Note to Readers: This is an important post, as Willis demonstrates that NASA GISS has taken a cooling trend and converted it into a warming trend for the one GHCN station in Nepal which covers the Himalayas. I offer NASA GISS, either via Jim Hansen or Gavin Schmidt, rebuttal opportunity to this issue on WUWT anytime. -Anthony
Guest Post by Willis Eschenbach
I read the excellent and interesting guest post by Marc Hendrickx about the IPCC and the Himalayas. My first big surprise was the size of the claimed warming. He cites IPCC Table 10.2 which says:
Nepal: 0.09°C per year in Himalayas and 0.04°C in Terai region, more in winter
Well, my bad number detector started ringing like crazy. A warming of nine degrees C (16°F) per century in the mountains, four degrees C per century in the lowlands? … I don’t think so. Those numbers are far too big. I know of no place on earth that is warming in general at 9°C per century.
Marc also quotes the IPCC source paper as saying:
The Kathmandu record, the longest in Nepal (1921–94), shows features similar to temperature trends in the Northern Hemisphere, suggesting links between regional trends and global scale phenomena.
Being cursed with a nagging, infernal curiosity, I thought I’d take a look at the Kathmandu temperature record. Foolish me …
I started by looking at where Nepal is located. It starts at the northern edge of the Indian plains, at the foothills of the Himalayas, and goes up to the crest:
Figure 1. Nepal (yellow outline). Yellow pins show all GHCN (Global Historical Climate Network) surface temperature stations.
So, that was my second surprise – a whole dang country, and only one single solitary GHCN temperature station. Hmmmm … as Marc shows, the paper cited by the IPCC gives the records of a dozen stations in Nepal. So why does GHCN only use Kathmandu in Nepal? But I digress.
Resolving not to be distracted by that, I went to the GISS dataset. I selected “Raw GHCN data + USHCN corrections” in the dropdown menu. (Kathmandu is outside the US, so in this case there are no USHCN corrections.) Typed in “Kathmandu”, and started the search. Figure 2 shows the result:
Figure 2. Kathmandu Air(port) Metadata.
This shows there are three records for Kathmandu Air (Airport), which looks promising. Also, it looks like there is an overlap between the records, which seems good. (There is no sign, however, of a record that is “the longest in Nepal (1921–94)”. The earliest date is 1951, and the latest is 2010. But again I digress.)
Clicking on the top Kathmandu Air link (on the GISS website, not on the graphic above) brings up the following GISS-generated graph:
Figure 3. Kathmandu Air. Three records are shown, as dotted, dashed, and blue.
Here’s an oddity. We have three records, each for different periods. And there is not a single year of overlap in the bunch. Not one.
Now, people think that I mine or search for these odd stations. Not so, I am simply curious about what I read, and this is not an atypical temperature record. Most are somewhat strange. Gaps and breaks in a given record often render large parts of the record unusable. GISS uses a cutoff of 20 years of consecutive data. As a result, the final GISS record for Kathmandu, rather than going from 1951-2009, goes from 1961 to 1980. Fair enough, these are all debatable choices, including the minimum record length cutoff size. In any case, the real problem with Kathmandu is not the record length. It is the lack of overlap which prevents the creation of a continuous record. This means that the apparent overall trend may not be real. It may simply be an artefact of e.g. different thermometers, or different locations. In this case, GISS has side-stepped the question by selecting only one record (shown in blue) for the final record.
How can we get to the graph of this final GISS record including all of their homogeneity adjustments? Well, we could go back to the same GISS website where we started and select a different dataset. However, here’s a trick to go directly from the raw data you are looking at to the final GISS homogenized dataset. Near the end of the URL of the raw GISS dataset under discussion you find the following:
… &data_set=0& …
GISS has three datasets. The raw data is dataset 0. The data “after combining records at the same location” is dataset 1. The final data “after cleaning/homogeneity adjustment” is dataset 2.
So to get the final adjusted result, all you have to do is to change the “0” in the URL to a “2”, viz:
… &data_set=2& …
Figure 3 shows the outcome of making that change:
Figure 3. Final GISS record for Kathmandu. The scale has been changed in both the X and Y axes. Note that they have discarded all segments of the record which are shorter than twenty years in length.
And that, dear friends, was my third big surprise. Take a close look at those two records, the adjusted and unadjusted …
As you no doubt observe, one is trending somewhat downwards, while the second is trending distinctly upwards. Hmmm … so, of course, I downloaded the GISS data (from the bottom of the same web page). Here is what they have done:
Figure 4. GISS Kathmandu Airport Annual Temperatures, Adjusted and Unadjusted, 1961–80. Yellow line shows the amount of the GISS homogeneity adjustment in each year. Photo is of Kathmandu looking towards the mountains.
GISS has made a straight-line adjustment of 1.1°C in twenty years, or 5.5°C per century. They have changed a cooling trend to a strong warming trend … I’m sorry, but I see absolutely no scientific basis for that massive adjustment. I don’t care if it was done by a human using their best judgement, done by a computer algorithm utilizing comparison temperatures in India and China, or done by monkeys with typewriters. I don’t buy that adjustment, it is without scientific foundation or credible physical explanation.
At best that is shoddy quality control of an off-the-rails computer algorithm. At worst, the aforesaid monkeys were having a really bad hair day. Either way I say adjusting the Kathmandu temperature record in that manner has no scientific underpinnings at all. We have one stinking record for the whole country of Nepal, which shows cooling. GISS homogenizes the data and claims it wasn’t really cooling at all, it really was warming, and warming at four degrees per century at that … hmmm, four degrees per century, where have I heard that before …
What conceivable scientific argument supports that, supports adding that linear 5.5°C/century trend to the data? What physical phenomena is it supposed to be correcting for? What error does it claim to be fixing?
Finally, does this “make a difference”? In the global average temperature, no – it is only one GHCN/GISS datapoint among many. But for the average temperature of Nepal, absolutely – it is the only GHCN/GISS datapoint. So it is quite important to the folks in Nepal … and infinitely misleading to them.
And when it is cited as one of the fastest warming places on the planet, it makes a difference there as well. And when the IPCC puts it in their Assessment Report, it makes a difference there.
Once again we see huge adjustments made to individual temperature records without reason or justification. This means simply that until GISS are able to demonstrate a sound scientific foundation for their capricious and arbitrary adjustments, we cannot trust the final GISS dataset. Their algorithm obviously has significant problems that lead to the type of wildly unreasonable results seen above and in other temperature datasets, and they are not catching them. Pending a complete examination, we cannot know what other errors the GISS dataset might contain.
[UPDATE] John Goetz pointed out that the likely source of the spurious trend is temperatures in Tingri (see Fig. 1, way back in the high mountains at the upper right at almost 6,000 metres elevation in the tundra) and GISS step 2. GISS says:
… in step 2, the urban and peri-urban (i.e., other than rural) stations are adjusted so that their long-term trend matches that of the mean of neighboring rural stations.
It seems John is right, Tingri is the likely problem. Or to be more accurate, their method is the problem. GISS uses a different method than GHCN to average stations for step 2.
The method of “first differences” is used by GHCN. GISS instead uses the “reference station” method described in the same citation. In my opinion, the reference station method is inferior to the first difference method.
The reference station here is likely Dumka, it is the longest of the nearby stations. Unlike Tingri, Dumka is at an elevation of 250 metres in the plains of West Bengal … hmmm. This should be interesting.
In the reference station method, Tingri gets adjusted up or down until the average temperatures match during the time of the overlap. Then Tingri and Dumka are averaged together. However, let’s take it a step at a time. First, I like to look at the actual underlying data, shown in Fig. 5.
Figure 5. Temperatures in Dumka (India) and Tingri (China). Left photo is Dumka on the lowland plains of West Bengal. Right photo is Tingri in the Himalayan mountains.
So the brilliant plan is, we’re going to use the average of the temperature anomalies in Dumka and Tingri to adjust the temperature in Katmandu, at 1,300 metres in the foothills?
Makes sense, I suppose. The average of mountains and plains is foothills, isn’t it? … but I digress.
The problem arises from the big jump in the Tingri data around 1970. Using the reference station method, that big jump gets wrapped into the average used to adjust the Kathmandu data. And over the period of Tingri/Kathmandu overlap (1963-1980), because of the big jump the “trend” of the Tingri data is a jaw-dropping 15°C per century. Once that is in the mix, all bets are off.
Obviously, there is some kind of problem with the Tingri data. The first difference method takes care of that kind of problem, by ignoring the gaps and dealing only with the actual data. You could do the same with the reference station method, but only if you treat the sections of the Tingri data as separate stations. However, it appears that the GISS implementation of the algorithm has not done that …
Nor is this helped by the distance-weighting algorithm. That weights the temperatures based on how far away the station is. The problem is that Tingri is much nearer to Kathmandu (197 km) than Dumka (425 km). So any weighting algorithm will only make the situation worse.
Finally, does anyone else think that averaging high mountain tundra temperature anomalies with lowland plains anomalies, in order to adjust foothills anomalies, is a method that might work but that it definitely would take careful watching and strict quality control?
[UPDATE 2] Lars Kamel pointed below to the CRU data. If we take all of the available CRU (originally GHCN) data, we get the following trend for Kathmandu.
Figure 6. CRU monthly and annual temperature data for Kathmandu. Red circles show those years with 12 months of data.
You can see the lack of a trend in the 1950-2000 data. Went down slightly 1950-1975, went up slightly 1975-2000. Gosh.
[UPDATE 3] Steve McIntyre reminded me below of his fascinating 2008 analysis of the numbers and locations of GISS adjustments that go up, down, and sideways. His post is here, and is well worth reading.
[UPDATE 4] Zeke Hausfather has an interesting post on Kathmandu here, with lots of good information.
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+9C rise per century? But that’s more than twice the +4C trend predicted in the Arctic. I thought that CO2 induced AGW is supposed to have the greatest magnitude at the poles. Does this mean that there is some doubt over the accuracy of the climate models? Well strap me to a tree and call me Brenda…
After all, James Hansen almost admits that he likes cooking the books on his official NASA web page:
http://www.giss.nasa.gov/staff/jhansen.html
Quote:
“The hardest part is trying to influence the nature of the measurements obtained, so that the key information can be obtained.“
First, my thanks to all for their kind comments on my work, much appreciated.
Next, Pamela Gray says:
August 11, 2010 at 8:47 am (Edit)
Thanks, Pamela. That yellow push-pin is Darjeeling. It is made up of five records, viz:
As you might guess, GISS has chosen the most warming of the Darjeeling records for their final data:
In either case, the lacunae in the Darjeeling data from 1961-1980 means it is useless for purposes of comparison with Kathmandu.
Again we see the use of derivatives to obfuscate actual temperatures.
Is this some more Hansen/GISS chichanery, or just some newfangled “science” fraud?
I wonder how many more Nepals we will find on Mother Earth!
So, they inferred two different warming rates (0.09°C per year in Himalayas and 0.04°C in Terai region) from one temperature record? That, in itself, is a pretty neat trick, from where I sit…
Michael Schaefer says:
August 11, 2010 at 6:33 am
Could we all agree to this new terminology: Adjustments = falsifications?
Show the raw data and the EXACT circumstances at every station plotting them, and let the users of the data sort out all by themselves, what that means, I say.
Of what purpose are ANY adjustments, when it takes MORE time and labour, to re-calculate and find mis-adjustments, than doing all adjustments on your own?
There’s only ONE possible purpose for GISS “adjusting” the data imaginable: Falsifying the records, in order to push the GW-agenda!
Well, you know? Once upon a time –and this ain’t no fairy-tale– station data was purely raw information. What you saw was the real McCoy.
Then some people took that data and tried to discover trends for purely informational purposes, such as to attempt to discover past and possible future impacts.
Then along came people who referred to themselves as ‘climate scientists’ if only that they studied past weather trends, along with current atmospheric effects, among other things.
They refer to themselves as ‘climate scientists’ because the term meteorologist didn’t sound hifalutin enough. Nothing like hiking one’s self up on a pedestal, you understand …
Now, with their new identification, they figured that in order to qualify their position in life and increase their newly discovered self-importance, they absolutely had to make crassly dire predictions, and over-inflated prognostications.
Anything, you understand, to get attention. And of course, that new distinction required higher pay to pretty much the very same thing that lowly weatherman does otherwise.
So now, we arrive at the raw data, and it simply cannot be allowed to tell the truth, because the truth is, well, inconvenient. It doesn’t support the dire prognostications of doom and gloom.
So then, the data are given the third degree: They are tortured into admitting things which just ain’t true. But because the data were tortured by professionals with a highfalutin appellation, then the confessions are seen as both acceptable and undeniable.
Now you understand that if any of the rest of us –whom don’t any highfalutin appellation– were to pull that very same stunt, why we’d be hauled into court, and reduced to quivering jelly, and tossed into a dungeon never to be heard from again.
And there you have it.
EAT INSECTS INSTEAD OF MEAT!!
http://www.popsci.com/science/article/2010-08/humanity-needs-start-farming-bugs-food-says-united-nations-policy-paper
It is rather difficult (or should I go to the extreme and say “impossible”) to interpolate from one data point. Every projection would be an extrapolation, and you know how those go–just dream up a target and go for it.
Using Willis’s method, checked neighbouring station of Darbhanga, picture is very similar.
There is no visible trend between 1880-1960 and cooling of about 1.5-2.0 degrees between 1960-1990
Which became warming of about 2.0 degrees after adjustements
See the
Chronological Development of TIA with some emphasis:
See TIAirport.com.np Contact us
Oh come on now, NASA GI** would not do that, would they?
Excellent sleuth work as always, Willis.
Chris
Norfolk, VA, USA
This entire area is under the influence of Monsoons. Monsoons are very much tied to oceanic oscillations. Certain oceanic conditions create these Monsoons and can also keep them at bay. When all Monsoon producing oscillations occur at the same time, you have floods and death, but water loving crops thrive. When all Monsoon limiting oscillations occur at the same time, you have severe drought and crop destruction.
Darjeeling has an interesting temperature history. Both extreme highs and extreme lows occurred in the same fall/winter period. When cold weather pattern variations come about, it is not uncommon to have hot dry summers and bitter cold dry winters.
http://www.mausam.gov.in/WEBIMD/ClimatologicalAction.do?function=getStationDetails&actionParam=1¶m=2&station=Darjeeling
I hope nobody is tempted to assume that the remaining temperature increase claims in the IPCC Table referred to above are accurate simply because Big Oil hasn’t funded any of us sufficiently to study all the adjusted data. LOL
Thanks Willis
C
An article about the heavy rains affecting India, Pakistan, and China, along with the drought in Russia. Not one single mention of climate change. And I love the last section in the last paragraph:
“D.S. Pai, director, forecasting, at IMD’s Pune unit, said all these weather conditions could be little more than a coincidence. ‘Usually, when it rains in China, showers weaken over north-west India. But historical data shows that it has simultaneously rained substantially in both regions before. It’s rare but not unprecedented.'”
http://www.livemint.com/2010/08/11000400/Monsoon-pattern-catches-meteor.html
That Chinese view on CAGW – http://libertygibbert.wordpress.com/2010/08/11/the-dragons-dissent/#comment-6629 – if even half correct is quite sensational and explans much. Thanks Pointman
As Watchman points out, the adjustment must be due to nearby rural stations. The closest, Tingri, looks to me like the culprit based on its graph:
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=205556640000&data_set=2&num_neighbors=1
There are no DATA other than the raw DATA. Anything else is fabrication, pure and simple, or impure and complex. 🙂
The only way to have accurate DATA is to collect the DATA from properly designed, sited, installed and maintained measurement stations with high quality, stable and properly calibrated sensors.
This reality should be “intuitively obvious to the casual observer”. However, it appears to elude the climate science community.
Rumplestiltskin was a character in a fairy tale. However, even he did not claim to be able to spin garbage into DATA.
John, I’ld bet that station was in a rural location before being moved to the airport. The break in the data indicates such a move, but from where to where is not clear.
Tim Williams says:
August 11, 2010 at 9:20 am
“All very interesting, but what could be melting the glaciers on Everest considering this cooling newly discovered cooling trend?”
Black carbon deposits, deforestation (increasing wind-based erosion), lack of precipitation, etc. There are many reasons glaciers can shrink.
Willis E.
The 1951-1960 data in your fig. 3 appears to come from the World Weather Records book 04 Asia. They have 9 data points where you have 7, but they follow almost identically. They were measured at the Indian Embassy Building in Kathmandu at 27-42N 84-21E.
Tim Williams says:
August 11, 2010 at 9:20 am
All very interesting, but what could be melting the glaciers on Everest considering this cooling newly discovered cooling trend?
Have you even checked the temperatures at the elevations the glaciers are situated?
I cannot claim any climatological expertise, but ice rarely melts at -5 to -35 degrees Celsius. My guess would be any decline is caused by ablation and a lack of precipitation.
In defence of the people at GISS – if your family’s next meal depended on your pay cheque from GISS, would you be complaining about the algorithm?