Guest Post by Willis Eschenbach
After I’d published my previous post on the Hurst Exponent entitled A Way To Calculate Effective N, I got an email from Dan Hughes which contained a most interesting idea. He thought that it would be productive to compare the Hurst analysis of the records of weather phenomena such as temperatures and the like, with the Hurst analysis of the corresponding climate model outputs. He proposed that we take a look at the question and discuss and share our findings. Hey, what’s not to like?
Along the way, as such things happen, the topic of our discussion and investigation turned to a larger and more interesting question—`which of the various natural datasets (temperatures, rainfall, eruptions, pressures, etc) and/or the corresponding global climate model outputs are chaotic?
I must, of course, start with the obvious question … what is meant by “chaotic”? A chaotic system is a system wherein nearby initial states either converge or diverge exponentially. An example is the ocean surface. If you drop two sealed empty bottles overboard in mid-ocean, one on each side of a boat, they will drift apart over time. This separation will be slow at first, and then faster and faster as the two bottles encounter different winds and currents in different areas.
Whether a dataset is chaotic or not is generally assessed by looking at the Lyapunov exponent. This is a measure of the “stretching factor”. In our ocean example above, the stretching factor measures how fast the two points are moving apart over time. In a chaotic dataset, the stretching factor generally increases or decreases with time. In non-chaotic datasets, on the other hand, the stretching factor doesn’t vary with time. Figure 1 shows the “Lyapunov curves” of the evolution of the stretching factor with time for a variety of natural and calculated datasets.
Figure 1. Lyapunov curves for a variety of datasets. All datasets have been detrended and standardized before analysis.
Now, I’ve graphed four types of datasets above, indicated by the four colors. The first type, shown in red and mostly obscured by the blue lines, shows four different varieties of random numbers—normal, uniform, poisson, and high Hurst exponent fractional Gaussian random numbers. Basically the Lyapunov curves of the random number datasets are all plotting right on top of each other. Starting from time = 0, they climb rapidly to their maximum value and then just stay there. As we would expect from random data, there’s no trend in the stretching factor over time.
The next group, in blue, shows the Lyapunov curves for a half-dozen climate-related datasets, viz:
• HadCRUT4 Monthly Mean Surface Air Temperatures 1850-2015
• Annual Nilometer Minimum River Height 622-1284
• Stockholm Monthly Tides 1801-2001
• Central England Temperature Record Daily Maximum Temperatures 1878-2015
• Armagh Ireland Daily Mean Temperatures 1865-2001
• Annual Average Nile Flow, Cubic Metres/Sec 1870-1944
As you can see, in terms of the Lyapunov analysis, all six of these climate-related datasets (blue lines) are indistinguishable from the four random datasets (red lines), which in turn are indistinguishable from each other. None of them show any trace of chaotic behavior.
Another group of datasets, those at the bottom in gold colors, are quite different from the random and the observational datasets. They are a variety of chaotic datasets. Note that they all share a common factor—as mentioned above, over time the rate of separation (as measured by the “stretching factor”) increases. The rate of separation doesn’t just go to a certain high point and stay there like the random or climate-related datasets did. The rate of separation in chaotic datasets continues to rise over time.
Finally, there are a couple of other datasets in purple. These show observations of phenomena that are usually thought of as “forcings”. One is changes in the solar activity, with daily sunspots as a proxy for the activity, from 1880 to 2015. The other is annual aerosol optical depth from 800 to 2000, which is generally a function of volcanic action and is calculated from ice core data. Curiously, these two datasets plot somewhere in between the random observations at the top, and the chaotic datasets at the bottom. In addition, both of them show significant variation in stretching factor over time. The sunspots have a slight but significant increase. The aerosol optical depth goes down and then looks like it’s starting back up. So it seems that these two datasets are weakly chaotic.
Now, these results were a great surprise to me. I’ve long believed, without ever checking it, that the climate was chaotic … however, this analysis shows that at least those six observational datasets that I analyzed above are not chaotic in the slightest. Hey, what do I know … I was born yesterday.
Are there any climate datasets which are chaotic, even weakly chaotic? I think so. It appears that tropical ocean temperatures are weakly chaotic … but that’s a question for the next post, which will look into Dan Hughes’s idea regarding the use of the Hurst analysis to distinguish between chaotic and non-chaotic datasets.
Regards to everyone,
w.
MY USUAL REQUEST: If you disagree with someone, please quote the exact words you disagree with. That way, we can all understand the exact nature of your objection.
CODE: To calculate the Lyapunov exponent I’ve used the lyap_k function from the R package tseriesChaos. Here are the functions I used to make Figure 1:
lineout=function(col="black",testdata=testdata,line0=F,lwd=3,s=110){
output <-lyap_k(scale(dtrendlin(testdata)), m=3, d=2, s=s, t=40, ref=100, k=4, eps=4)
lines(output,main="",cex.main=.95,col=col,lwd=lwd)
invisible(output)
}
plotout=function(col="black",testdata=testdata,line0=T,lwd=3,s=110){
output <-lyap_k(scale(dtrendlin(testdata)), m=3, d=2, s=s, t=40, ref=100, k=4, eps=4)
plot(output,main="",cex.main=.95,new=F,ylim=c(-6,1),col=col,lwd=lwd,
ylab="Log(Stretching Factor)")
if (line0) abline(h=c(0,1),lty="dotted")
invisible(output)
}
dtrendlin=function(timeseries,doplot=FALSE){
outseries=timeseries
thelm=lm(timeseries~time(timeseries))
thegood=which(is.finite(timeseries))
outseries[thegood]=outseries[thegood]-thelm$fit
if (doplot){
plot(outseries)
}
outseries
}
The use by Warmistas of the term “chaos” is a political term, not a mathematical term. The political term chaos means “running around in circles waving your arms in the air and screaming we’re all going to die” which unfortunately is true. Willis here has done a nice expose of the mathematical term.
It also suggests that sunspots and optical depth do not produce chaos in the system.
There may be some evidence that the climate is chaotic but not on a time or length scale that you are using. Chaotic systems are predictable on time scales short compared to the largest Lyapunov exponent and because they are sort-of-kind-of periodic if they are low dimensional enough. This can be used to make predictions by analogy. For example, if you take the last two sunspot cycles and slide them back over the historical record, they line up fairly well with the sunspots just before the Dalton minimum around 1800. That seems to be not a bad prediction for what’s happening now with the sun.
Joe Bastardi of Weather Belle has hinted that they do the same thing for their weather forecasts by looking back in the historical record for matches with the current state of the Jet Stream, sea surface temperatures, and so on. By using the best match they can get a prediction for the near term. Lorenz tried to do something like this in 1963 but certainly didn’t have either the data or the compute power to do a good job.
Thanks, Paul. If they are only chaotic on a long timescale, then why does the weather diverge from models within a few days?
w.
That is a great question. An opinionated quasi answer. Because the weather models are unquestionably of the nonlinear dynamic sort. Per comments above, they contain time dependent feedbacks so are by definition mathematically chaotic. So, display sensitive dependence on initial conditions. Which initial conditions can never be sufficiently known, as Lorenz first showed.
Whether analog real weather operates just like its math models is debatable. I am reminded of an Einstein dictum: ‘God integrates naturally. I have great difficulties’. Hope got that dictum about right since did not Google. Regards for a stimulating post.
Weather is only chaotic on some very small surface areas of the planet giving extremes, but overall the planet’s huge surface area is a very stable system. This is why weather diverges from models within a few days. That’s just one of many reasons why only using 0.1% of the planets surface is an awful way of measuring climate.
The time scale that matters is that of the largest Lyapunov exponent, actually its inverse. If it’s three days, after five days the prediction and the weather aren’t going to match well.
I should have said back in time not time scale, my bad. I meant having data that covers long time spans so that you would have a chance for a pattern match. The “periodic” pattern you’re looking for is probably only a few days to a few weeks, a season? That is something that the meteorologists have a handle on. I don’t mean to bs you, I’m trying to just give an idea of what’s involved.
Because you’re confusing random with chaotic? Maybe? MAYBE!!??
It’s not the time scale, it’s chaotic period. If you measured your weather to the milli-degree of temp, the 1/100 of a percent of humidity and the microbar of pressure, you would notice the actual weather diverges from the model after a few seconds, rather than a few days!
“If they are only chaotic on a long timescale, then why does the weather diverge from models within a few days?”
Too many damn butterflies ; )
Ha, probably true metaphorically speaking.
Perhaps the weather/climate system is chaos short term, randomness mid-term, and back to chaos long term. Can systems be chaotic xor random on different time scales (window sizes)?. I think the answer is yes, but the math is beyond me, so it’s a hunch.
Peter
Re: Is the Climate Chaotic? 10/22/15:
This subject was a topic on WUWT on March 15. That discussion covered the questions of chaos and linearity in the climate based on external, established definitions of the two terms. But Willis immediately takes the discussion into the weeds of Lyapunov exponents and stretching. I say into the weeds because the dissertation has zero references or sources. Of course, an author can always insert his own definition, and Willis’ definition is this:
A chaotic system is a system wherein nearby initial states either converge or diverge exponentially.
But what are the “states” of the climate? Next, what are the “initial states”? Can we just pick whatever time we want for the “initial states”? Might it be an ice age or a so-called genial epoch? But why the plural “states”? What is the other one? What does “nearby” mean? Is that a distance in space, or is it in time? How do measure distance to know if these states converge or diverge?
Chapter 6 on the chaosbook.org website is about Lyapunov exponents. Part I of that book puts chaos in the context of basic notions of dynamics, prescribing 7 initial steps. The first step is, “Define your dynamical system (M,f); the space of its possible states M, and the law f^t of their evolution in time.” How do we do even get started for climate in order to apply Lyapunov anything?
Then in Chapter 6, we have, “This sensitivity to initial conditions can be quantified as [see hard to type equation in html] where lambda, the mean rate of separation of trajectories of the system, is called the leading Lyapunov exponent.
The path through the weeds produces exactly the same problem as discussed back in March. Lyapunov exponents and stretching, like the concepts of linearity and chaos, apply only to the equations of a system, not to the real world the scientist hoped to represent by his choice of equations.
The climate is neither linear nor nonlinear. It is neither chaotic nor well-behaved, and the relevant questions, like the conclusions of IPCC, are competent only with respect to the models, the system of equations.
Some people can’t tell the weeds from the forest. It’s not his fault, in a way. It’s our fault for not calling shenanigans.
By the way, just because of a low dimension analysis of the system, it appears to be random, not chaotic, it does not mean it is random and not chaotic.
You have to add dimensions from the state space and look again. And again. Until you find chaos or you find your dataset is too tiny to identify close to identical states. The later is actually the case. The case where you exhaust all dimensions I won’t take into account for obvious reasons.
There is more: Pseudo-temperature does not define the physical state of the system. Pseudo-temperature is not even part of the state of the system. To look at it to identify if the system is chaotic or not is very wrong.
Now, the big claim:
Not only the dataset is too small, but even if the dataset for the whole climate since its inception would be available, it would be still too small. The claim is that the system never ever came with its states close to an old trajectory in the state space, so even with the over four billion years of the whole climate data available, you cannot identify two close states to start comparison. The system is so complex that even with the huge time passed it had time to explore only a tiny portion of its state space and it never ever came back close to an old state. It might appear so if you use a tiny subset of the dimensions, but probably you’ll get the ‘random’ conclusion.
Comparing an insanely complex system with some very, amazingly simple mathematical systems is not ok. Not at all.
Hear, hear!
Cheers.
Somebody gets it. And somebody ain’t Willis.
Chaos: When the present determines the future, but the approximate present does not approximately determine the future.
So simple. So … chaotic.
He doesn’t understand and finds “these results were a great surprise to me.” Problem is, he still doesn’t understand.
I bet he will confuse auto-correlation again.
“You have to add dimensions from the state space and look again. And again.”
Adding dimensions to the state space and looking again was the first practical application of chaos theory I ever encountered. Add some pattern recognition to the procedure and it can be automated. It seems to be the mathematically terminal result of all the chaos blah, blah, blah.
The problem is, people are looking for some great theory, some great truth from chaos and it just isn’t there. I looked for it and ended up being very disappointed. I’m like, “That’s it? Plot the dimensions that contain the information and then look for patterns? That’s it? Ugh.”
Is Climate Chaotic?
A picture can say a thousand words.
http://i772.photobucket.com/albums/yy8/SciMattG/HADCRUT4vKelvin_zpsvihx1qfx.png
Pseudo-temperature is not the system. Climate system, if you want to talk about a sub-system of the whole, with some numerology applied. But even so, with a large enough temporal scale, you might have some (some would say tiny, using that temperature scale) chaotic surprises. Nevertheless, pseudo-temperature is not the climate.
Temperature is not the best way to measure energy, but it is the best we currently have. At least with Kelvin at absolute value, energy and temperature has a better meaning. This gives a better indication how changes we have seen over that past century+ are greatly insignificant compared to overall energy in the climate system, where zero Kelvin represents none.
I hope this sort of fits here as well. The 2014 Concordia Uni study found that there has been about 0.56 C of warming since 1800 attributable to the top 20 countries. Therefore according to this study total warming would be about 0.68 C over the last 215 years.
Not a lot of warming considering the planet’s recovery from one of the coldest periods over the last 10,000 years. I’ve read that many studies show that glacier advance was at the highest Holocene point during the LIA.
So how much of this slight warming is attributable to human Co2 emissions and why? I ‘ve read that the IPCC states that attribution starts after 1950. Here’s a reference to the study————–
http://berc.berkeley.edu/ranking-global-warming-contributions-by-country/
Any chance us mere mortals get to play in this game ?
I like the analogy of a straightjacketed crazy man in a rubber room. A lot of the time he sits around and drools. But then some tiny event in his brain stirs him into a frenzy…he rises, screaming, and runs about, bouncing off the walls, till he is exhausted. Then he settles again into a good long drool.
The Earth’s climate, i.e. weather averaged over time, is dominated by negative feedbacks. This is a necessary conclusion based on the relative stability of the climate over eons. The negative feedbacks are like the walls of the rubber room. Perhaps a chaos theorist would call them strange attractors, as in comments above.
Within the room, however, the crazy man is a chaotic system. Tiny instabilities in his brain, perhaps even a single synapse or two firing at random, can produce diverging (stretched) behavior of comparatively large magnitude. One moment he is sitting, the next bouncing off the west or the north wall. Yet the walls keep him in within a certain locus.
Thus the weather may be chaotic, but the climate overall, bounded as it is by the negative feedbacks of clouds, storms, ocean heat sinks, etc., is far less so.
I like that analogy, it seems to apply well.
Sometimes I wonder if Man’s ego calls something “chaotic” as an excuse. If Man doesn’t really know what’s going on, call it “Chaotic”. If Man can put a name to what is beyond him then, somehow, he really does know. After all, Man gave it a name so Man’s “on top of it”.
GD, mathematical chaos is precisely defined as a consequence of non-linear dynamic systems (having time dependent feedbacks, for the uninitiated). Now, whether and how that abstract math applies to Earth is a discussion worthy subject.
Thank you.
So in Math “chaos” has a literal meaning. Beyond that it’s more of a figure of speech or a … comfort? … as I used it.
Sort of like “imaginary numbers”. Are we talking Math or climate science? 😎
I think you are onto something here. Chaos has certain characteristics that identify it and I think Lorenz’s discovery of it is viable, but I suspect that the term gets broadly used when we can’t quite figure something out satisfactorily. I notice in discussions on climate, the word it self is repeated and hurled about and coupled atmosphere/ocean/land complexities are bemoaned – it is a kind of sophisticated hand waving thing. I’ve questioned this before – usually following a dissertation by Dr. Robert Brown on the intractability of determining where climate is going.
Having the luxury of not being taxed with resolving such issues, I just offer that for such chaos, somehow there seem to be only a few kinds of weather (I reckoned 10 in a comment above where I live, probably half that in the tropics) and each time I’ve seen them, they look pretty much like the last 1000 times I’ve seen it. A sunny day at the beach on a clear day in 1950 looks like a carbon copy of the same thing in 2015. A rainy April in Ottawa, Ontario is indistinguishable from one year to another. Heck, we had a thread on here many months ago that talked about the few days earlier the cherry blossoms were blooming in Japan in 2014 compared to 50 years ago.
Look at the polar ice graphs they pretty well waggle up and down a bit more or a bit less and change direction on September 22nd at both poles!! Farmers get caught once in a while planting a week or two early but generally agricultural output follows pretty smooth curves. The first frost, the first and last snows, the tropical storm and tornado seasons….a nor’easter bring rain, nor’wester cold and snow in the fall to spring, pineapple expresses, Colorado lows, ………even migratory birds get it pretty well right and monarch butterflies begin to collect in the Niagara Peninsula in Ontario in the fall where they wait for the never failing north wind to assist them in their flight over lakes Ontario and Erie. How chaotic is that?
Is The Climate Chaotic?
Word has it;
” While the earth remaineth, seedtime and harvest, and cold and heat, and summer and winter, and day and night shall not cease. ”
~ Modeler of modelers ; )
Gunga has just defined a large percentage of what we currently call science.
But the concept of chaos in not that complex. Chaos: When the present determines the future, but the approximate present does not approximately determine the future.
In other words, the fine grain of our future state is unpredictable and unknowable. Anyone who can’t deal with that has yet to grow up. Chaos is what makes life interesting. If the future were predictable we would all be very bored.
Unless we had a copy of “Grey’s Sports Almanac”. 😎
(Reference to “Back to the Future” for those I just confused.)
As long as there is some kind of tax on the air being considered, then I feel better.
I’m sure the largest emitters will pledge …something.
It’s all good, didn’t even have to fly all those private jets to the coven.
Nobody notices expenditures like that.
Nobody.
Willis
Far too many people equate temperature with climate. Temperature is merely one of the variables that make up climate (others include humidity, precipitation (amount, nature and cycles thereof), air pressure, wind, windiness, influenced by El Nino/La Nina conditions etc etc). Each of these parameters is variable, and constantly varying within bounds, and each may interact with each other.
I am far from convinced that you have looked at climate. It seems to me that you have only looked at a couple of the parameters (predominantly temperature) that go into the climate melting pot, and thus you are not in a position to say that climate is not chaotic.
That said, your findings are interesting.
Ya, or from the hospital bed “who woulda thunk” 🙂
The path of least resistance allows a degree of randomness. The issue is, how wide is the path. That is likely bounded by statistics related to regional extremes combined with broader regime shifts.
the shortest and toughest answer available. Thx. Hans
If more than to forcings work on a system the result is chaos?
two
“If you drop two sealed empty bottles overboard in mid-ocean, one on each side of a boat, they will drift apart over time. This separation will be slow at first, and then faster and faster as the two bottles encounter different winds and currents in different areas.”
Man, I don’t like that definition of chaos. So the bottle’s separation is at first not chaotic and when it reaches the magic exponential threshold it suddenly becomes chaotic? A black hole is chaotic?
No. This is that Lorenzian statistical chaos that drives me nuts. Granted, it has some impressive practical applications in information theory. Our cell phones work because the medium is the message.
Every message must have a medium. The waves in the ocean would not exist without the water. But just because impressive practical applications can be derived from a particular definition of medium and regressed in that framework does not mean that the medium or the regression is fundamental.
Take Isaac Newton. My God, what a medium he construed, and what incredible derivations followed from that. Yet we now believe his medium is fundamentally untrue.
Gym, Nicely put. : )
Would an arbitrary human life, from conception to death, be any easier to predict?
Let’s get small ??
Like!
beautiful
I recommend reading the climate research being performed by Dr. David Evans at the following location. At the present time there are 14 articles which will be followed by more. These articles contain semi_complicated math but the theory is presented in bite size chunks. The data presented by Dr. Evans accepts all the IPCC values and then shows how the models are incorrectly constructed. He states that there is an intellectual mind block because warmest state that the math is dead on while the sceptics state that observations invalidate the math.
http://joannenova.com.au/tag/climate-research-2015/
Many years ago I heard an interview with Edward Lorenz (the father of chaos theory). He described his aha moment.
Lorenz was running a climate model and needed the results for a conference. Something went wrong before the model could finish its run and the results were incomplete. He decided that if he re-ran the model with fewer significant digits, it would run faster (and he would have something to present at the conference). His results wouldn’t be as accurate but they would be a sufficient approximation. What he actually found, however, was that the results were completely different.
As far as I can tell, Lorenz defined the climate as the very prototype of a chaotic system.
1 – The climate is exquisitely dependent on initial conditions.
2 – It is impossible to define the initial conditions with sufficient accuracy.
3 – It is impossible to have enough significant digits to compute an accurate result.
4 – Therefore, changing anything (even slightly) about the inputs to the model results in completely different outputs. butterfly effect
Nature is not chaotic. You can make a intelligent guess if the apple will fall down or up or if it will snow or rain. Natural laws give some limits of variations and even within those limitations You can predict fairly good by observing and calculating.
I don’t think that’s true. Look, for instance at water droplets from a dripping tap (a description of how they are chaotic appears above). Or snowflakes, shorelines, thousands of possible examples ranging right down to the fingerprints on your hand.
Within limits!
I think you may have your own definition of chaos. With the other definition of chaos, the scientific one, most natural dynamical systems (non linear, not at equilibrium) are chaotic. You may find many exceptions with simple ones, but there are plenty of simple ones that are chaotic, too.
To be chaotic means: to be sensible to initial conditions, to have dense periodic orbits and to be topologically mixing. It does not matter that the state space is bounded. It does not matter how you perceive the distance between bounds. With a change of scale it might appear tiny, anyway. Look what Matt did with the pseudo-temperature not so far above. Despite that, it does not show that the system is not chaotic.
Sometimes, you may get away with a change of scale. For example, even a gas with a well defined and unchanging temperature (that is, at equilibrium) is indeed chaotic. Just look at what molecules do.
But the macro system appears not to be. Of course, in this case there is the luxury of being at equilibrium, a luxury that real natural systems seldom offer.
Put that gas out of equilibrium, make it flow and have temperature and pressure fields rather than the same everywhere and things get quite interesting indeed. And quite hard to predict for a long time, except some very particular and simple setups.
I am not sure, but I get an uneasy feeling that you have not got the right definition of chaotic – more like a definition of ‘unbounded’.
Divergence is not the same as chaos
Nor it seems is Lyapunov a criteria of chaos, but of stability.
https://en.wikipedia.org/wiki/Lyapunov_function
And the exponent that shows divergence is indeed an indicator of chaotic behaviour, but the converse is not true. Non divergence does not indicate non chaos, as many chaotic systems are bounded and represent chaotic orbits around attractors.
I fear all you have done here is prove mathematically that Climate is (reasdaonably) stable and governed by some kind of overall negative feedback, which is pretty obvious given the fact life exists at all.
I suspect its quite difficult to come up with a metamathematical test for chaos – especially chaos with many variables.
One approach is of course Fourier analysis. But quasi periodic chaotic behaviour might show up there too as a peak in the spectral density.
I deficiently applaud the intention shown in this article, but I fear – though I do not have quite enough maths to prove – that you have missed the target a bit.
Chaos mathematics has not been developed very much and its not a popular subject, because it doesn’t give answers. by and large.
But this attempt shows we do need a test for regions of chaos so we can mark them with ‘Here Be Dragons: Give up or die” and move onto more profitable endeavours.
I just dont think Lyupanov is the acid test.
http://www.hindawi.com/journals/mpe/2010/720190/
us a very interesting paper.
“Lyapunov exponent is the most important quantity to chaotic systems as a positive maximal Lyapunov exponent is a strong signature of chaos. In the contrary, a zero maximal Lyapunov exponent denotes a limit cycle or a quasiperiodic orbit and a negative maximal Lyapunov exponent represents a fixed point.”
Which I think says what I was trying to say. if its positive its chaotic but if its zero its not necessarily non-chaotic.
Anyway that paper – which I found before, asking a similar question, had one important effect on me personally. I realised I dont have the maths or the time to acquire it to answer the question.
My humble point is to suggest that you too may not have quite enough maths, either, which shouldn’t be taken as a criticism, because there seem to be only half a dozen people in the world who do.
It actually us a compleat bitch of a problem. And requires a mathematical genius or three to answer.
So many papers are written, peer reviewed, and published whose authors suffer from exactly the same problem. Folks with a weak understanding of statistics or signal processing will throw data into a random tool and think they have meaningful results. It’s pathetic but the really pathetic part is that it gets past the editors and peer reviewers. Here’s my favorite example …
If one looks at enough factors, any data set will produce correlations. Naturally, the authors avoided the participation of any genuine statisticians; that would have spoiled the hoax. It’s fairly obvious that any paper that uses any mathematical analysis should involve real mathematicians. That should have stopped Michael Mann dead in his tracks.
Engineers understand that they should practice within the limits of their knowledge, skills and abilities. Many scientists seem to lack that understanding. [/rant]
The opposite of what I had assumed. There is hope therefore that Climate and Weather Science may yet achieve to level of understanding and predictive capability.
I am puzzled by your methodology & conclusion.
In order of predictability the ladder is
constant > periodic + linear > “simple” non linear > chaotic > random.
So, regarding methodology, to answer the question “Is The Climate Chaotic?”, I would
* since “weather is not climate”, I wouldn’t use weather data, but climate data : yearly averages of rain, solar irradiance, number of days with rain, freezing temp, high speed winds… Climate is much more predictable than weather, as the saying goes “climate is what you expect, weather is what you get”.
* indeed use, as comparisons, a single random (one is enough) and a couple of known chaotic maps, but also some more predictable maps (sunrise hour at your home for instance). I would also add some funnies : my heartbeat data, Dow Jones, population of New York …
And, regarding conclusion, after your work I wouldn’t say that weather/climate variables are “weakly chaotic”, but, quite the reverse : so “highly chaotic” that they compare more to random than to usual chaotic reference such like logistic map. But then again that’s because you used weather variable, not climate. I guess climate will to much less random.
Natural laws tend to give limitations of variations and even within those limitations. It is easy to predict by carefully observing and calculating.