Many scientists look on chemistry and physics as ideal models of what psychology should be like. After all, the atoms in the brain are subject to the same all – inclusive physical laws that govern every other form of matter. Then can we also explain what our brains actually do entirely in terms of those same basic principles? The answer is no, simply because even if we understood how each of our billions of brain cells work separately, this would not tell us how the brain works as an agency. The “laws of thought” depend not only upon the properties of those brain cells,but also on how they are connected. And these connections are established not by the basic, “general” laws of physics, but by the particular arrangements of the millions of bits of information in our inherited genes. To be sure, “general” laws apply to everything. But, for that very reason, they can rarely explain anything in particular.
– Marvin Minsky in The Society of Mind pp. 26
science
Knowledge: Technical and Scientific
Utility had been deliberately excluded from Aristotelian natural philosophy. Aristotle had nothing against practical knowledge, which he called techne; he simply did not consider it to be the same kind of thing as scientific knowledge, which he called episteme. From techne we have the word technology, which means to us largely the application of scientific knowledge, while from episteme we have the word epistemology, a branch of philosophy that deals with the theory of knowledge, scientific or any other. For Aristotle, however, the difference between techne and episteme was not a difference between application and theory, but was one of sources of knowledge and goals of knowledge. The source of technical knowledge was practical experience and its goal was, roughly speaking, knowing what to do next time. The source of scientific knowledge was reason, and its goal was the understanding of things through their causes.
– Stillman Drake, Galileo A Very Short Introduction (p. 4)
Open Access Manifesto
Information is power. But like all power, there are those who want to keep it
for themselves. The world's entire scientific and cultural heritage, published
over centuries in books and journals, is increasingly being digitized and locked
up by a handful of private corporations. Want to read the papers featuring the
most famous results of the sciences? You'll need to send enormous amounts to
publishers like Reed Elsevier.
There are those struggling to change this. The Open Access Movement has fought
valiantly to ensure that scientists do not sign their copyrights away but
instead ensure their work is published on the Internet, under terms that allow
anyone to access it. But even under the best scenarios, their work will only
apply to things published in the future. Everything up until now will have been
lost.
That is too high a price to pay. Forcing academics to pay money to read the work
of their colleagues? Scanning entire libraries but only allowing the folks at
Google to read them? Providing scientific articles to those at elite
universities in the First World, but not to children in the Global South? It's
outrageous and unacceptable.
"I agree," many say, "but what can we do? The companies hold the copyrights,
they make enormous amounts of money by charging for access, and it's perfectly
legal - there's nothing we can do to stop them." But there is something we can,
something that's already being done: we can fight back.
Those with access to these resources - students, librarians, scientists - you
have been given a privilege. You get to feed at this banquet of knowledge while
the rest of the world is locked out. But you need not - indeed, morally, you
cannot - keep this privilege for yourselves. You have a duty to share it with
the world. And you have: trading passwords with colleagues, filling download
requests for friends.
Meanwhile, those who have been locked out are not standing idly by. You have
been sneaking through holes and climbing over fences, liberating the information
locked up by the publishers and sharing them with your friends.
But all of this action goes on in the dark, hidden underground. It's called
stealing or piracy, as if sharing a wealth of knowledge were the moral
equivalent of plundering a ship and murdering its crew. But sharing isn't
immoral - it's a moral imperative. Only those blinded by greed would refuse to
let a friend make a copy.
Large corporations, of course, are blinded by greed. The laws under which they
operate require it - their shareholders would revolt at anything less. And the
politicians they have bought off back them, passing laws giving them the
exclusive power to decide who can make copies.
There is no justice in following unjust laws. It's time to come into the light
and, in the grand tradition of civil disobedience, declare our opposition to
this private theft of public culture.
We need to take information, wherever it is stored, make our copies and share
them with the world. We need to take stuff that's out of copyright and add it to
the archive. We need to buy secret databases and put them on the Web. We need to
download scientific journals and upload them to file sharing networks. We need
to fight for Guerilla Open Access.
With enough of us, around the world, we'll not just send a strong message
opposing the privatization of knowledge - we'll make it a thing of the past.
Will you join us?
Aaron Swartz
July 2008, Eremo, Italy
via | Open Access Manifesto
Michael Faraday
Can Stars Be Seen in Daylight?
The constellations that we saw at night half a year ago are now overhead in the daytime. Six months later they will again adorn the night sky. The sunlit atmosphere of the Earth screens them from the eye because the air particles-disperse the sun-rays more than the rays emitted by the stars. (The observer located on the top of a high mountain, with the densest and dustiest layers of- the atmosphere below, would see the brighter stars even in daytime. For instance, from the top of Mt. Ararat (5 km. high), first-magnitude stars are clearly distinguished at 2 o’clock in the afternoon; the sky is seen as having a dark blue colour.)
The following simple experiment will help explain why the stars disappear in daylight. Punch a few holes in one of the sides of a cardboard box, taking care, however, to make them resemble a familiar constellation. Having done so, glue a sheet of white paper on the outside. Place a light inside the box and take it into a dark room; lit from the inside; the holes, representing stars in the night sky, are clearly seen. But, switch on a light in the room without extinguishing the light in the box and, lo, the artificial stars on our sheet of paper vanish without trace: “daylight” has extinguished them.
One often reads of stars being seen even in daylight from the bottom of deep mines and wells, of tall chimney-stacks and so on. Recently, however, this viewpoint, which had the backing of eminent names, was put to test and found wanting. As a matter of fact, none of the men who wrote on this subject, whether the Aristotle of antiquity or 19th-century Herschel, had ever bothered to observe the stars in these conditions. They quoted the testimony of a third person. But the unwisdom of relying on the testimony of
“eye-witnesses,” say in this particular field, is emphasized by the; following example. An article in an American magazine described daylight visibility of stars from the. bottom of a well as a fable. This was hotly contested by a farmer who claimed that he had seen Capella: and Algol in daytime from the floor of a 20-metre high silo. But when his claim was checked it was found that on the latitude of his farm neither of the stars was at zenith at the given date and, consequently could not have been seen from
the bottom of the silo.
Theoretically, there is no reason why a mine or a well should help in daylight observation of stars. We have already mentioned that the stars are not seen in daytime because sunlight extinguishes them. This holds also for the eye of the observer at the bottom of a mine. All that is subtracted in this case- is the light from the sides. All the particles in the layer of air above the surface of the mine continue to give off light and, consequently, bar the stars to vision.
What is of importance here is that the walls of the well protect the; eye from the bright sunlight; this, however, merely facilitates observation of the bright planets, but not the stars. The reason why stars are seen through the telescope in daylight is not because they are seen from “the bottom of a tube,” as many think, but because the refraction of light, by the lens or its reflection in the mirrors detracts from the brilliancy of the part of the sky under observation, and at the same time enhances the brilliancy of the stars (seen as points of light). We can see first-magnitude and even second-magnitude stars in daytime through a 7 cm. telescope. What has been said, however, does not hold true for either wells, mines, or chimneys.
The bright planets, say, Venus, Jupiter or Mars, in opposition, present a totally different picture. They shine far more brilliantly than the stars, and for this reason, given favourable conditions, can be seen in daylight.
From Astronomy for Entertainment – Yakov Perelman Pg: 135-137
Available here.
Deductive Theory in Science
Does Tulsi has environmental benefits too?
Recently there was a news item in Times of India which had the same heading as that of this particular post. The news claimed
(Around two decades back Dada Dham, a socio-spiritual organization brought together a team of botanists, ayurvedic scholars and environmental enthusiasts to study the environmental benefits of tulsi.)NAGPUR: Ayurvedic medicinal values of Tulsi are well known. Our ancient scriptures have enumerated the medicinal benefits of tulsi. Its extracts are used widely for curing common ailments like common cold, headache, stomach disorder etc.
But the environmental benefits have been comparatively unknown. Around two decades back Dada Dham, a socio-spiritual organization brought together a team of botanists, ayurvedic scholars and environmental enthusiasts to study the environmental benefits of tulsi.
“Tulsi gives out oxygen for 20 hours and ozone for four hours a day along with the formation of nascent oxygen which absorbs harmful gases like carbon monoxide, carbon dioxide and sulphur dioxide from the environment,” said Shyamkant Padoley, an eminent botanist.
Ozone is a powerful oxidant (far more so than dioxygen) and has many industrial and consumer applications related to oxidation. This same high oxidizing potential, however, causes ozone to damage mucus and respiratory tissues in animals, and also tissues in plants, above concentrations of about 100 parts per billion. This makes ozone a potent respiratory hazard and pollutant near ground level.…There is evidence of significant reduction in agricultural yields because of increased ground-level ozone and pollution which interferes with photosynthesis and stunts overall growth of some plant species. The United States Environmental Protection Agency is proposing a secondary regulation to reduce crop damage, in addition to the primary regulation designed for the protection of human health.…There is a great deal of evidence to show that ground level ozone can harm lung function and irritate the respiratory system.Exposure to ozone and the pollutants that produce it is linked to premature death, asthma, bronchitis, heart attack, and other cardiopulmonary problems.…
Padoley, member of technical committee, ministry of environment and forest, NewDelhi, and forest tech committee, also read a paper at the International Conference on Occupational Respiratory Diseases at Kyoto in 1997 where cyclo oxygenate, an enzyme only found in tulsi was labelled for the first time. This enzyme regulates the entire mechanism of oxygen evolution. (emphasis added)
This again I am unable to understand. It says this enzyme is “only found in Tulsi”, and it also “regulates entire mechanism of oxygen evolution”. One can agree that a particular enzyme is found in a particular plant, but if this enzyme controls “entire mechanism of oxygen evolution”, how do other plants regulate their mechanisms of oxygen evolution.
Dada Dham initiated a campaign ‘Tulsi Lagao Pradushan Hatao’ in 1987 under the guidance of Narendra Dada, the institution’s head. It was under this campaign that the above mentioned panel of experts was formed. After finding out the environmental benefits of the plant, Dada Dham organized a number of programmes like street plays, nukkad sabhas and lectures to propagate the use of the plant.
Dr Dattatraya Saraf, an ayurvedic doctor and expert said, “The plant enriches the environment with oxygen almost 24X7 and also absorbs other pollutants.” He further added that if the size of the plant can be increased, the environmental benefits can be increased.
This statement that “plant enriches the environment with oxygen almost 24X7” is in contradiction to statement by above Padoley regarding 20 and 4 hour cycles. Which one is to be believed? And mind you this is just appearing a few lines later, this is either very poor editing and reporting, or hogwash to the public.
“That is why we want to urge scientists and concerned authorities to make research on the issue of increasing the height of tulsi plant. If big trees can be converted to bonsai plants then big tulsi trees can be possible too,” said Kishor Verma, PRO of Dada Dham.
This is another statement that I would like to contest. Did they compare the rate of oxygen production vis-a-vis to other plants. That is to say simply did they have any control sample? And does making “tulsi tree” make any sense (can one really do it is another question), will it really increase oxygen making capabilities, is it a linear relationship between these two variables? The water is completely muddy in this !
He also citied the research and work by other organization in support of tulsi’s environmental benefits.
“The forest department of Uttar Pradesh, with the help of an organization called Organic India Limited, Lucknow planted lakhs of tulsi saplings around Taj Mahal to protect its surface from industrial emissions. This step has yielded positive results,” Verma said.
“We are just asking the administration to take notice of these extra ordinary benefits of tulsi and take steps for utilizing them. Even simple steps like planting tulsi plants on road dividers, parks etc can bring a difference,” said Verma.
The reporter and also the editor make no effort to correct these glaring inconsistencies in the report itself, forget about doing nay research on the topic, or verifying the claims made by these people. Maybe this was like the paid news that is talked about a lot these days.
What I find here i that the agenda of what is to be done was already set, the conclusions were already drawn, by our ancestors, written in black and white in ancient texts. The point was only to justify what they were doing, and trying to provide a “scientific basis” of what they already believed to be true (for whatever reasons, mostly religious, and presence of a religious organization in this sort of confirms this).
A good example of pseudo-science and bad science reporting.
Science, a humanistic approach
Science is an adventure of the whole human race to learn to live in and perhaps to love the universe in which they are. To be a part of it is to understand, to understand oneself, to begin to feel that there is a capacity within man far beyond what he felt he had, of an infinite extension of human possibilities . . .
I propose that science be taught at whatever level, from the lowest to the highest, in the humanistic way. It should be taught with a certain historical understanding , with a certain philosophical understanding , with a social understanding and a human understanding in the sense of the biography, the nature of the people who made this construction, the triumphs, the trials, the tribulations.
I. I. RABI
Nobel Laureate in Physics
via Project Physics Course, Unit 4 Light and Electromagnetism Preface
Do see the Project Physics Course which has come in Public Domain hosted at the Internet Archive, thanks to F. James Rutherford.
CURE Logo
In earlier post we had seen the CUBE Logo, now in this post we will see, CURE Logo. CURE stands for a cure of problems of CUBE and is Collaborative Undergraduate Research and Education. The idea is to propagate the spirit and activities via making many-many centres across India and when one centre gets the know-how, it starts acting as a centre itself. This has enormous potential and is also not so easy, if we are planning to form a network of 20,000 odd colleges across India. Hats off to this initiative by Dr. M. C. Arunan.
Since the idea was to propagate the via forming numerous nodes, and absence of a centralized structure, we came up with the Pythagorean Tree as one of the possible candidates for the logo. The Pythagorean Tree is a fractal structure which is self similar. This also reflects the spirit of CURE and CUBE, that the size of the institute or its location should not reflect on the facilities or the opportunities that it provides to its students.
In this program an initial batch of students , lets call them Batch-0 is trained for performing a series of experiments . At end of their training which is a hands on, they give a talk on their work. In the next step, these students build these facilities at their alma mater and maintain them. This is the first iteration of the program. After this iteration, the Batch-0 students, who have handled these biological systems for some time now and carried out some investigations become mentors for the next batch of students. Lets call these as Batch-1. Now we conduct another session of training, in this the Batch-0 students act as mentors for Batch-1 students. Thus at end of this training another iteration of the programme is completed. So the second iteration builds on the first one. Then for the Batch-2 students, the students from earlier batches act as mentors, thus at each stage we are increasing the mentors as well as the facilities available for doing research. Iteratively, collaboratively we can sure reach the 20,000 odd under-graduate colleges in India
In the logo the base triangle forms the basis of all the structure, this we call as Batch-0, and rest of all others are based on this. And since this is an iterative, self-similar figure, none of them are different from one another, neither are the squares different. For example the small branch sitting on top of the large branch is a similar to the larger branch. If we scale it. it would be the same.
Lack of research facilities at the undergraduate level , is most often cited as cause for poor education at that level. And the facilities come expensive. This was we can make in-expensive or some times zero-expense facilities for college education and get the students involved. This logo is released under Creative Commons Share Alike License. The logo was made using Free Software for vector editing Inkscape.
Explosives or Not
We have earlier seen some quotes from the book The Golem: What You Should Know About Science. There are two companion volumes to this book The Golem Unleashed: What You Should Know about Technology and Dr. Golem: How to think about Medicine. These series of books by Harry Collins and Trevor Pinch provide us with examples from these fields which most of the times are ‘uncontested’. For example in the first volume they discuss about the famous 1920 experimental confirmation of Einstein’s predictions in general relativity by Eddington. This experiment is told as a matter-of-fact anecdote in physics, where petty borders of nationalism could not stop physics and physicists. But in the book, as they show inspite of scanty or almost no positive evidence, Eddington “Concluded” that the predictions were true. This they term “experimenters’ regress”.
The experimenter’s regress occurs when scientists cannot decide what the outcome of an experiment should be and therefore cannot use the outcome as a criterion of whether the experiment worked or not.
– The Golem Unleashed pp. 106
In The Golem Unleashed they present us with many examples of this from field of technology. One of the examples is from the Challenger accident which Feynman made famous by courtroom drama. In this case they call the “experimenter’s regress” as “technologist’s regress”.
Recently I read (all further quotes from the same link)an episode in India which would fit in very with these episodes. This is regarding baggage scanning machines installed at Indian airports. They were brought at 2 crore rupees per unit in 2010. But in August 2011 they failed the tests on tasks they were supposed to do.
The scanners are called in-line baggage inspection systems as they scan bags that go into the cargo hold of the aircraft after passengers check in and hand over their luggage to the airline. They use x-ray imaging and “automatic intelligence” to verify the contents of bags and determine whether they include explosives.
Now one would think that this would be as easy as it gets. Either the scanner detects whether the explosives are present in the baggage or they do not. But it is not as simple as it seems so. Now when the tests were done, the testers found the machines failed.
During the tests, security sources said that a technological specification committee of officials from the IB, RAW, SPG, NSG, BCAS and the civil aviation ministry passed bags containing 500 gm of six kinds of explosives, including PETN and ammonium nitrate, as well as IEDs through these systems. The scanners did not flag any of these bags as suspicious, the sources said.
So after this “failure” the companies which supplied these machines were asked to improve upon the machines or to share the software to recalibrate them. But the companies and interestingly Airport Authortiy of India AAI said that the testing methods were at fault. Now the explosives were passed and the machines did not detect them, then how can companies say that the testing methods were not working?
The machines work on the so called 70:30 principle.
“Though it works on a 70:30 principle, if there is an explosive in the 70 per cent, it will throw up the image of each and every bag that has dangerous substances. We would like to emphasise that the systems supplied and installed by our company at Indian airports are of state-of-the-art technology and are fully compliant with current standards.”
The 70:30 principle refers to the “automatic intelligence” used by Smiths Detection machines to clear 70 per cent of the baggage and reject the rest, according to the Airports Authority of India (AAI). “The machines reject 30 per cent of the baggage, the images of which are then sent to the screener. These systems have automatic intelligence capability and have been tested against a wide range of substances considered dangerous for aircraft. The details and specifications are never disclosed, or else terrorists would understand the software,”
But if anyway machines are doing the job, why not do it 100%? And the funny thing is that they are not sharing the software, which is the main agenda of the proprietary software companies. This is a case where people realize that they are just Users of the software under question. This argument that “or else terrorists would understand the software” does not hold. They don’t need to if the machine is going to reject a whole lot of bags And in anyway if there are bus/holes in the software, a thousand eyes repair them much faster than a few. And this is The companies further say that
“The technology or physics is that x-ray based system can’t detect explosives, it is only approximate detection of dangerous substances,”
Why is the AAI siding (they are rather defending the companies) with the companies is something worth pondering.
AAI people say “The problem could be due to the sheer ignorance of officers who lacked the skills to test for explosives,”
Still with no unanimity in the testing results, the case truly presents us with a “technologist’s regress.”