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**JJackson** · November 25, 2008, 11:11 AM

Re: How to Think About Science - CBC podcasts

I am surprised not to see Karl Popper's name appear in the lists.

**JJackson** · November 28, 2008, 11:14 PM

Re: How to Think About Science - CBC podcasts

Originally posted by JJackson View Post

I am surprised not to see Karl Popper's name appear in the lists.

I retract the above as I have just listened to Episode 24 with Nicolas Maxwell who knew Popper and who's work largely started with Popper and refined it. Maxwell is - in my opinion - correct in both his view that their are inadequately acknowledged assumptions gnoring at science's plinth and that the scientific method has given us dangerous toys without training us to use them safely.

**JJackson** · November 30, 2008, 12:09 PM

Re: How to Think About Science - CBC podcasts

<o:smarttagtype namespaceuri="urn:schemas-microsoft-com:office:smarttags" name="country-region"></o:smarttagtype><o:smarttagtype namespaceuri="urn:schemas-microsoft-com:office:smarttags" name="City"></o:smarttagtype><o:smarttagtype namespaceuri="urn:schemas-microsoft-com:office:smarttags" name="place"></o:smarttagtype> I have been doing a bit of cooking over the weekend which has kept my hands and eyes busy but left my brain and ears free. So I have had the opportunity to listen to some more of these lectures while I cooked and they have been very interesting.

At first glance 24 one hour lectures on the philosophical underpinnings of science may not seem like the stuff of a good time but this has been time well spent. The blurb against each program in Sally’s original post is principally biographical and does not cover the content of each individual interview which, in the talks I have listened to so far, is the form they have taken. Based on these notes I have downloaded and listened to a number of episodes some of which I have commented on below.

In #24 Nicolas Maxwell provides my favourite of these downloads and it is closest to the title. Starting from the Popperian view of empirical falsification he articulates two ideas which I have probably always held subliminally but have been brought into focus by my interest, over the last few years, in H5N1 as a pandemic threat. He argues that there are a hierarchy of assumptions which underpin the supposedly rigorously empirical scientific method. As a starting point he argues that we are fooling ourselves into thinking we are searching for truth when we are starting from the assumption that the answer is basically comprehensible and simple. By simple I mean elegant and to our eyes beautiful. Given the option of a messy complex solution and a clear elegant one human nature will make us take the elegant one despite both fitting the data. He argues that dogma is weakening science by failing to acknowledge some or all of these assumptions. The institutional enterprise of science i.e. the text books, academic institutions, funding, academic promotional systems and criteria for accepting work for journal publication all have a skewing effect. The second and main point is much easier to explain it is simply that we should have become wise, or civilised, in parallel with our acquisition of knowledge but the two are out of sync and we have acquired the power to do great harm to our planet and ourselves without the wisdom to know how to control it.

#13 - Dean Bavington
If you only listen to one of this series please listen to this. It is a case study on the collapse of the Grand Banks Cod Fishery and given the state of our wild fish stocks should be compulsory listening for everyone and most especially for anyone making decisions about fish catch quotas. It highlights many of the dangers of the way we practice – and use - science and the problems of having predominantly non scientists making the critical decisions, which are political, upon data that they are basically not trained to understand. Decision makers commission research with a view to making a decision based upon it and expect an answer that will guide them but seldom fully grasp the implicit premises or confidence levels. Bavington talks about the discrepancies between the anecdotal evidence of the inshore fishermen and the research data from research vessels and commercial trawlers off shore. The anecdotal evidence was largely ignored by the scientists and not included in the reports on which management decisions were made. Bavington does not pursue this point but I think it sits at the root of two major flaws in the scientific system. Mathematics is the indispensible tool of science and with the advent of computing comes modelling. The anecdotal evidence’s crime was it did not lend itself to being quantified and, although it was not possible to ascertain how important it was, it was excluded primarily because it could not be fed into the model. The other unspoken problem is that while our mathematical tools for solving engineering & modelling problems are impressive the reality is they can not tackle most real world situations. Newtonian mechanics beautifully predicated the motion of planets but could not solve the absurdly simple (compared to most real world situations) three body problem. Our more recent understanding of the concept of Chaos has again limited the range of problems for which there is – in any meaningful sense – a solution. These limitations constrain the topics we attempt or make the caveats to our findings so wide ranging as to render the outcomes poor to useless as a basis for action.

#23 - Lee Smolin works on quantum gravity or more specifically Loop Quantum Gravity (LQG) rather than the bigger and better know String Theory. One difference is that LQG calls for a fixed background or medium in which it operates while String Theory allows for an infinite range of backgrounds in which the strings can vibrate. The problem with this is that it leaves String Theory accounting for reality but making no predictions (and no reason to believe this is temporary) and therefore un-testable. If the basis of scientific advancement is limiting options by falsification then is this a scientific theory? Smolin’s main gripe, which is much more important and general, is to do with changes in funding. In his case LQG is not fashionable and it is very difficult to get grants to work on but more generally Universities have moved form a largely autonomous system with a fair degree of individualism to all competing for grants from enormous national bodies which leads to more homogeneity in both process and the personnel on the boards. This he argues leads to inertia with, in his case, too many people in string theory and not enough in competing fields. The pressure to publish and the relative infrequency of academics being given tenure and then allowed to do their own thing – often for a long time without making a break through - is a recurring theme. I recall an interview with Richard Feynman in which he recounts being given a position at Cornell and being stuck, in part, by being concerned by feeling he should be producing something important. Bob Wilson called him in and said don’t worry about that when we appoint a professor it is our risk to put someone in this environment and if you achieve nothing it is not your problem you should do what ever you want. I don’t see this conversation occurring much these days. Feynman took him at his word and got interested in the equations governing an eccentric rotating disk after watching someone throw a plate into the air. He then found this had relevance to the spin of the electron according to Dirac’s equations which got him back into his work on QED.

#10 with Brian Wynne is another case study this time on Nuclear issues in the UK but touches on funding bodies limiting research, risk assessment and triangular communication between scientists, government and the public. As with the analysis of the Grand Banks fisheries collapse it highlights many of the same errors, failure to acknowledge the underlying assumptions in your theories and the models limits. It also puts some new concerns under the spot light. Compartmentalisation and specialisation has led to several problems, a failure to see the big picture due to not being aware of research in other disciplines and a lack of familiarity with their ways of working. The loss of confidence in the trust worthiness of science – and scientists – due to lies and spin by governments (these politicians obviously never read Sandman). The main focus was on the abuse of science and the scientific method by a Judge lead planning enquiry into a nuclear reprocessing plant and the mechanism by which political value judgements are repackaged as the inevitable consequences of the scientific evidence. While not directly addressed here this debate encompasses the problems caused by the more recent phenomenon of interest groups deliberately pushing weak science. I am sure you have seen the standard political format of putting up two opposing politicians arguing their case on TV. If you can arrange this between two scientists, confident that the audience does not have the knowledge to tell their data based arguments apart, you can muddy the water and prevent any kind of political action. This works for fishing quotas, GMO’s, nuclear power or virtually any other complex science based argument. The underlying problem is that all the really critical decisions we need to make as a society, or species, require a level of scientific literacy that neither those who will make the decision nor those who appointed them have.

In #6 James Lovelock discusses the concept of Gaia and argues that self regulating systems defy analysis and that those, like a thermostat, that we are ‘happy’ with have a goal programmed into them by us. That the Earth, since the arrival of life on it, has become a self regulating system seems to be backed up by the evidence in the global climate record and, Lovelock argues, its goal is to keep the biosphere within the range suitable for carbon based life forms. There is strong evidence to show some of these regulatory mechanisms are biological but it has not been possible to square their development with the Darwinian concept of natural selection. In short they smack of divine purpose which is not a concept that sits well with current biological dogma. Lovelock is not advocating a deity as designing the goals of the system rather than it is set by the basic properties of the universe (by which I assume he means Martin Rees’s ‘Just Six Numbers’ although he does not elaborate – I would also caution against viewing any of these as constants under all conditions, even for this universe). Although he does not state it quite like this I take his argument to be that we should consider the planet as a multi-organism life form with an obscure control mechanism and treat the Gaia theory as an extension of Natural Selection as General Relativity is to Newtonian mechanics. I have to admit to an irrational problem with this. As he says we have had to accept many things as ‘just the way things are’ without any understanding of why, this is particularly true within the Standard Model and in areas like quantum electrodynamics where there has been an unprecedented degree of accuracy in theoretical prediction to experimental data but absolutely no theory as to why it is the case (if like me you learnt ‘angle of incidence = angle of reflection’ in school physics try reading Feynman’s ‘QED’ to shatter your illusions). Why I should not have a problem accepting a lack of mechanism in Bohr’s world but not in Newton’s I do not know.

Since looking into the science surrounding the flu virus it is more than a little scary that there seems to be no mainstream debate on recombination. Henry Niman, and others, have made a plausible case for this mechanism’s role in transferring polymorphisms from one serotype, or strain, to another and if he is correct this could render our Tamiflu stockpile useless – due to a ready supply of resistance in H1N1. This seems to be a case of dogma and the PTB ignoring inconvenient data. There is also strong evidence that H5N1 has a reservoir in wild birds well outside the few countries in which it is generally accepted to be endemic but I have seen little concerted effort to use infected wild birds to develop an assaying system that can reliably test asymptomatic birds for low level infection. These seem such important and obvious lines of research it is confusing to an outsider why they were not done as a matter of urgency long ago. The other major problem has been in modelling. A closer examination of some of the models have shown some truly arbitrary values for critical input values and yet the outputs have been given significant weight in planning. Values for ‘pandemic economic consequences’ or deaths are often quoted as ranges as if the values could only fall between these limits. The other obvious problem was just how many assumptions and gross simplifications even the best models have to make to remain manageable. I had been amusing myself in the run up to the US presidential elections by looking at the polling data on the BBC site which had been running data form four different polls. I was not looking at the candidates so much as the irony that on most days each poll was giving the candidates % and margin of error but they usual did not overlap i.e. one poll would have McCain at 42% +or- 2% and another would have him at 48% +or- 2% leaving no value which would satisfy both companies, the BBC never commented or questioned this absurdity.

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How to Think About Science - CBC podcasts

How to Think About Science - CBC podcasts

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