Rashad Alakbarov Paints with Shadows and Light:
You're reading: Yearly Archives: 2012
Why the hot light bulb annoys me
A new post is available over at Second-Rate Minds by Peter Rowlett.
The light bulb puzzle presents you with three switches, one of which controls a light bulb inside a closed room. You are permitted to flip switches as much as you like, then you must open the door and say which switch controls the light bulb. You don’t seem to have enough information. You can …
Read the full post: “Why the hot light bulb annoys me“
Favourite popular mathematics books
I consider popular mathematics writing to be a good thing. I even tried a little myself and would be keen to try more. I am not, however, an expert in this genre. I certainly read popular maths and science books as a teenager and I remember fondly, along with a couple of physics books and biographies, the mathematical stories told in James Gleick’s Chaos, Ivars Peterson’s The Mathematical Tourist and Simon Singh’s Fermat’s Last Theorem. I’m not sure this is sufficient qualification to have a strong critical opinion. I have a copy of Alex Bellos’ Alex’s Adventures in Numberland that I was bought last birthday and, although it is on the top of my pile and I feel sure I will enjoy this when I get chance (perhaps someday I’ll spend a holiday not worrying about my PhD), I haven’t quite got around to reading it.
This week Guardian Books offered Ian Stewart’s top 10 popular mathematics books in which, the description promises, “the much-acclaimed author chooses the best guides to ‘the Cinderella science’ for general readers”. Why Cinderella you ask? Stewart means this in the sense at the start of the story, “undervalued, underestimated, and misunderstood”, and perhaps intends popular mathematics to take mathematics to the ball, saying:
Popular mathematics provides an entry route for non-specialists. It allows them to appreciate where mathematics came from, who created it, what it’s good for, and where it’s going, without getting tangled up in the technicalities. It’s like listening to music instead of composing it.
It will be no surprise, after the opening paragraph, if I admit that I neither own nor have I read any of Stewart’s choices. I’ve heard of several of them but by no means all. I was surprised by the inclusion of Newton’s Principia. In the back of my mind I have collected the ‘fact’ (citation needed) that Newton is a difficult read and I felt this made it a strange choice against the aim to bring “the best guides to ‘the Cinderella science’ for general readers” (though I’m aware the description will have been added later, possibly without Stewart’s knowledge). Stewart justifies its inclusion as “a great classic” saying that although this is “not popularisation in the strict sense”, this “slips in because it communicated to the world one of the very greatest ideas of all time: Nature has laws, and they can be expressed in the language of mathematics” and claims “no mathematical book has had more impact”.
On Twitter, Tony Mann confirmed my half-remembered notion that “Principia is hard, very hard. Even in English“. As to the claim of impact, Tony suggested Stewart should have chosen the Latin version as having more impact. Thony Christie agreed this is “a very hard book to read and comprehend“, though Christian Perfect suggested that he found the scans of Newton’s college notebooks which were recently made available online to be “quite readable“.
Reading what Stewart wrote about Newton’s Principia and its impact in the history of science, I wonder if the book was chosen more to tell the story in the article than out of a serious suggestion that it might be read. Christian Perfect makes this point more generally about the list over on my Google+ page:
I think he’s chosen 10 books about his favourite mathematical ideas rather than 10 books which most effectively communicate mathematical ideas to a member of the “populace”.
To include a classic, I wondered if something like Euler’s Elements of Algebra, which I had heard travels fairly well to a modern reader, might be a more appropriate choice. On my G+ page, Sarah Kavassalis suggested “one of Poincaré’s popular books instead though, for readability”.
I asked people for their thoughts on the list and what else they would include. It’s quite noticeable that several respondents report not having read many on the list (the same is true of the comments under the original article). Alex Bellos, on G+ expands on this:
I guess there are two types of “popular” – 1) something accessible for people who know no maths and 2) something fun for the math literate. I’d say Ian’s list is very much the latter. If a lay friend asked me for a maths book suggestion they might understand and enjoy, I would only recommend the first two on his list [Robert Kanigel’s The Man Who Knew Infinity and Douglas Hofstadter’s Gödel, Escher, Bach].
Given the popular medium and Stewart’s introduction to the article, in which he talks about popular mathematics as “an entry route for non-specialists”, it is strange to see the list being regarded in this way. There’s nothing wrong with a list of fun books for maths folks, with something to surprise us rather than just the obvious choices, but if that was what was intended then this probably should have said so. I worry about someone using this list to build a ‘must-read’ list and perhaps being put off popular mathematics as a result.
I also asked for your suggestions and these follow. It may not be fair but I have listed these in the order they were suggested. I’ve included descriptions, except where stated these are those given on Amazon UK.
Thank you to everyone who played along with this little game. We’ve got more than ten and I can’t vouch for which would suit “people who know no maths” or “the math literate”, but I’ve enjoyed looking through the suggestions. Further suggestions are, of course, welcome via the comments.
Alex Bellos’ Alex’s Adventures in Numberland (US title: Here’s Looking at Euclid)
Suggested by Vincent Knight and Singing Hedgehog on G+.
In this richly entertaining and accessible book, Alex Bellos explodes the myth that maths is best left to the geeks. Covering subjects from adding to algebra, from set theory to statistics, and from logarithms to logical paradoxes, he explains how mathematical ideas underpin just about everything in our lives.
Edwin Abbott’s Flatland: A Romance of Many Dimensions
Suggested by Sarah Kavassalis (“very different approach to popular mathematics”) and Singing Hedgehog (“strange since Ian Stewart wrote the follow up Flatterland!”) on G+.
How would a creature limited to two dimensions be able to grasp the possibility of a third? Edwin A. Abbott’s droll and delightful ‘romance of many dimensions’ explores this conundrum in the experiences of his protagonist, A Square, whose linear world is invaded by an emissary Sphere bringing the gospel of the third dimension on the eve of the new millennium. Part geometry lesson, part social satire, this classic work of science fiction brilliantly succeeds in enlarging all readers’ imaginations beyond the limits of our ‘respective dimensional prejudices’.
Ian Stewart’s Cabinet of Mathematical Curiosities and Hoard of Mathematical Treasures
Singing Hedgehog, on G+, recognises that Stewart can’t choose his own books for the list but would add Cabinet and Hoard, which he calls “fabulous repositories of interesting stuff”.
A book of mathematical oddities: games, puzzles, facts, numbers and delightful mathematical nibbles for the curious and adventurous mind.
A new trove of entrancing numbers and delightful mathematical nibbles for adventurous mind.
Clifford Pickover’s The Math Book
Suggested by Singing Hedgehog on G+.
Maths infinite mysteries and beauty unfold in this fascinating book. Beginning millions of years ago with ancient ‘ant odometers’ and moving through time to our modern-day quest for new dimensions, it covers 250 milestones in mathematical history.
Barry Mazur’s Imagining Numbers: (Particularly the Square Root of Minus Fifteen)
Suggested by Singing Hedgehog on G+.
The book shows how the art of mathematical imagining is not as mysterious as it seems. Drawing on a variety of artistic resources the author reveals how anyone can begin to visualize the enigmatic ‘imaginary numbers’ that first baffled mathematicians in the 16th century.
Florian Cajori’s A History of Mathematical Notations
Suggested by Singing Hedgehog on G+, who says this “covers the history of mathematics through the methods of writing it”.
Described even today as “unsurpassed,” this history of mathematical notation stretching back to the Babylonians and Egyptians is one of the most comprehensive written. In two impressive volumes–first published in 1928-9–distinguished mathematician Florian Cajori shows the origin, evolution, and dissemination of each symbol and the competition it faced in its rise to popularity or fall into obscurity.
Richard Elwes’ Maths 1001: Absolutely Everything That Matters in Mathematics
Susan Turnbull insists this mustn’t be forgotten over on G+.
Maths 1001 provides clear and concise explanations of the most fascinating and fundamental mathematical concepts. Distilled into 1001 bite-sized mini-essays arranged thematically, this unique reference book moves steadily from the basics through to the most advanced of ideas, making it the ideal guide for novices and mathematics enthusiasts.
William Poundstone’s The Recursive Universe: Cosmic Complexity and the Limits of Scientific Knowledge
Suggested by John Read on G+.
In The Recursive Universe, William Poundstone uses Conway’s Life as a vehicle to explore complexity theory and modern physics. Poundstone demonstrates how simple rules can produce complex results when applied recursively and suspects our own universe was created in a similar manner. (Description source)
Ivan Moscovich’s Super-games
Suggested by John Read on G+, but of which I cannot find a description.
Benoit Mandelbrot’s The Fractal Geometry of Nature
Suggested by John Read on G+.
“…a blend of erudition (fascinating and sometimes obscure historical minutiae abound), popularization (mathematical rigor is relegated to appendices) and exposition (the reader need have little knowledge of the fields involved) …and the illustrations include many superb examples of computer graphics that are works of art in their own right.” Nature
John Allen Paulos’ Innumeracy: Mathematical Illiteracy and Its Consequences
Suggested by John Read on G+.
Why do even well-educated people often understand so little about maths – or take a perverse pride in not being a ‘numbers person’?
In his now-classic book Innumeracy, John Allen Paulos answers questions such as: Why is following the stock market exactly like flipping a coin? How big is a trillion? How fast does human hair grow in mph? Can you calculate the chances that a party includes two people who have the same birthday? Paulos shows us that by arming yourself with some simple maths, you don’t have to let numbers get the better of you.
Martin Gardner’s Mathematical Puzzles and Diversions
Suggested by John Read on G+ who says this is “the first I bought and the one I go back to most” but I can’t find a cover blurb description of this.
Marcus Du Sautoy’s The Music of the Primes: Why an unsolved problem in mathematics matters
Suggested by John Read on G+.
In this breathtaking book, mathematician Marcus du Sautoy tells the story of the eccentric and brilliant men who have struggled to solve one of the biggest mysteries in science. It is a story of strange journeys, last-minute escapes from death and the unquenchable thirst for knowledge. Above all, it is a moving and awe-inspiring evocation of the mathematician’s world and the beauties and mysteries it contains.
Ian Stewart’s Game Set and Math: Enigmas and Conundrums
John Read on G+ says “I’d also pick an Ian Stewart – probably Game, Set and Math”. Again, I can’t find a description.
William Cook’s In Pursuit of the Traveling Salesman: Mathematics at the Limits of Computation
Mitch Keller on Twitter notes that only one book on Stewart’s list focuses on a specific problem and suggests this as another.
What is the shortest possible route for a traveling salesman seeking to visit each city on a list exactly once and return to his city of origin? It sounds simple enough, yet the traveling salesman problem is one of the most intensely studied puzzles in applied mathematics–and it has defied solution to this day. In this book, William Cook takes readers on a mathematical excursion, picking up the salesman’s trail in the 1800s when Irish mathematician W. R. Hamilton first defined the problem, and venturing to the furthest limits of today’s state-of-the-art attempts to solve it.
On G+ Alex Bellos recommended the following three for an accessible list for “people who know no maths”, saying “the challenge when writing a maths book is to find a strong narrative – and these three books do it better than any others”.
Simon Singh’s Fermat’s Last Theorem: The story of a riddle that confounded the world’s greatest minds for 358 years
Recommended by Alex Bellos on G+.
The extraordinary story of the solving of a puzzle that has confounded mathematicians since the 17th century… A remarkable story of human endeavour and intellectual brilliance over three centuries, Fermat’s Last Theorem will fascinate both specialist and general readers.
Apostolos Doxiadis and Christos Papadimitriou’s Logicomix: An Epic Search for Truth
Recommended by Alex Bellos on G+.
This brilliantly illustrated tale of reason, insanity, love and truth recounts the story of Bertrand Russell’s life… An insightful and complexly layered narrative, Logicomix reveals both Russell’s inner struggle and the quest for the foundations of logic. Narration by an older, wiser Russell, as well as asides from the author himself, make sense of the story’s heady and powerful ideas. At its heart, Logicomix is a story about the conflict between pure reason and the persistent flaws of reality, a narrative populated by great and august thinkers, young lovers, ghosts and insanity.
Apostolos Doxiadis’ Uncle Petros and Goldbach’s Conjecture
Recommended by Alex Bellos on G+.
Uncle Petros and Goldbach’s Conjecture is an inspiring novel of intellectual adventure, proud genius, the exhilaration of pure mathematics – and the rivalry and antagonism which torment those who pursue impossible goals.
For a list of “something fun for the math literate”, Alex recommended the following three.
Petr Beckmann’s A History of Pi
Recommended by Alex Bellos on G+.
The history of pi, says the author, though a small part of the history of mathematics, is nevertheless a mirror of the history of man. Petr Beckmann holds up this mirror, giving the background of the times when pi made progress — and also when it did not, because science was being stifled by militarism or religious fanaticism.
Tobias Dantzig’s Number: The Language of Numbers
Recommended by Alex Bellos on G+.
A new edition of the classic introduction to mathematics, first published in 1930 and revised in the 1950s, explains the history and tenets of mathematics, including the relationship of mathematics to the other sciences and profiles of the luminaries whose research expanded the human concept of number.
Paul Hoffman’s The Man Who Loved Only Numbers: The Story of Paul Erdös and the Search for Mathematical Truth
Recommended by Alex Bellos on G+.
The biography of a mathematical genius. Paul Erdos was the most prolific pure mathematician in history and, arguably, the strangest too.
For this group, Alex also recommends “the complete works of Martin Gardner”.
James Gleick’s Chaos and The Information
Recommended by Alex Bellos on G+. Alex says these are between the two lists as they are “both utterly brilliant but might lose the casual reader in parts”.
Chaos: This book brings together different work in the new field of physics called the chaos theory, an extension of classical mechanics, in which simple and complex causes are seen to interact. Mathematics may only be able to solve simple linear equations which experiment has pushed nature into obeying in a limited way, but now that computers can map the whole plane of solutions of non-linear equations a new vision of nature is revealed. The implications are staggeringly universal in all areas of scientific work and philosophical thought.
The Information: We live in the information age. But every era of history has had its own information revolution: the invention of writing, the composition of dictionaries, the creation of the charts that made navigation possible, the discovery of the electronic signal, the cracking of the genetic code.
In The Information James Gleick tells the story of how human beings use, transmit and keep what they know. From African talking drums to Wikipedia, from Morse code to the ‘bit’, it is a fascinating account of the modern age’s defining idea and a brilliant exploration of how information has revolutionised our lives.
E-Learning in Mathematical Subjects
In 2005 I was asked to attend a meeting at Nottingham Trent University with some fellow PhD students. I explained my topic, e-learning in university mathematics, to one student who said, “oh, you should go and talk to Mike in Physics; he’s interested in that sort of thing”. When I found him, it turned out Mike had a little interest in primary school teaching but he said “oh, you should go and talk to Dave downstairs; he’s interested in that sort of thing”.
Feeling like I was on a wild goose chase, I went downstairs and knocked on the relevant door. Dave turned out to be Dr. David Fairhurst, a physicist who had recently moved to Nottingham Trent University. Dave was indeed interested in university education and after a quick chat we agreed there are lots of subjects all trying to deliver mathematical content through electronic means who might benefit from getting together and a seminar series might be useful. I was keen on this; as a PhD student I was encouraged to attend departmental seminars but I hadn’t even managed to understand the titles of any so far.
We booked a room and sent an email around whoever we could think of as an invitation to a general discussion on setting up a seminar series. Thirty or so people turned up and someone suggest Trevor Pull could give the first talk. Over the next three-and-a-bit years we held a total of 25 meetings which were attended by teachers of mathematics from subjects such as mathematics, statistics, physics, chemistry, biosciences, environmental sciences, engineering, computing, social sciences, business and economics, as well as researchers from both computing and education and university learning technology developers. It was really pleasing to meet all these people and see how mathematics is taught in nearly every academic school in the university. We were joined in the organisation by Pete Bradshaw from the School of Education.
In 2006 we had a talk by Steve Maddox about his work supporting two blind physics students at the University of Nottingham. This was excellent and I felt a great sense of loss at having only made this available to the twenty or so people in the room who saw it live. Steve did write his talk up for MSOR Connections, but this only appeared a whole year later because these things take time. I applied for funding from the Institute of Mathematics and its Applications (I was a member but this is long before I worked for them) and received £600 towards speakers’ expenses and refreshments at meetings in exchange for recording the talks and making them available online. The Maths, Stats and OR Network (long before I worked for them too) were kind enough to host the large video files on their web server.
For the first two talks I borrowed video cameras from the computing department and recorded and edited these myself. I wrote an article in MSOR Connections about this experience: A quick and easy (rough and ready) method for online video. From 2007 onwards, much to my relief, these were recorded and edited professionally by Chris Shaw of Nottingham Trent University.
Many of the seminar videos cover teaching, learning, assessment and support using specific technologies – wikis, podcasting, Logo, interactive whiteboards, GeoGebra, VLEs and interactive voting systems – a series of talks related to accessibility, particularly access to mathematics by students with visual impairments, and several related to more general pedagogy such as designing effective online questions and relevance of learning styles to e-learning. In the end we recorded fourteen talks as videos. These have been available for a while on the ELMS website and have been downloaded quite a few times (by unique ip addresses: min 30; max 176; mean 51; SD 38; median 37). Now I have transferred the videos also to a YouTube playlist. The website has downloads relating to talks (such as slides) where these are available.
I wrote updates on the availability of new ELMS talks in Mathematics Today (43(3), p. 85; 43(5), p. 164); 45(1), p. 11) and MSOR Connections (7(2), pp. 49-50; 7(4), p. 43; 9(2), pp. 29-30), and a final grant report in Mathematics Today (46(6), pp. 287-288).
ELMS seminars stopped when I moved to full time employment and couldn’t get to Nottingham Trent very often to organise them. I’m really glad for this experience. I met a lot of interesting people doing these seminars and later ran workshops for the MSOR Network’s Accessing MSOR group, staff development seminars for the School of Mathematical Sciences at the University of Nottingham when I worked there and in my current job for the MSOR Network we run seminars and workshops. ELMS was the experience that demystified this process for me and that alone was incredibly useful.
Paula Swisheer
She literally got her art in my maths!
The sign on my office door
Recently, someone left my office at Newcastle University and a new person took their place, so we needed a new sign on our front door. I wanted to do something clever with it, but it needed to be instantly legible to lost supervisors trying to find their students.
My first thought was that since there are seven of us, something to do with the Fano plane would look good. Our names didn’t have enough of the right letters in the right places for it to work, though.
That got me thinking about the Levenshtein distance. The Levenshtein distance between two strings is a measure of how many changes you need to make to one to end up with the other.
Click here to continue reading The sign on my office door on cp’s mathem-o-blog
What is mathematics?
This morning on Twitter Tony Mann asked the question: “This morning’s class is “What is Mathematics?” Answers in a tweet please.” Answers were collected via the #MATH1103 hashtag.
Some of the answers were what you might expect: patterns, abstraction, order.
Stuart Ravn sent a series of tweets giving his views:
Math is everything you can do with the abilities to count and deduce. There’s literally no end to the fun you can have. No joke.
Math is the only thing which is truly universal; it underlies and makes it possible to understand and communicate with everything.
Everything, immediately or ultimately, is mathematical and arises from mathematics.
Ask yourself what isn’t mathematics, and try to prove yourself right.
Noam Chomsky said of love, “I can’t tell you what it is, but life’s empty without it.” The same is viscerally true of mathematics.
I don’t just have enthusiasm for maths. I love it. It’s the closest thing to my heart after my family. I’m emotional about it.
Noel-Ann Bradshaw noted that “What is mathematics?” is the name of “an excellent book by Courant & Robbins revised by Stewart“. I have the tenth printing from 1960. Although this has a lot to say on the subject, it opens a discussion of historical development with:
Mathematics as an expression of the human mind reflects the active will, the contemplative reason, and the desire for aesthetic perfection. Its basic elements are logic and intuition, analysis and construction, generality and individuality. Though different traditions may emphasise different aspects, it is only the interplay of these antithetic forces and the struggle for their synthesis that constitute the life, usefulness, and supreme value of mathematical science.
I was interested in a related question: When does mathematics become something else? At some point some topic is clearly applied maths and at some point it is physics, astronomy, engineering, economics, computer science, biology, and so on.
We struggle with this a little on the Math/Maths Podcast, where we try to report news from mathematics and its applications. On Twitter I said that I think I tend to stray a little further from that which is unambiguously mathematics than does Samuel Hansen. We both report applications but I think mine are often more tangential than Samuel’s. This was quite noticeable on episode 80 this week when Samuel picked me up on an astrophysics story I was defending as involving statistical models. He said:
This is ‘Math/Maths’, not ‘Stat/Stats’, and it’s definitely not ‘Astronomy/Astronomies’. I’m assuming you put ‘s’ at the end of every single science – you have ‘Chemistries’ and ‘Physicses’, right?
and later
Now you’ve turned us into ‘Geology/Geologies’.
Answering my question on Twitter, Samuel said: “if an application has been around long enough to have own name, Physics astronomy or thermodynamics. It’s not math“. I don’t fundamentally disagree with this and some disciplines, notably computer science, were born this way. However, Sharon Evans made a very practical (if teasing) counter-point: “so it’s only maths if it hasn’t got a name? You’re not leaving much to report on in [the podcast]“.
Clarissa Wornack replied to say “Well, when you start writing code; it’s IT/software eng/comp sci; if you create something that is a material object; it’s eng” and Charles Brain said “Applied maths becomes Engineering when it hits the real world and money becomes part of the equation!” I don’t particularly agree with these. I know people who use high end computing to do mathematics and just because they are using computing as a tool (and writing bespoke code) this doesn’t mean they are doing computer science research. I also don’t agree that it stops being applied maths when it creates a material object. Defining mathematics as that which doesn’t involve the real world or money seems very self-defeating.
Felipe Pait offered this definition: “Applied math interests mathematicians and non mathematicians. Otherwise it’s pure math, or pure engineering. Math stops being applied math and becomes pure physics when it doesn’t interest mathematicians. An operational definition.”
There’s something in this. When I think about “what is mathematics?” I am really thinking “what can mathematicians do?” I am particularly interested in what university mathematics graduates might become and would like this to be a broad as possible. I meet a lot of mathematics researchers working in different application areas. For example, back when I was doing the Travels in a Mathematical World podcast for the IMA I spoke to Paul Shepherd. I am much more naturally inclined to consider Paul a mathematician working in architecture than an architecture researcher who once did a maths degree. By extension, I am happy to include Paul’s use of geometry in architecture as part of mathematics than to exclude it.
Daniel Colquitt suggested “a lot depends on the user” and “in many cases, the distinction is arbitrary“. I think this may be the wisest view on the subject I have heard. From my point of view I am biased towards including topics on the edge within mathematics rather than excluding them, and maybe even collecting a little of the host subject along with them. I would rather cast the arbitrary net as wide as possible.