Guest Post by Willis Eschenbach
Recently, Nature Magazine published a paywalled paper called “Human contribution to more-intense precipitation extremes” by Seung-Ki Min, Xuebin Zhang, Francis W. Zwiers & Gabriele C. Hegerl (hereinafter MZZH11) was published in Nature Magazine. The Supplementary Information is available here. The study makes a very strong claim to have shown that CO2 and other greenhouse gases are responsible for increasing extreme rainfall events, viz:
Here we show that human-induced increases in greenhouse gases have contributed to the observed intensification of heavy precipitation events found over approximately two-thirds of data-covered parts of Northern Hemisphere land areas.
Figure 1. Extreme 1-day rainfall. New Orleans, Katrina. Photo Source
There are two rainfall indices which are used in their analysis, called the RX1day and RX5day indices. The RX1day and RX5day indices give the maximum one-day precipitation and five-day precipitation for a given station for a given month. These individual station datasets (available here, free registration required) have been combined into a gridded dataset, called HADEX (Hadley Climate Extremes Dataset) . It is this gridded dataset that was used in the MZZH11 study.
So what’s wrong with the study? Just about everything. Let me peel the layers off it for you, one by one.
Other people have commented on a variety of problems with the study, including Roger Pielke Jr., Andy Revkin, Judith Curry . But to begin with, I didn’t read them, I did what I always do. I went for the facts. I thrive on facts. I went to get the original data. For me, this is not the HADEX data, as that data has already been gridded. I went to the actual underlying data used to create the HADEX dataset, as cited above. Since they don’t provide a single datablock file with all of the areas (grrrr … pet peeve), I started by looking at the USA data.
And as is my habit, the first thing I do is just to look at the individual records. There are 2,661 stations in the USA database, of which some 731 contain some RX1day maximum one day rainfall data. However, as is usual with weather records of all kinds, many of these have missing data. In addition, only 9% of the stations contain a significant trend at the 95% confidence level. Since with a 95% confidence interval (CI) we would expect 5% of the stations to exceed that in any random dataset, we’re only slightly above what would be expected in a random dataset. In addition, the number of stations available varies over time..
Now, let me repeat part of that, because it is important.
91% of the rainfall stations in the US do not show a significant trend in precipitation extremes, either up or down.
So overwhelmingly in the US there has been
No significant change in the extreme rainfall.
And as if that wasn’t enough …
Of the remaining 9% that have significant trends, 5% of the trends are probably from pure random variation.
So this means that
Only about 5% of the stations in the US show any significant change in rainfall extremes.
So when you see claims about changes in US precipitation extremes, bear in mind that they are talking about a situation where only ~ 5% of the US rainfall stations show a significant trend in extreme rainfall. The rest of the nation is not doing anything.
Now, having seen that, let’s compare that to the results shown in the study:
Figure 2. The main figure of the MZZH11 study, along with the original caption. This claims to show that the odds of extreme events have increased in the US.
Hmmmm …. so how did they get that result, when the trends of the individual station extreme precipitation show that some 95% of the stations aren’t doing anything out of the ordinary? Let me go over the stages step by step as they are laid out in the study. Then I’ll return to discuss the implications of each step.
1. The HADEX folks start with the individual records. Then, using a complex formula based on the distance and the angle from the center of the enclosing gridcell, they take a weighted station average of each month’s extreme 1-day rain values from all stations inside the gridcell. This converts the raw station data into the HADEX gridded station data.
2. Then in this study they convert each HADEX gridcell time series to a “Probability-Based Index” (PI) as follows:
Observed and simulated annual extremes are converted to PI by fitting a separate generalized extreme value (GEV) distribution to each 49-year time series of annual extremes and replacing values with their corresponding percentiles on the fitted distribution. Model PI values are interpolated onto the HadEX grid to facilitate comparison with observations (see Methods Summary and Supplementary Information for details).
In other words, they separately fit a generalized three-parameter probability function each to gridcell time series, to get a probability distribution. The fitting is done iteratively, by repeatedly adjusting each parameter to find the best fit. Then they replace that extreme rainfall value (in millimetres per day) with the corresponding probability distribution value, which is between zero and 1.
They explain this curious transformation as follows:
Owing to the high spatial variability of precipitation and the sparseness of the observing network in many regions, estimates of area means of extreme precipitation may be uncertain; for example, for regions where the distribution of individual stations does not adequately sample the spatial variability of extreme values across the region. In order to reduce the effects of this source of uncertainty on area means, and to improve representativeness and inter-comparability, we standardized values at each grid-point before estimating large area averages by mapping extreme precipitation amounts onto a zero-to-one scale. The resulting ‘probability-based index’ (PI) equalizes the weighting given to grid-points in different locations and climatic regions in large area averages and facilitates comparison between observations and model simulations.
Hmmm … moving right along …
3. Next, they average the individual gridcells into “Northern Hemisphere”, “Northern Tropics”, etc.
4. Then the results from the models are obtained. Of course, models don’t have point observations, they already have gridcell averages. However, the model gridcells are not the same as the HADEX gridcells. So the model values have to be area-averaged onto the HADEX gridcells, and then the models averaged together.
5. Finally, they use a technique optimistically called “optimal fingerprinting”. As near as I can tell this method is unique to climate science. Here’s their description:
In this method, observed patterns are regressed onto multi-model simulated responses to external forcing (fingerprint patterns). The resulting best estimates and uncertainty ranges of the regression coefficients (or scaling factors) are analysed to determine whether the fingerprints are present in the observations. For detection, the estimated scaling factors should be positive and uncertainty ranges should exclude zero. If the uncertainty ranges also include unity, the model patterns are considered to be consistent with observations.
In other words, the “optimal fingerprint” method looks at the two distributions H0 and H1 (observational data and model results) and sees how far the distributions overlap. Here’s a graphical view of the process, from Bell, one of the developers of the technique.
Figure 2a. A graphical view of the “optimal fingerprint” technique.
As you can see, if the distributions are anything other than Gaussian (bell shaped), the method gives incorrect results. Or as Bell says (op. cit.) the optimal footprint model involves several crucial assumptions, viz:
• It assumes the probability distribution of the model dataset and the actual dataset are Gaussian
• It assumes the probability distribution of the model dataset and the actual have approximately the same width
While it is possible that the extreme rainfall datasets fit these criteria, until we are shown that they do fit them we don’t know if the analysis is valid. However, it seems extremely doubtful that the hemispheric averages of the probability based indexes will be normal. The MZZH11 folks haven’t thought through all of the consequences of their actions. They have fitted an extreme value distribution to standardize the gridcell time series.
This wouldn’t matter a bit, if they hadn’t then tried to use optimal fingerprinting. The problem is that the average of a PI of a number of extreme value distributions will be an extreme value distribution, not a Gaussian distribution. As you can see in Figure 2a above, for the “optimal fingerprint” method to work, the distributions have to be Gaussian. It’s not as though the method will work with other distributions but just give poorer results. Unless the data is Gaussian, the “optimal fingerprint” method is worse than useless … it is actively misleading.
It also seems doubtful that the two datasets have the same width. While I do not have access to their model dataset, you can see from Figure 1 that the distribution of the observations is wider, both regarding increases and decreases, than the distribution of the model results.
This seems extremely likely to disqualify the use of optimal fingerprinting in this particular case even by their own criteria. In either case, they need to show that the “optimal fingerprint” model is actually appropriate for this study. Or in the words of Bell, the normal distribution “should be verified for the particular choice of variables”. If they have done so there is no indication of that in the study.
I think that whole concept of using a selected group of GCMs for “optimal fingerprinting” is very shaky. While I have seen theoretical justifications for the procedure, I have not seen any indication that it has been tested against real data (not used on real data, but tested against a selected set of real data where the answer is known). The models are tuned to match the past. Because of that, if you remove any of the forcings, it’s almost a certainty that the model will not perform as well … duh, it’s a tuned model. And without knowing how or why the models are chosen, how can they say their results are solid?
OK, I said above that I would first describe the steps of their analysis. Those are the steps. Now let’s look at the implications of each step individually.
STEP ONE: We start with what underlies the very first step, which is the data. I didn’t have to look far to find that the data used to make the HADEX gridded dataset contains some really ugly errors. One station shows 48 years of August rains with a one-day maximum of 25 to 50 mm (one to two inches), and then has one August (1983) with one day when it is claimed to have rained 1016 mm (40 inches) … color me crazy, but I think that once again, as we have seen time after time, the very basic steps have been skipped. Quality doesn’t seem to be getting controlled. So … we have an unknown amount of uncertainty in the data simply due to bad individual data points. I haven’t done an analysis of how much, but a quick look revealed a dozen stations with that egregious an error in the 731 US datasets … no telling about the rest of the world.
The next data issue is “inhomogeneities” (sudden changes in volume or variability) in the data. In a Finnish study, 70% of the rainfall stations had inhomogeneities. While there are various mathematical methods used by the HADEX folks to “correct” for this, it introduces additional uncertainty into the data. I think it would be preferable to split the data at the point of the inhomogeneous change, and analyze each part as a separate station. Either way, we have an uncertainty of at least the difference in results of the two methods. In addition, the Norwegian study found that on average, the inhomogeneities tended to increase the apparent rainfall over time, introducing a spurious trend into the data.
In addition, extreme rainfall data is much harder to quality control than mean temperature data. For example, it doesn’t ever happen that the January temperature at a given station averages 40 degrees every January but one, when it averages 140 degrees. But extreme daily rainfall could easily change from 40 mm one January to an unusual rain of 140 mm. This makes for very difficult judgements as to whether a large daily reading is erroneous.
In addition, an extreme value is one single value, so if that value is incorrectly large it is not averaged out by valid data. It carries through, and is wrong for the day, the month, the year, and the decade.
Rainfall extreme data also suffers in the recording itself. If I have a weather station and I go away for the weekend, my maximum thermometer will record the maximum temperature of the two days I missed. But the rainfall gauge can only give me the average of the two days I missed … or I could record the two days as one with no rain on the other day. Either way … uncertainties.
Finally, up to somewhere around the seventies, the old rain gauges were not self emptying. This means that if the gauge were not manually emptied, it could not record an extreme rain. All of these problems with the collection of the extreme rainfall data means it is inherently less accurate than either mean or extreme temperature data.
So that’s the uncertainties in the data itself. Next we come to the first actual mathematical step, the averaging of the station data to make the HADEX gridcells. HADEX, curiously, uses the averaging method rejected by the MZZH11 folks. HADEX averages the actual rainfall extreme values, and did not create a probability-based index (PI) as in the MZZH11 study. I can make a cogent argument for either one, PI or raw data, for the average. But using a PI based average of a raw data average seems like an odd choice, which would result in unknown uncertainties. But I’m getting ahead of myself. Let me return to the gridding of the HADEX data.
Another problem increasing the uncertainty of the gridding is the extreme spatial and temporal variability of rainfall data. They are not well correlated, and as the underlying study for HADEX says (emphasis mine):
[56] The angular distance weighting (ADW) method of calculating grid point values from station data requires knowledge of the spatial correlation structure of the station data, i.e., a function that relates the magnitude of correlation to the distance between the stations. To obtain this we correlate time series for each station pairing within defined latitude bands and then average the correlations falling within each 100 km bin. To optimize computation only pairs of stations within 2000 km of each other are considered. We assume that at zero distance the correlation function is equal to one. This may not necessarily be the best assumption for the precipitation indices because of their noisy nature but it does provide a good compromise to give better gridded coverage.
Like most AGW claims, this seems reasonable on the surface. It means that stations closer to the gridbox center get weighted more than distant stations. It is based on the early observation by Hansen and Lebedeff in 1987 that year-to-year temperature changes were well correlated between nearby stations, and that correlation fell off with distance. In other words, if this year is hotter than last year in my town, it’s likely hotter than last year in a town 100 km. away. Here is their figure showing that relationship:
Figure 3. Correlation versus Inter-station Distance. Original caption says “Correlation coefficients between annual mean temperature changes for pairs of randomly selected stations having at least 50 common years in their records.”
Note that at close distances there is good correlation between annual temperature changes, and that at the latitude of the US (mostly the bottom graph in Figure 3) the correlation is greater than 50% out to around 1200 kilometres.
Being a generally suspicious type fellow, I wondered about their claim that changes in rainfall extremes could be calculated by assuming they follow the same distribution used for temperature changes. So I calculated the actual relationship between correlation and inter-station distance for the annual change in maximum one-day rainfall. Figure 4 shows that result. It is very different from temperature data, which has good correlation between nearby stations and drops off slowly with increasing distance. Extreme rainfall does not follow that pattern in the slightest.
Figure 4. Correlation of annual change in 1-day maximum rainfall versus the distance between the stations. Scatterplot shows all station pairs between all 340 mainland US stations which have at least 40 years of data per station. Red line is a 501 point Gaussian average of the data.
As you can see, there is only a slight relationship at small distances between extreme rainfall event correlation and distance between stations. There is an increase in correlation with decreasing distance as we saw with temperature, but it drops to zero very quickly. In addition, there are a significant number of negative correlations at all distances. In the temperature data shown in Figure 3, the decorrelation distance (the distance where the average correlation drops to 0.50) is on the order of 1200 km. The corresponding decorrelation distance for one-day extreme precipitation is only 40 km …
Thinking that the actual extreme values might correlate better than the annual change in the extreme values, I plotted that as well … it is almost indistinguishable from Figure 4. Either way, there is only a very short-range (less than 40 km) relation between distance and correlation for the RX1day data.
In summary, the method of weighting averages by angular distances used for gridding temperature records is supported by the Hansen/Lebedeff temperature data in Figure 3. On the other hand, the observations of extreme rainfall events in Figure 4 means that we cannot use same method for gridding of extreme rainfall data. It makes no sense, and reduces accuracy, to average data weighted by distance when the correlation doesn’t vary with anything but the shortest distances, and the standard deviation for the correlation is so large at all distances.
STEP 2: Next, they fit a generalized extreme value (GEV) probability distribution to each individual gridcell. I object very strongly to this procedure. The GEV distribution has three different parameters. Depending on how you set the three GEV dials, it will give you distributions ranging from a normal to an exponential to a Weibull distribution. Setting the dials differently for each gridcell introduces an astronomical amount of uncertainty into the results. If one gridcell is treated as a normal distribution, and the next gridcell is treated as an exponential distribution, how on earth are we supposed to compare them? I would throw out the paper based on this one problem alone.
If I decided to use their method, I would use a Zipf distribution rather than a GEV. The Zipf distribution is found in a wide range of this type of natural phenomena. One advantage of the Zipf distribution is that it only has one parameter, sigma. Well, two, but one is the size of the dataset N. Keeps you from overfitting. In addition, the idea of fitting a probability distribution to the angular-distance weighted average of raw extreme event data is … well … nuts. If you’re going to use a PI, you need to use it on the individual station records, not on some arbitrary average somewhere down the line.
STEP 3: Hemispheric and zonal averages. In addition to the easily calculable statistical error propagation in such averaging, we have the fact that in addition to statistical error each individual gridpoint has its own individual error. I don’t see any indication that they have dealt with this source of uncertainty.
STEP 4: Each model needs to have its results converted from the model grid to the HADEX grid. This, of course, gives a different amount of uncertainty to each of the HADEX gridboxes for each of the models. In addition, this uncertainty is different from the uncertainty of the corresponding observational gridbox …
There are some other model issues. The most important one is that they have not given any ex-ante criteria for selecting the models used. There are 24 models in the CMIP database that they could have used. Why did they pick those particular models? Why not divide the 24 models into 3 groups of 8 and see what difference it makes? How much uncertainty is introduced here? We don’t know … but it may be substantial.
STEP 5: Here we have the question of the uncertainties in the optimal fingerprinting. These uncertainties are said to have been established by Monte Carlo procedures … which makes me nervous. The generation of proper data for a Monte Carlo analysis is a very subtle and sophisticated art. As a result, the unsupported claim of a Monte Carlo analysis doesn’t mean much to me without a careful analysis of their “random” proxy data.
More importantly, the data does not appear to be suitable for “optimal fingerprinting” by their own criteria.
End result of the five steps?
While they have calculated the uncertainty of their final result and shown it in their graphs, they have not included most of the uncertainties I listed above. As a result, they have greatly underestimated the real uncertainty, and their results are highly questionable on that issue alone.
OVERALL CONCLUSIONS
1. They have neglected the uncertainties from:
• the bad individual records in the original data
• the homogenization of the original data
• the averaging into gridcells
• the incorrect assumption of increasing correlation with decreasing distance
• the use of a 3 parameter fitted different probability function for each gridcell
• the use of a PI average on top of a weighted raw data average
• the use of non-Gaussian data for an “optimal fingerprint” analysis
• the conversion of the model results to the HADEX grid
• the selection of the models
As a result, we do not know if their findings are significant or not … but given the number of sources of uncertainty and the fact that their results were marginal to begin with, I would say no way. In any case, until those questions are addressed, the paper should not have been published, and the results cannot be relied upon.
2. There are a number of major issues with the paper:
• Someone needs to do some serious quality control on the data.
• The use of the HADEX RX1day dataset should be suspended until the data is fixed.
• The HADEX RX1day dataset also should not be used until gridcell averages can be properly recalculated without distance-weighting.
• The use of a subset of models which are selected without any ex-ante criteria damages the credibility of the analysis
• If a probability-based index is going to be used, it should be used on the raw data rather than on averaged data. Using it on grid-cell averages of raw data introduces spurious uncertainties.
• If a probability-based index is going to be used, it needs to be applied uniformly across all gridcells rather than using different distributions a gridcell by gridcell basis.
• No analysis is given to justify the use of “optimal fingerprinting” with non-Gaussian data.
3. Out of the 731 US stations with rainfall data, including Alaska, Hawaii and Puerto Rico, 91% showed no significant change in the extreme rainfall events, either up or down.
4. Of the 340 mainland US stations with 40 years or more of records, 92% showed no significant change in extreme rainfall in either direction.
As a result, I maintain that their results are contrary to the station records, that they have used inappropriate methods, and that they have greatly underestimated the total uncertainties of their results. Thus the conclusions of their paper are not supported by their arguments and methods, and are contradicted by the lack of any visible trend in the overwhelming majority of the station datasets. To date, they have not established their case.
My best regards to all, please use your indoor voices in discussions …
w.
[UPDATE] I’ve put the widely-cited paper by Allen and Tett about “optimal fingerprinting” online here.
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Looks like the Ioannidis Demon (John P.) at work again. Common in th AGW crowd.
Gridding a temperature measurement over distance might be argued to have some validity. It would be a difficult argument to win, but doing the same thing with rainfall? Absurd. Precipitation extremes can have a span of only a couple of miles or so.
It seems to me to be time to prohibit anyone from publishing statistical analysis that is not supported by an “audit certificate” provided by a registered and named statistician.
Roy says:
February 21, 2011 at 12:58 am
I think that the general point that a change in climate will produce changes in the (frequency of particular types of) weather is logically sound!
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I would agree with the general thrust of that premise.
The issue is whather 0.5C, or o.9C, or 1.5C or 2C etc amounts to a change in climate. It is hard to see that a change of no more than 0.8C (that appears to be the max warming of the last century even if the temp record is reliable) amounts to a significant change in climate and it is therefore extremely unlikely that the present change is culpable at this stage.
Good post Willis.
It is becoming easier and easier to debunk the crapscience coming from these guys. If the study had used the exact same methodology and came to the exact opposite conclusion, what are the chances it sees publication? Zero.
Excellent analysis by Willis again. Unfortunately, the whole point of these flawed alarmist papers is not to produce sound science, but to allow the media to scream ‘science shows extreme rainfall is caused by man.’ They know full well that whilst the sceptics will pull it apart strand by strand, the message has already been broadcast, and to achieve their ends – legally binding carbon mitigation legislation – that is all that matters.
Like Viv Evans (3:39), I enjoyed this entertaining look under the hood. A lot of hoods need to be lifted more often — rust and gunk and sabotage found everywhere. I guess this means public, signed peer review comments at the very least. Thanks for this exceptional effort, as usual, Willis.
I agree with Manfred, 12:34 am:
It is annoying, that such poor science slipped again through Nature’s peer review process.
I associate with co-author Gabriele Hegerl questionable practices within the IPCC, disproven Hockey team “science”, climategate and her few rooms apart neighbour Geoffrey Boulton running the failed Muir/Russell “inquiry”.”
Both Nature and Science enterprises are run now as last ditch efforts to save their (and their corporate-government-academic sponsors) cushy jobs, incomes, benefits, pensions on taxpayers’ generosity. Since there is so much lucre involved, they will fight to the last breath — like the “public servant” unions in Wisconsin and other states in the U.S.
We must be there to take down their names and put them into a “shamed” pool of pseudo-scientists (or authoritarian unionists as compared to “democratic” unions) who should never be hired again. I am tired of payin’ for ’em.
I am not sure if Nature is as unscientific as Greenpeace – that would be very difficult – so it was like a breath of fresh air to hear this from one of Greenpeace’s founders:
http://www.stockwatch.com/News/Item.aspx?bid=Z-C:*CURRENT-1810801&symbol=*CURRENT&news_region=C
It’s even worse than you say. It is known that the models are very bad at simulating historic rainfall at regional/local scales. There have been issues over time with rain gages and changes in methods, and rain data in many parts of the world are just awful. But it is just unbelievable that they don’t bother to check their assumptions of correlation with distance and normality etc and especially what is the null about number of stations that would show a trend by chance. Simply appalling. Furthermore, their test doesn’t show what they claim: if it is getting warmer naturally vs by GHG, rain will go up either way (as it seems to have done) and the models will simulate it going up without that proving that it is due to GHG.
Willis, great read. The grid cell distribution they use how big are the cells? Here in Texas, it can rain in small or large areas, as anywhere else, but most of the time i have seen it rain on one side of a fence line and not the other, so IMO i do not see this being a very good way of saying that there are more exreme rain events for any particular areas much less N.H. or global. And one more question,why do they take measured data and put in a model instead of actually using OBSERVED and measured data and using it? Sorry if the last is confusing because it is confusing me also. Models=GIGO!
Here is a scatterplot of HadUKP England and Wales precipitation (a fully quality controlled dataset) versus HadCET temperatures back to 1766.
Technically, there should be a trend in precipitation of 2% to 3% per 1.0C increase in temperatures.
There is no trend in this data and no evidence that global warming is causing more precipitation in the UK.
http://img249.imageshack.us/img249/1669/engwalesprecipvshadcetk.png
Either the temperature data is wrong, the precipitation data is wrong or the Clausius Clapeyron relation is wrong (on a local level at least – and if that is the case, the studies are based on a false premise to start with).
There is also no trend in daily precipitation in England and Wales back to 1931 (over 29,000 individual datapoints), a period when temperatures have supposedly increased by 0.8C in the UK.
http://img101.imageshack.us/img101/4800/dailyrainfallenglandwal.png
On our farm, located on the western Canadian prairie, we have helped along with other neighbors, to record the observed rainfall for our area for the last 35 years. These records are kept for the Agriculture dept. of our province and cover the growing period of April 1 to Oct.30. Our son, with an interest in numbers, decided to plot these records, in an attempt to discern a pattern. He simply straight lined the average and plotted the monthly totals and yearly totals. Predictably the tracking line jumped above and below the average with huge month to month and year to year variation. Even a generally dry year would surprise you with a spike in monthly rainfall or likewise a wet year would produce a month with very little rain. There was less rain in the dryer 1980’s but not every year in the 1980’s. There has been more rain in the last decade but not every year of the last decade. We have been unable to discern any pattern. The only thing that we could conclude from our little exercise was the erratic and unpredictable nature of rainfall on the Canadian Prairie but then everyone around here knew that already.
Rainfall data is all suspect to begin with. Let me give you an example why. I live just outside London Ontario. There is a weather station at London airport.
Last summer, as an example, we had very little rain in August where I am, but the city of London got dumped on many times. I could see the rain clouds pass right over us and drop nothing, only to drop it all over London. My son’s place is a 20 minute drive from me, and he will get dumped on while we don’t and visa versa.
Snow is worse. We get lake effect snow, sometimes 2 to 3 feet in 48 hour period. But those are fingers of deep snow drop from Lake Huron, and completely dependant on the wind pattern. We get 3 ft of snow, London airport get’s nothing.
So what is the rainfall for our ‘grid’? Change the wind pattern and we get dumped and not London. So London’s station records too little rainfall, or too much rainfall (both due to highly localized dumps).
Unless you have rain stations every kilometer, and observe changes in drop zones due to wind patterns, there is no way you can deduce if there is any trend happening. And there is some indication, from all those wind turbines, that wind over the past 6 years have been slowing. That will change the drop zones of the rain even though the rain volume hasn’t changed.
They could have used a Binomial test to compare the observed value in each grid square with the expected value (ie assuming an equal chance of finding activity). The expected value (I assume) varied from year to year, reflecting their observation of increased activity. Since there were potentially hundreds of tests (thus exposing the possibility of numbers of false positives accuring in the data set) they might have used used a Bonferroni correction which could be repeated to test, for example, 5 times the average number. The Bonferroni correction would have made the results more rigorous so that, where previously, there was a 1 in 20 chance of the result for any particular grid square being wrong, after applying the correction, there would be only a 1 in 20 chance of any square in the whole grid being wrong.
However, no amount of applying otherwise appropriate statistical practices improves poor hypothesis formulation or testing
Merovign says:
February 21, 2011 at 1:06 am
“It is, frankly, difficult for the layman to understand how so many errors can be made in a row, accidentally, by professionals…”
This is the same thought that I had while reading Willis’ excellent post. It’s sobering that so many so-called “experts” can make so many mistakes. I guess it should be expected when people try to push a religion based on faith. Everything can be twisted and contorted into evidence to support their cause.
‘Not Even wrong’ , these miserable excuses for scientists at Nature make it quite clear that this is a war over truth. An attempt to manipulate mass behavior the world over.
It’s beyond time to throw the gauntlet down; gentlemanly discussion is useless. It’s time to call a spade a spade. Nature needs to be publicly called out and humiliated over their
new policy of scientific fictionalizing.
Thanks Willis,
When I read it I knew you would have a field day. As I see it there are at least three angles at the piece. The first on instruments, the one you did on data and methods,
and then a last one on the GCMs they selected.
I havent found anything on optimal fingerprinting.
Richard M says:
February 21, 2011 at 5:36 am
I first thing that hit me when I first read about this paper were the dates … 1951-1999. Did the world stop measuring rainfall in 1999? Why not 2009? Why not start in 1900? Does anyone else feel like this entire study was likely another alarmist cherry picking exercise?
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there was a “problem” with data after 1999. Its covered in the SI. But I didnt have access to the SI to tell you what the problem was
The cutoff date doesnt really effect the main conclusions. BUT it does show that models underestimate extreme events. Go figure 1998 and 1999 had a lot of extreme events. Since models dont represent the timing of el ninos the models under estimate extreme events in that period.
How does such sophomoric analysis get into a “prestigious” journal? The tacking of calculation upon assumption upon calculation upon assumption introduces such uncertainty that the data could not be used to show nuclear weapons cause cancer.
After hearing this description, my wife, a business major with no math background, said “it sounds like that plugged stuff into their calculator until they got the answer they wanted”.
Peter Miller says:
February 21, 2011 at 7:31 am
I am not sure if Nature is as unscientific as Greenpeace – that would be very difficult – so it was like a breath of fresh air to hear this from one of Greenpeace’s founders:
http://www.stockwatch.com/News/Item.aspx?bid=Z-C:*CURRENT-1810801&symbol=*CURRENT&news_region=C
————
Peter, I wish this were something new, but it isn’t. Patrick Moore has increasingly distanced himself from Greenpeace since he left in 1986. What would be exciting would be if other Greenpeace zealots also saw the light.
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Willis, I am in awe, as always. You have restored my faith in Divine Providence. That being said, I had to look up Weibull distribution and have to confess I am none the wiser, although apparently its very important for engineering.
There are just too many locallized surface variables that affect where and when rain will fall. The US suffered the dust bowl years in the 1930s, but was that offset with more rain in another region of the continent? Was that drought caused by changes in wind patterns that just took the rain to another location? Thus there is no way of knowing if the current data is showing any actual change in rain fall, or just changes in where the rain falls.
The only way to measure rain fall properly is to get the actual downfall a storm system drops and add them all up across the globe. Since that has not appened in the past, and would be most difficult today (radar might be one method), then there is no way we can know if there is any change in rain over time.
Is it not absurd to assume that max rainfall data correlates to stations by distance? We have all seen the thunderstorm raining only on the front yard, not the back yard, so their choice of “gridding” seems contrived. Why doesn’t anyone in climate science just average ALL the stations together and say what the yearly trend of the average is? No, they would rather create data they don’t have…
Unfortunately the brain dead UK politicians believe in this study.
http://s446.photobucket.com/albums/qq187/bobclive/?action=view¤t=Pakistanfloods.mp4
This seems pretty much par for the course. Take some data that obviously doesn’t support your idea, and then do a huge amount of complicated statistical jiggery-pokery with it. Then, hey presto, the data says what you want it to say. You get some nice headlines, and nobody in the media is interested when a while later the shenanigans are uncovered. It’s what the Team does best.
Thanks Willis for another clear analysis. There is a new precipitation database, measuring system in the US. It has been getting organized for the past few years, all volunteers. I don’t know whether this will be a separate database or is amended onto an existing one. It is the Community Cooperative Rain Hail & Snow network, or CoCoRAHS. Here is the home page http://www.cocorahs.org/
Looks like if you go to ‘Data Analysis’ under Resources, then the bottom of that page lets one download data either as Excel or KMZ files.
@richard Telford
February 21, 2011 at 1:55 am
Could this be the birth of a new logical fallacy – Argumentum ad R? Adding more tea leaves to the cup doesn’t make divination any more accurate, and if you need to use code rather than plain English to make an argument, I suspect you don’t really have one to make. All you have proven is that you most likely found the article too painful to read beyond the fifth paragraph, you find something disdainful in the word ‘sceptic’, and that commenter kadaka (1.29am) was resoundingly correct in his prediction (and I’ll bet he didn’t even have to resort to inappropriately applied statistical methods used to deliberately blur the line between observation and model results to make it).