — as your fourth predictor — on on the predicted values from a simple regression of GISS on year?”
In addition to MEI, AOD, and TSI as independent variables, I used the values of the linear trend, which EXCEL calculated with its LINEST function from the monthly GISS data, as the fourth independent variable. Yes, this apparently was confusing for some. But there were others early on who understood what I had done and verified the results with other regression software. In retrospect, I should not have included the equations. I should have included a table that listed the coefficients instead.
And I just noticed that I failed to explain another portion of the post, and it may have been confusing to those who are looking at equations and graphs. I performed the regression analyses with the “raw” monthly data; then I made the adjustments to the monthly data. (I had prepared a graph using monthly data, similar to F&R’s Figure 4, with 1979-2010 as base years. But I felt my version was an unintelligible spaghetti graph with little value, so I didn’t include it.) I then converted the adjusted data to annual data; and last, changed the base years to 1979-2010. The bottom line: It’s difficult to see any difference between my Figure 7 and F&R’s Figure 5, which I included as my Figure 8.
Gneiss says: “The fact that I and others have so easily replicated their basic conclusion, using varied and generally simpler approaches, confirm what F&R said: their results are robust.”
I was also able to replicate F&R’s basic results using my primitive methods. My Figure 7 is pretty close to being a duplicate of F&R’s Figure 5, (which I included as my Figure 8). But I disagree that F&R’s results are robust for the simple reason that they assumed including an ENSO index in their regression analyses would eliminate the effects of ENSO on global surface temperatures. The second part of this post clearly illustrated that it cannot be done. The results of F&R are erroneous for that reason.
Geoff Sharp says:
January 4, 2012 at 7:00 pm
The claim is not unfounded and the main point is the chemical solar connection to climate that is not being addressed in this whole exercise. Any study that tries to isolate climate drivers without looking at the solar chemical connection is unfounded. But glad to see you finally admit this connection even if you wrongly think there is only a small effect on temperature.
You are completely off the wall here. The issue is EUV, not UV. But this is your usual straw man style.
Baldwin talks about UV processes that occur in the mesosphere that contribute to ozone. What you are missing is that this process happens above 120 km where an O2 molecule is split by strong UV radiation.
And any O3 molecule would be destroyed by the same process. And you falsely claimed that Baldwin talked about EUV. He did not. Either you did not even read his paper or you are deliberately lying and hoping nobody would notice. Which is it?
Only UV in the band lower than 242 nm is capable of this process that makes available single oxygen molecules for later production of ozone.
The O molecules above 150 km do not participate in creation of ozone. There is no ozone to speak of up there in the Thermosphere. Do you believe the O atoms move downwards? From 150 km down to the stratosphere the density increases a million-fold. And EUV is below 120 nm, BTW.
This firmly puts EUV in the important class.
This is something you make up. EUV does not create ozone, rather EUV destroys ozone.
EUV is not the major driver
You are backing off. You did call it a ‘viable’ driver of climate. That implies a significant effect. But it is good to see that you don’t think that any more.
but it and others forms of UV make up one aspect of the natural climate drivers
EUV does not. You have no evidence of that. Just what you make up. Produce some links, if you can. UV produces ~0.05 K effect at the surface, so is also not important.
You are wiggling mightily to get out of the pickle you got yourself into with this silly statement:
Geoff Sharp says:
January 2, 2012 at 9:01 pm
Using TSI as a solar proxy is one mistake made in this process and one that the warmist brigade are happy to use. Solar influence on climate (isolating PDO) is more likely a result of the large fluctuations in solar EUV
and this one:
Geoff Sharp says:
January 2, 2012 at 10:28 pm
Strange how a scientist after being shown by many that solar effects can be chemical and radiative that he continues with the same line. This can only mean an agenda is involved.
and this one:
Geoff Sharp says:
January 3, 2012 at 2:06 pm
I and others have shown you the chemical reaction along with the change in atmospheric heights are the components of EUV that science papers and bodies are now strongly suggesting as a viable climate driver.
You can check my article from June 2010 which has many links to articles and papers related to EUV and climate.
Your article does not contain a single reference or link to any such papers.
It is time to take your ball and go home, rather than try to play with the big boys.