Image Credit: WoodForTrees.org
Guest Post By Werner Brozek, Edited By Just The Facts
You may have seen the following recent articles (1, 2 and 3) by Walter Dnes on his January Leading Indicator. The same idea can also be shown in a different way. Namely, we can compare this decade to the last decade and see how things are turning out. We have all read that the 2001 to 2010 decade was the hottest in recorded history. But what has happened since then? How does 2001 compare with 2011, and 2002 with 2012, and 2003 with 2013? And what will happen in 2014?
See the above graph that shows January 2001 to January 2004 and then from January 2011 to January 2014 for RSS. Compare the left red point with the left green point. Note that the left red point is higher than the left green point indicating that January 2001 was warmer than January 2011. As it turns out, 2001 was warmer than 2011. Now compare the right red point with the right green point. Note that the right red point is higher than the right green point indicating that January 2004 was warmer than January 2014. What logical predictions can be made here?
I am now going to provide 8 pairs of numbers, however the final number in the last pair will be missing until next January. The format of the numbers is as follows:
(Jan 2001, Jan 2011); (2001 anomaly, 2011 anomaly);
(Jan 2002, Jan 2012); (2002 anomaly, 2012 anomaly);
(Jan 2003, Jan 2013); (2003 anomaly, 2013 anomaly);
(Jan 2004, Jan 2014); (2004 anomaly, 2014 anomaly?).
For the RSS data, note that in every case, the second number is lower than the first. What do you predict for *?
(0.101, 0.080), (0.246, 0.143);
(0.359, -0.064), (0.315, 0.187);
(0.440, 0.439), (0.320, 0.218);
(0.311, 0.262), (0.202, *).
Information on the prior Januaries for the other 5 data sets can be found in Section 3 below.
Are there physical reasons to explain Walter Dnes January Leading Indicator? I can think of several. Perhaps you can add to this list.
1. By the laws of averages, half of all Januaries should be above the yearly average and half should be below. So with a number of high Januaries, the final anomalies would be higher than for a number of low Januaries.
2. Related to the above, if the January anomaly went from 0.4 to 0.3, and if we assume the previous year also had an average anomaly of 0.4, and with the chances being 50% for an anomaly of less than 0.3 for the new year, the odds are greater than 50% for an anomaly of less than 0.4.
3. The number in January may be so much higher or lower that it takes 11 months of normal values to partially negate the effect of the high or low January value. To use a sports analogy, two teams may be very equal, but one team has the jitters for the first 5 minutes and is down by 3 goals in this time. It is quite possible that the rest of the game is not long enough for this deficit to be overcome. Walter’s method is analogous to being allowed to predict the outcome of a game after watching the first 5 minutes.
4. According to Bob Tisdale, effects of El Nino or La Nina often show themselves in January so in those cases, it would be obvious why the rest of the year follows.
5. Any other cycle such as a sun that getting quieter every year would automatically be reflected in the anomalies for January and the rest of the year as well.
6. Can you think of others?
In the sections below, we will present you with the latest facts. The information will be presented in three sections and an appendix.
The first section will show for how long there has been no warming on several data sets.
The second section will show for how long there has been no statistically significant warming on several data sets.
The third section will show how January of 2014 compares with 2013 and the warmest years and months on record so far. In addition to what I have presented previously, I will compare the anomalies for January 2013 with those of 2014 as well as January 2004 with those of 2014
The appendix will illustrate sections 1 and 2 in a different way. Graphs and a table will be used to illustrate the data.
Section 1
This analysis uses the latest month for which data is available on WoodForTrees.com (WFT). All of the data on WFT is also available at the specific sources as outlined below. We start with the present date and go to the furthest month in the past where the slope is a least slightly negative. So if the slope from September is 4 x 10^-4 but it is – 4 x 10^-4 from October, we give the time from October so no one can accuse us of being less than honest if we say the slope is flat from a certain month.
On all data sets below, the different times for a slope that is at least very slightly negative ranges from 9 years and 1 month to 17 years and 5 months.
1. For GISS, the slope is flat since November 2001 or 12 years, 3 months. (goes to January)
2. For Hadcrut3, the slope is flat since August 1997 or 16 years, 6 months. (goes to January)
3. For a combination of GISS, Hadcrut3, UAH and RSS, the slope is flat since January 2001 or 13 years, 1 month. (goes to January)
4. For Hadcrut4, the slope is flat since January 2001 or 13 years, 1 month. (goes to January)
5. For Hadsst3, the slope is flat since December 2000 or 13 years, 2 months. (goes to January)
6. For UAH, the slope is flat since January 2005 or 9 years, 1 month. (goes to January using version 5.5)
7. For RSS, the slope is flat since September 1996 or 17 years, 5 months (goes to January). So RSS has passed Ben Santer’s 17 years.
(P.S. The anomaly for February for RSS has come in and the time is now 17 years and 6 months going from September 1996 to February 2014.)
The next graph shows just the lines to illustrate the above. Think of it as a sideways bar graph where the lengths of the lines indicate the relative times where the slope is 0. In addition, the sloped wiggly line shows how CO2 has increased over this period.
When two things are plotted as I have done, the left only shows a temperature anomaly.
The actual numbers are meaningless since all slopes are essentially zero and the position of each line is merely a reflection of the base period from which anomalies are taken for each set. No numbers are given for CO2. Some have asked that the log of the concentration of CO2 be plotted. However WFT does not give this option. The upward sloping CO2 line only shows that while CO2 has been going up over the last 17 years, the temperatures have been flat for varying periods on various data sets.
The next graph shows the above, but this time, the actual plotted points are shown along with the slope lines and the CO2 is omitted.
Section 2
For this analysis, data was retrieved from Nick Stokes’ Trendviewer page. This analysis indicates for how long there has not been statistically significant warming according to Nick’s criteria. Data go to their latest update for each set. In every case, note that the lower error bar is negative so a slope of 0 cannot be ruled out from the month indicated.
On several different data sets, there has been no statistically significant warming for between 16 and 21 years.
The details for several sets are below.
For UAH: Since February 1996: CI from -0.042 to 2.415
For RSS: Since November 1992: CI from -0.022 to 1.900
For Hadcrut4: Since October 1996: CI from -0.027 to 1.234
For Hadsst3: Since January 1993: CI from -0.016 to 1.812
For GISS: Since September 1997: CI from -0.014 to 1.299
Section 3
This section shows data about January 2014 and other information in the form of a table. The table shows the six data sources along the top and other places so they should be visible at all times. The sources are UAH, RSS, Hadcrut4, Hadcrut3, Hadsst3, GISS. Down the column, are the following:
1. 13ra: This is the final ranking for 2013 on each data set.
2. 13a: Here I give the average anomaly for 2013.
3. year: This indicates the warmest year on record so far for that particular data set. Note that two of the data sets have 2010 as the warmest year and four have 1998 as the warmest year.
4. ano: This is the average of the monthly anomalies of the warmest year just above.
5. mon: This is the month where that particular data set showed the highest anomaly. The months are identified by the first three letters of the month and the last two numbers of the year.
6. ano: This is the anomaly of the month just above.
7. y/m: This is the longest period of time where the slope is not positive given in years/months. So 16/2 means that for 16 years and 2 months the slope is essentially 0.
8. sig: This the first month for which warming is not statistically significant according to Nick’s criteria. The first three letters of the month is followed by the last two numbers of the year.
9. Jan14: This is the January 2014 anomaly for that particular data set.
10.Jan13: This is the January 2013 anomaly for that particular data set.
11.diff: Here I simply indicate if the difference between the January 2014 number is negative or positive with respect to the January 2013 number. A negative difference indicates 2014 will be forecast to be cooler than 2013 and vice versa. See Row 1 for the 2013 rank.
12.Jan14: This is a repeat of the January 2014 anomaly for that particular data set. I am repeating row 9 for clarity as row 12 will now be compared to row 13.
13.Jan04: This is the January 2004 anomaly for that particular data set.
14.diff: Here I simply indicate if the difference between the January 2014 number is negative or positive with respect to the 2004 number. A negative difference indicates 2014 will be forecast to be cooler than 2004 and vice versa.
15.04rk: Here I give the rank in 2004 for each particular data set.
16.rnk: This is the rank that each particular data set would have if the anomaly for January 2014 were to remain that way for the rest of the year. Of course it will not, but think of it as an update 5 minutes into a game. Due to different base periods, the rank is more meaningful than the average anomaly.
| Source | UAH | RSS | Had4 | Had3 | Sst3 | GISS |
|---|---|---|---|---|---|---|
| 1. 13ra | 7th | 10th | 8th | 6th | 6th | 6th |
| 2. 13a | 0.197 | 0.218 | 0.486 | 0.459 | 0.376 | 0.60 |
| 3. year | 1998 | 1998 | 2010 | 1998 | 1998 | 2010 |
| 4. ano | 0.419 | 0.55 | 0.547 | 0.548 | 0.416 | 0.66 |
| 5. mon | Apr98 | Apr98 | Jan07 | Feb98 | Jul98 | Jan07 |
| 6. ano | 0.662 | 0.857 | 0.829 | 0.756 | 0.526 | 0.93 |
| 7. y/m | 9/1 | 17/5 | 13/1 | 16/6 | 13/2 | 12/3 |
| 8. sig | Feb96 | Nov92 | Oct96 | Jan93 | Sep97 | |
| Source | UAH | RSS | Had4 | Had3 | Sst3 | GISS |
| 9.Jan14 | 0.235 | 0.262 | 0.506 | 0.472 | 0.341 | 0.70 |
| 10.Jan13 | 0.504 | 0.439 | 0.450 | 0.392 | 0.292 | 0.63 |
| 11.diff | neg | neg | pos | pos | pos | pos |
| 12.Jan14 | 0.235 | 0.262 | 0.506 | 0.472 | 0.341 | 0.70 |
| 13.Jan04 | 0.184 | 0.311 | 0.516 | 0.504 | 0.359 | 0.56 |
| 14.diff | pos | neg | neg | neg | neg | pos |
| 15.04rk | 12th | 11th | 11th | 7th | 9th | 13th |
| Source | UAH | RSS | Had4 | Had3 | Sst3 | GISS |
| 16.rnk | 4th | 6th | 4th | 5th | 11th | 1st |
(P.S. The RSS anomaly for February is in and it has a value of 0.162. When averaged with the January anomaly of 0.262, it comes to 0.212 and this would make 2014 rank 11th if it stayed this way.)
What can we conclude from the two sets of differences above? Below, I will assume that Walter Dnes’ qualitative prediction holds true and give the results.
For UAH, the final rank would be colder than 7th but warmer than 12th.
For RSS, the final rank would be colder than 11th.
For Hadcrut4, the final rank would be colder than 11th but warmer than 8th.*
For Hadcrut3, the final rank would be colder than 7th but warmer than 6th.*
For Hadsst3, the final rank would be colder than 9th but warmer than 6th.*
For GISS, the final rank would be warmer than 6th.
*Obviously we cannot have any contradictions. As Walter explained, there is a lot of noise in these numbers. To find the true prediction, we need to find the place that January 2014 fits on the best fit line. The January 2004 numbers were closer to the line on Walter’s graphs, so they would give the most reliable estimate in my opinion. Note that my numbers are for version 5.5 for UAH and I have numbers for Hadsst3 that Walter does not have, so I cannot comment on those. However it seems as if the odds favour cooling according to Walter.
See the following graph:
All graphs have been offset so they start at 0.4 for January 2004. So to see if 2014 is expected to be colder or warmer than 2004, see if the final point, namely January 2014, is above or below 0.4. But keep in mind this is only a qualitative estimate.
If you wish to verify all of the latest anomalies, go to the following:
For UAH, version 5.5 was used since that is what WFT used.
http://vortex.nsstc.uah.edu/public/msu/t2lt/tltglhmam_5.5.txt
For RSS, see: ftp://ftp.ssmi.com/msu/monthly_time_series/rss_monthly_msu_amsu_channel_tlt_anomalies_land_and_ocean_v03_3.txt
For HadCRUT4, see: http://www.metoffice.gov.uk/hadobs/hadcrut4/data/current/time_series/HadCRUT.4.2.0.0.monthly_ns_avg.txt
For HadCRUT3, see: http://www.cru.uea.ac.uk/cru/data/temperature/HadCRUT3-gl.dat
For HadSST3, see: http://www.cru.uea.ac.uk/cru/data/temperature/HadSST3-gl.dat
For GISS, see: http://data.giss.nasa.gov/gistemp/tabledata_v3/GLB.Ts+dSST.txt
To see all points since January 2013 in the form of a graph, see the WFT graph below:
As you can see, all lines have been offset so they all start at the same place in January. This makes it easy to compare last January 2013 with January 2014.
Appendix
In this part, we are summarizing data for each set separately.
RSS
The slope is flat since September 1996 or 17 years, 5 months. (goes to January) So RSS has passed Ben Santer’s 17 years.
For RSS: There is no statistically significant warming since November 1992: CI from -0.022 to 1.900.
The RSS anomaly for January is 0.262. This would rank it in 6th place if it stayed this way. 1998 was the warmest at 0.55. The highest ever monthly anomaly was in April of 1998 when it reached 0.857. The anomaly in 2013 was 0.218 and it is ranked 10th.
(P.S. The anomaly for February for RSS has come in and the time is now 17 years and 6 months going from September 1996 to February 2014. Also, when the February anomaly of 0.162 is averaged with the January anomaly of 0.262, it comes to 0.212 and this would make 2014 rank 11th if it stayed this way.)
UAH
The slope is flat since January 2005 or 9 years, 1 month. (goes to January using version 5.5)
For UAH: There is no statistically significant warming since February 1996: CI from -0.048 to 2.415.
The UAH anomaly for January is 0.235. This would rank it in 4th place if it stayed this way. 1998 was the warmest at 0.419. The highest ever monthly anomaly was in April of 1998 when it reached 0.662. The anomaly in 2013 was 0.197 and it is ranked 7th.
Hadcrut4
The slope is flat since January 2001 or 13 years and 1 month. (goes to January)
For Hadcrut4: There is no statistically significant warming since October 1996: CI from -0.027 to 1.234.
The Hadcrut4 anomaly for January is 0.506. This would rank it in 4th place if it stayed this way. 2010 was the warmest at 0.547. The highest ever monthly anomaly was in January of 2007 when it reached 0.829. The anomaly in 2013 was 0.486 and it is ranked 8th.
Hadcrut3
The slope is flat since August 1997 or 16 years, 6 months. (goes to January)
The Hadcrut3 anomaly for January is 0.472. This would rank it in 5th place if it stayed this way. 1998 was the warmest at 0.548. The highest ever monthly anomaly was in February of 1998 when it reached 0.756. One has to go back to the 1940s to find the previous time that a Hadcrut3 record was not beaten in 10 years or less. The anomaly in 2013 was 0.459 and it is ranked 6th.
Hadsst3
For Hadsst3, the slope is flat since December 2000 or 13 years and 2 months. (goes to January).
For Hadsst3: There is no statistically significant warming since January 1993: CI from -0.016 to 1.812.
The Hadsst3 anomaly for January is 0.341. This would rank it in 11th place if it stayed this way. 1998 was the warmest at 0.416. The highest ever monthly anomaly was in July of 1998 when it reached 0.526. The anomaly in 2013 was 0.376 and it is ranked 6th.
GISS
The slope is flat since November 2001 or 12 years, 3 months. (goes to January)
For GISS: There is no statistically significant warming since September 1997: CI from -0.014 to 1.299.
The GISS anomaly for January is 0.70. This would rank it as 1st place if it stayed this way. 2010 was the warmest at 0.66. The highest ever monthly anomaly was in January of 2007 when it reached 0.93. The anomaly in 2013 was 0.60 and it is ranked 6th.
Conclusion
According to Walter’s criteria, the message seems to be rather mixed as to whether we will have cooling or warming this year. At times, the qualitative indication is opposite to the quantitative indication. This shows that there is quite a bit of noise in the data. Overall, there seems to be a greater indication of cooling. My inclination is to trust the quantitative number in these cases to give the best indication as to where we are headed.
I would say that unless a very strong El Nino develops fairly quickly, there will be little change this year and the length of the period of no warming will continue to increase. As well, the period of no statistically significant warming will also increase this year unless we have an El Nino. Do you agree?
Mike McMillan says:
March 9, 2014 at 1:44 pm
“1. By the laws of averages, half of all Januaries should be above the yearly average and half should be below.”
I think you mean “median,” not “average.”
+++++++++++++++++++++++++++++++++++++++++++++++++++++++
Mathematical point of order:
MEDIAN is the center point of an ordered (ascending or descending) set of discrete data;
MODE is the most frequently appearing value in a set of discrete data;
MEAN is the “average” of a set of discrete data;
Statements about data distribution (e.g.: half January values above & half below) must either be based on actual data analysis (e.g.: by observation, half the January data points were above the MEAN…) or assumptions about the statistical distribution of data. The statement that “…half the January data is above & below the MEAN and/or MEDIAN…” assumes data is normally distributed (“normal distribution” is one of several specific statistical distributions, and requires MEAN = MEDIAN = MODE), which seems to be inaccurate for the limited data set under discussion.
I apologize for having hijacked this thread about the decades. Was not my intention! Did not realize my comment would be the first. Sorry! Thanks also to those who pointed out that meteorologists typically go “1” to “0”.
“You’re getting a mention on several climate blogs …”
Cotton is spamming that blog too? Unreal.
1. 4 years is not a decade.
2. I do not believe any such analysis can predict what the trend will be this year.
wbrozek says:
March 9, 2014 at 2:55 pm
. If you can prove that this assumption is totally out to lunch, be my guest.
I don’t have a dog in the hunt, and was only trying to be helpful. With the little I know about temperatures, I can see no reason, a priori, why one would necessarily believe that there are as many Januaries above the average as below. In fact, I would find such a discovery rather remarkable, given that the temperature time-series seems to be widely known to be non-stationary.
Since you seem to rely on that particular observation, I think it would improve your article if you could make explicit your reason for believing it so.
Chip Javert says:
March 9, 2014 at 3:14 pm
Mike McMillan says:
March 9, 2014 at 1:44 pm
“1. By the laws of averages, half of all Januaries should be above the yearly average and half should be below.”
I think you mean “median,” not “average.”
+++++++++++++++++++++++++++++++++++++++++++++++++++++++
Mathematical point of order: …
Chip beat me to the point. Assuming that half the Januaries will be above average is only valid if the data are normally distributed. Are they? You must show that first in order to make the statement. In many northern places, such as Alberta, monthly temperatures in January follow a bi-modal distribution. Are the monthly anomalies normally distributed- off hand I do not know.
Anyone who deals in statistics regularly cringes at this so called “law of averages”. This from Wikipedia is a good comment on the “law”:
“The law of averages is a layman’s term used to express a belief that outcomes of a random event will “even out” within a small sample.
As invoked in everyday life, the “law” usually reflects bad statistics or wishful thinking rather than any mathematical principle. “
Chip Javert says:
March 9, 2014 at 3:14 pm
What I was talking about has nothing to do with “Mean” or “Mode” or “Median”. I was not comparing 100 different Januaries with each other. I was comparing Januaries with the average anomaly for the year. So if we have 100 different anomalies for 100 different years, I am assuming that for 50 of those years, the January anomaly will be above the yearly anomaly. And 50 Januaries will be below the yearly anomaly.
NZ Willy says:
March 9, 2014 at 3:22 pm
I apologize for having hijacked this thread about the decades.
No problem! I anticipated it at some point which is why I had my response virtually ready right away.
PS: My image would also be great on billboards. Hop to it, Heartland and CFACT! (Or, better yet–Big Oil; and don’t forget to grease my palm!) Here’s the idea again:
Image—A hockey stick with its shaft slanting upwards & to the right and its blade flat.
Caption—Who’s in Denial Now?
Poptech says:
March 9, 2014 at 3:30 pm
I do not believe any such analysis can predict what the trend will be this year.
According to Walter Dnes’ first article, there is a 90% success rate when RSS shows a warmer January. That is a lot better than the MET office! Of course the MET office does not set the bar very high. Or they give such a large range that it is almost impossible to miss.
“The global average temperature in 2014 is expected to be between 0.43 C and 0.71 C above the long-term (1961-1990) average of 14.0 C”
PPS–For a billboard, the hockey stick would be overlaid by a temperature graph and a chart-grid with anomaly numbers on it. And there’d be a footnote giving the source of the data.
….was going to mention ‘visitin’ fizz-assist’ has been identified as Doug Cotton on several other sites, but Poptech beat me to it.
Are there physical reasons to explain Walter Dnes January Leading Indicator? I can think of several. Perhaps you can add to this list.
1. By the laws of averages, half of all Januaries should be above the yearly average and half should be below
Not only is this a non-physical reason, it isn’t true for all distributions.
rogerknights says:
Here’s a sharp image for a coffee mug or button:
Image—A hockey stick with its shaft slanting upwards & to the right and its blade flat.
Caption—Who’s in Denial Now?
Sort of like this?
Kudos to Merrick (March 9, 2014 at 2:10 pm) for his most interesting post which shows that THERE WAS A YEAR ZERO !!!!! Hoo boy, what a riposte to the pedants. Thanks, Merrick! :-))
DAV says:
March 9, 2014 at 4:52 pm
Not only is this a non-physical reason, it isn’t true for all distributions.
I apologize to every one for not being clearer. What I was trying to get at is related to the saying: “An apple does not fall far from the tree.”
To paraphrase Walter Dnes’ post, if the future January is warmer than the one you are comparing it with, then the anomaly of that future year will also be warmer than the one you are starting with.
So I will start by taking 31 cold years on Hadcrut4: 1900 to 1930.
I found that 16 Januaries were higher than the yearly average and 13 were lower with 2 virtual ties.
Now I will take 30 warm years: 1984 to 2013.
I found that 14 Januaries were higher than the yearly average and 15 were lower with 1 virtual tie.
Now here is, in effect,what I was trying to say. If you take any January from 1900 to 1930 and compare it to any January from 1984 to 2013, the Januaries from 1984-2013 will all be higher than the Januaries from 1900-1930. According to my paraphrase of Walter, every year from 1984-2013 should then be warmer than any year from 1900-1930. And indeed that is the case. So besides saying what I did, I should also have added that the January anomalies are never far from the annual average. Sorry about the confusion!
Strange we had an argument about what signals a new year or century in an Ancient History graduate unit. For example 5th Century AD is actually the years falling in the 400s. Like 20th Century is the 1900s. According to our lecturer, the 21st century started on January 1st 2000. As AD work backwards and BC go forward. Does it really matter, if the year is specifically mentioned?
Wow—that looks too good to be true! (Thanks for the find.) Here’s its full URL: http://stevengoddard.files.wordpress.com/2013/03/screenhunter_256-mar-02-06-55.jpg
Here are the changes I recommend if the image and caption I suggested are used as our side’s badge & billboard:
1. The chart’s lines should be an average of the five data sets, to avoid accusations of cherry-picking.
2. The spiky ups-and-down lines should be shown in a faint color in the background.
3. There should be a more prominent running mean line.
4. The hockey stick’s blade and shaft should be wider (even though unrealistic compared to a real hockey stick), in order to cover more of the swings of the running mean.
5. Most important, the blade should be flat (horizintal). We mustn’t over-reach—we mustn’t even SEEM to over-reach. We mustn’t give the other side a comeback.
In subsequent years, if Ma Nature cooperates with global cooling, the blade can be rotated downwards.
I suggest that a large-scale (1000+) but short-run (two weeks?) billboard campaign be run every year in mid-February, after the GASTA numbers for the previous year are published. At that point the sub-title, “(The Warm Is Turning)” can be added.
All of this nit picking about what defines a decade and whether or not miniscule trends are statistically significant provide a totally pointless distraction.
The significant question is: Did, or did not, models predict the future accurately?
This defines the level of understanding climate science has about the climate. We need no other measure.
If people would stop arguing about a 2C increase in global temps, why don’t they start worrying more about a drop of 2C. Seems the climate commission in Australia are relaying that Australia had a 150 records of highest temps last year. As we haven’t kept temperatures since 1788 hardly a surprise. The original Aborigines just got on with life and changed locations so they could provide food and water, etc.
I effectively ignored those articles. This analogy of yours clearly explains why I believe this analysis to be meaningless for prediction,
“Walter’s method is analogous to being allowed to predict the outcome of a game after watching the first 5 minutes.”
I attribute it more to meteorological voodoo than a valid prediction method. As for the reason you see differences in the temperature record trend dates, is my belief that RSS is the least manipulated and biased record as of right now. That is until the RSS team decides that they have to get rid of the current cooling trend.
Yes, global cooling will continue for the next 3 years. Here is something I have spent the last two days working on. It is a connection between solar cycles and the Multivariate ENSO Index. For the solar cycles I used Dr Svalgaard,s chart. Below is the relevant part of a comment I made about an hour ago.
Late Friday evening, as I finished the reading for the day at WUWT, I had the thought to straighten up a few folders where I save stuff. As I was in the process of doing that, once again I found myself comparing several charts to refresh my thoughts. I took the chart of the Multivariate ENSO Index and set it on the desktop. Then I put a solar cycle chart from pics into the preview so that I could then compare the two. I could not find the copy of Dr Svalgaard,s great high resolution chart at the time. The other solar charts which I had were of a coarser image. I went online and saved a recent solar chart from Dr Hathaway, which had a better resolution and current data. As I perused the combination of the two charts and puzzled over where to start to find a first puzzle piece connection, the first connection came into view. My thought had been to use the grand max of 1959 as the first piece. That should have been the easiest one to fit into some other piece on the MEI. And then I saw a fit. The grand max of 1959 fit with the El Nino of 1990, which began right at the end of 1989. The connection was a spacing of 30 years +/-1. The reason why no ones connect the Sun with the warming is that the warming from the Sun enters into the oceans and then comes out of the oceans 30 years later. Then I started examining the MEI for further connections, and there they were. I started with El Ninos and solar maxs. Every one was there, solar max…El Nino starts. I quickly glanced at a few of the minimums and sure enough, solar minimum…La Nina starts. I started writing down the sequences and improving my approach to the exercise. Then I noticed that there were a few events that did not readily connect with the La Nina. All of the major El Ninos were looking good though. I knew that I had found something. Inspiration grew! Then I thought that I should look once more for Dr Svalgaard,s higher res chart. I had a little trepidation with that thought as his chart had refuted a previous ‘connect the dots’ idea that I had. Plus I had already left my cryptic message up above saying that ‘I found something’. Yet, I knew full well that I had to use Dr Svalgaard,s work, or I would be deceiving myself. I found his chart and went to work, and BINGO. It went way beyond my expectations. Every move and tweak on the MEI had the right 30 year phase offset pattern, and I do mean every little move. Connections that I could not make with Dr Hathaway,s chart were completely verified with Dr Svalgaard,s work. Next step, here is the data connections. I use the prefixes ‘pre’ and ‘post’ to denote a shift which occurs before or after the top of a max or the bottom of a min.
Also note that, Note that the use of Nino and Nina only implies the changes in the MEI and not that the conditions for Nino or Nina were actually fulfilled.
SSN pre Min-1919/20 Nina-1949/50
SSN Min -1924/25 Nina-1954/55
SSN Max -1927/29 Nino-1957/58
SSN pre Min-1929/30 Nina-1959/60
spike-up-1933 Nino-1964
SSN min -1934/35 Nina-1964/65
SSN pre Max-1935/36 Nino-1965/66
SSN postMin-1936/37 Nina-1967/68
SSN Max -1938/39 Nino-1968/69
SSN pre Min-1940/41 Nina-1970/71
spike-up-1942 Nino-1972
SSN Min -1943/44 Nina-1973/74
SSN Max -1947/48 Nino-1977/78
1948-spike-down Nina-1978
SSN postMax-1948/49 Nino-1978/79
1950/51-spike down Nina-1981
spike up-1951 Nino-1981
1952-spike down Nina1982
spike up-1952 Nino-1982
1952.1/2-spike down Nina-1982.1/2
SSN post spike 1951/52 Nino-1982/83
1954-spike down Nina-1984
spike up-1954 Nino-1984
SSN Min-1954/55 Nina-1984/85
SSN pre Max-1957 Nino-1986/87
1958/59 spike down Nina-1988/89
SSN Grand Max-1959/60 Nino+ -1990/95
SSN postMin-1966/67 Nina-1996/97
SSN Max-1967/68 Nino-1997/98 El Grande
1968 spike down Nina-1998/99
spike up-1970 Nino-2000
1970-spike down Nina-200/01
SSN Max end-1971 Nino-2001
SSN pre Min-1972 Nina-2002
SSN post Max-1972/73 with continued up spikes Nino-2002/03/04/05
1974 spike down Nina-2004
SSN Min-1976 Nina-2006
SSN pre Max-1977 Nino-2007
SSN post Min-1977 Nina-2007
SSN Max 1978-itty bitty Nino-2008-itty bitty
1978 spike down Nina-2008
SSN Max-1979 Nino-2009/10
SSN pre Min-1981 Nina-2010/11
SSN Max-1982 Nino-2012
SSN pre Min-1983 early Nina-2013
spike up-1983 Nino-2013
SSN pre Min-1983 Nina-2013 late
spike up-1983 Nino-2013 late
SSN Min-1984 Nina-2014
and that is all she wrote for now, as the saying goes. That is every twist and turn of the MEI as correlated with Dr Svalgaard,s great work in his high res solar cycle chart.
Further, as I consider this to be accurate that means that I should now be able to make a prediction for future El Nino and La Nina. Here it is. It looks like a definite la Nina for now. That is an easy prediction, See I am already spot on with that prediction. The first swing back towards an El Nino will be early next year, but that should be an El Nado and short. After that it should be a strong La Nina all the way till late 2016 and then another short small El Nado. Late 2016 should be the beginning of a true El Nino that will go through 2018, and then back to La Nina. The winter of 2016/17 is very probable for a very heavy rain for the Pacific Northwest. I will leave my prediction there for now. I am tired, and my eyes are bugging out from trying to follow the year by year chart by Dr Svalgaard, which has no larger indicators to show where one might be such as 1970, 1980, 1990, etc etc.
This should allow for anyone to predict future MEI conditions, and also hindcast MEI to ssn and vice versa.
“Filby became pensive. ‘Clearly,’ the Time Traveller proceeded,’ any real body must have extension in four directions: it must have Length, Breath, Thickness, and – Duration. But through a natural infirmity of the flesh, which I will explain to you in a moment, we incline to overlook this fact”
H. G. Wells – The Time Machine.
The ‘Duration of Time, a Cycle or a Period’ will always be just so. 😉
Kate Forney says:
March 9, 2014 at 1:14 pm
yeah, it always a blast when people confuse mean for median…and its not like the information is hard to find…..
Ode to The Pause
(inspired by the children’s poem “There was an old woman who swallowed a fly”)
Some climate alarmists predicted no pause,
We all know the cause that demanded no pause,
The end times they saw.
Some climate alarmists have blamed some volcanoes,
That’s quite a trick with no change in albedos!
They blamed the volcanoes to post-hoc the pause
But we all know the cause that demanded no pause,
The end times they saw.
Some climate alarmists now blame the sun,
The same sun they said didn’t matter- what fun!
They blamed the dim sun for lack of volcanoes,
They blamed the volcanoes to post-hoc the pause,
But we all know the cause that demanded no pause,
The end times they saw.
Some climate alarmists are blaming the vortex,
That cools down our winters enough to wear Gore-Tex!
They blamed the cold vortex to pass on the sun,
They blamed the dim sun for lack of volcanoes,
They blamed the volcanoes to post-hoc the pause,
But we all know the cause that demanded no pause,
The end times they saw.
Some climate alarmists are blaming La Nina,
That mischievous foe of death-trains prima donnas,
They blamed the La Nina, with vortices sparse,
They blamed the cold vortex to pass on the sun,
They blamed the dim sun for lack of volcanoes,
They blamed the volcanoes to post-hoc the pause,
But we all know the cause that demanded no pause,
The end times they saw.
Some climate alarmists now blame the past,
And cool the old data, how tardily dast!
They twiddle the past to ignore the La Nina,
Ignorable ‘til it becomes an El Nino!
They blamed the La Nina, with vortices sparse,
They blamed the cold vortex to pass on the sun,
They blamed the dim sun for lack of volcanoes,
They blamed the volcanoes to post-hoc the pause,
But we all know the cause that demanded no pause,
The end times they saw.
Some climate alarmists are infilling where,
The ‘best-measured’ data is not really there!
They infill the Arctic and twiddle the past,
They twiddle the past to ignore the La Nina,
Ignorable ‘til it becomes an El Nino!
They blamed the La Nina, with vortices sparse,
They blamed the cold vortex to pass on the sun,
They blamed the dim sun for lack of volcanoes,
They blamed the volcanoes to post-hoc the pause,
But we all know the cause that demanded no pause,
The end times they saw.
Some climate alarmists keep averaging farther,
To smear out the pause that’s become such a bother.
The widening window avoids filling-in,
They infill the Arctic and twiddle the past,
They twiddle the past to ignore the La Nina,
Ignorable ‘til it becomes an El Nino!
They blamed the La Nina, with vortices sparse,
They blamed the cold vortex to pass on the sun,
They blamed the dim sun for lack of volcanoes,
They blamed the volcanoes to post-hoc the pause,
But we all know the cause that demanded no pause,
The end times they saw.
Some regular folks plot the data and see,
The cycles and monsters of uncertainty.
Destroyed they must be!
[! Mod]