Author: fbenedictus

  • Irrational Happiness

    When I started writing this blogpost a week ago, I wrote this: “When times are as difficult and unpredictable as they are today, I find comfort in mathematics. No matter how things turn out, how many more difficulties come our way, we may be certain that mathematics stays the way it is* – it is our indestructable beacon of rationality. In this blogpost I want to share with you some of the comfort that mathematics gives to me.”

    But the longer I think about these things, the more I realise that it is not this comfort that I want to share. I realise that when I am at home alone, sitting in my ‘internest’, writing this blog, I forget about all the trouble around me. I stop worrying about the coronavirus or about my recent divorce. Mathematics makes me happy, that’s what I want to share!


    Pythagoras (c. 570 – c. 495 BC)

    Just like me, the followers of Pythagoras in the sixth century BC really loved their numbers. When one of them discovered that there are numbers, like √2, which you can’t write out in all their decimals, because they have infinitely many of them (√2=1.41421356237…), the other Pythagoreans threw the poor fellow into the sea. But his death hasn’t helped. Numbers with infinitely many decimals exist, and √2 is one of them.

    To prove that √2 has infinitely many decimals, we must show that it can’t be written as the division of two whole numbers – that √2 is an irrational number (so-called because it is not the ratio between two whole numbers).

    If mathematical proof isn’t your favourite pass-time (not even in quarantine) then perhaps you should skip to the paragraph ‘Hamlet’s nutshell’.

    Talk contradictory to me baby!

    The proof that √2 is an irrational number is a proof by contradiction. We assume that the opposite of what we want to prove, the statement “√2 is the ratio between two whole numbers”, is true, and from that we derive a contradiction, so that we know that the assumption that we started with is false.

    So we start with the assumption that √2 is the ratio between two whole numbers. Let’s begin by writing the ratio in terms of its smallest divisors, the lowest values of m and n for which the ratio stays the same (so that 3/6 becomes 1/2, 5/15 becomes 1/3 and 2/1200 becomes 1/600). Let’s call these smallest divisors m and n. To derive the contradiction that we need for our proof, we will show that the m and the n that go into √2 are even numbers, which means that $\frac{m}{n}$ is not the ratio between two smallest divisors (because both terms in the ratio can be divided by two). But the assumption that we started with is that m and n are the smallest divisors, so if our reasoning is correct, our starting assumption must be wrong.

    Let’s begin with this:

    $\sqrt{2}=\frac{m}{n}$

    square both sides to get

    $2 = \left( \frac{m}{n} \right)^2 = \frac{m^2}{n^2}$

    then multiply both sides by $n^2$ to get

    $2n^2=m^2$

    If m and n are arbitrary whole numbers, then so are $m^2$ and $n^2$. So if $n^2$ is equal to some arbitrary whole number multiplied by two, $m^2$ must be an even number (because any number multiplied by 2 is an even number). Ok, so we know that $m^2$ is even, but what about m? Is m also even, if $m^2$ is even? m appears in our equation in its squared form, but whatever the value of $m^2$, there are only two possibilities: m is either even or odd (mathematicians like stating the obvious). But how does that help us? How can we explore these two possibilities?

    We’re going to use a little trick here: we know that a number is an even number if it can be divided by 2, so if m is an even number, we may write $m=2k$, where k is again some arbitrary number. Think about it. If some arbitrary number is one of these “1, 2, 3, 4, 5…” then two times that number is in the list “2, 4, 6, 8…”. This gives us a list of even numbers, but how do we get to the odd numbers? The second part of our trick is to add 1 to every number in the list of even numbers, so that we get a list with odd numbers (“3, 5, 7, 9…”), so we know that we can write any odd number as $2k+1$. Try it yourself, fill in “1, 2, 3, 4, 5…” for k in $2k+1$ and you get “3, 5, 7, 9…”.

    Back to our two possibilities. We know that $m^2$ is even, but what about m? Is m even or odd? Where do these possibilities lead us?

    Possibilities

    Case 1) If m is even, we know that $m=2k$ for an arbitrary k, so that $m^2= \left( 2k \right)^2=4k^2$, which is again an even number because it is divisible by two. We now know that $\sqrt{2}=\frac{m}{n}$ is consistent with $m^2$ and m being both even.

    Case 2) If m is odd, then we may write $m=2k+1$ for some arbitrary number k, so that $m^2= \left( 2k + 1 \right) \left( 2k+1 \right) = 4k^2 + 4k+1$. This expression has the form “even number + 1”, because $4k^2 + 4k$ is even, so $4k^2 + 4k+1$ must be odd. We see that the second possibility leads to saying “if m is odd, then $m^2$ is also odd.”

    Before we started talking about the two possibilities, we asked “what can we say about m if we know that $m^2$ is even?” We see that assuming that m is odd leads to an $m^2$ which is odd, so possibility 2 is not a possibility at all! The only remaining option is possibility 1: if $m^2$ is even, then m is also even.

    Are we there yet? We started this blogpost by saying that it is impossible that $\sqrt{2}=\frac{m}{n}$ if m and n are smallest divisors because $\sqrt{2}=\frac{m}{n}$ implies that m and n are even, but we haven’t shown that yet. We know that from $m^2 = 2n^2$ it follows that both m and $m^2$ are even, but what about n? Let’s use our ‘little trick’ again. Since we know that m is an even number, we may write $m = 2k$. We also know that $m^2=2n^2$, which gives us $4k^2=2n^2$. Divide both sides by 2, and we see that $2k^2=n^2$, which tells us that $n^2$ is an even number. We know from our earlier reasoning that if the square of an arbitrary number is even, then so is the number itself (if $m^2$ is even then m is even). We just showed that $n^2$ is even, so n itself must also be even.

    Phiew! We have finally reached the contradiction. Both m and n are even, so they are not the smallest divisors in $\sqrt{2}=\frac{m}{n}$. This contradicts our starting assumption, so that assumption must be false, so √2 is not a rational number.

    Q.E.D.**

    Something keeps nagging, though. We have shown that both m and n are even, which tells us that m and n are not the smallest divisors in $\sqrt{2}=\frac{m}{n}$, but what does that tell us? We assumed that they were smallest divisors, and that’s why there was a contradiction. What if we don’t make this assumption? What if we assume that there are numbers m and n such that $\sqrt{2}=\frac{m}{n}$, for some m and n that are not the smallest divisors in $\frac{m}{n}$?

    What we should realise is that both m and n could be any number, so if we say $\sqrt{2}=\frac{m}{n}$, then this equation must hold for all choices of m and n, including the choice where m and n are smallest divisors. m and n being the smallest divisors is not an extra assumption – it is part of the assumption that m and n are arbitrary numbers.

    Can’t we make a claim about √2 that is a bit weaker? What if we say that m and n are numbers for which $\sqrt{2}=\frac{m}{n}$ does not have smallest divisors? Will that allow us to say that √2 is a ratio between whole numbers?

    Nice try, but it won’t work. Or rather, it works, but then the m and n that go into √2 are not numbers as we know them. Take any pair of positive, whole numbers, and make a rational number out of them $\left(\frac{m}{n}\right)$. Depending on the choice you make, it is either possible to divide both n and m by some other number (so that, for example, $\frac{3}{6}$ becomes $\frac{1}{2}$, and $\frac{4}{16}$ becomes $\frac{1}{4}$) or you can’t do that, in which case you have the smallest divisors ($\frac{1}{2}$, $\frac{5}{8}$, $\frac{6}{7}$). The possibility left for m and n that neither have nor are smallest divisors of √2, is to choose for m and n some trans-finite numbers, such as $\aleph_0$, which represents, among other things, the cardinality of the set of all integers. But the moment we start talking about trans-finite numbers, we leave the realm of the real and the rational numbers. The ratio which trans-finite numbers can give us is not a rational number.

    Hamlet’s nutshell

    It makes me a bit dizzy when I start thinking about trans-finite numbers (if you’ve skipped the proof, just believe me when I say that trans-finite numbers are stranger than fiction). Math-induced dizziness is a pleasant dizziness, much as that due to a glass of whisky. It reminds me of something that Shakespeare’s Hamlet says:

    “I could be bounded in a nutshell, and count myself a king of infinite space”

    No matter what happens, no matter what comes our way or how isolated I become, in my mind I can instantly travel to the farthest reaches of human understanding. Simply by following the rules of logic.


    *) which is not to say that it’s impossible that mathematicians discover new theorems or new mathematical relations. What I mean is that mathematics, as logical reasoning about numbers, will continue, no matter what.

    **) Nerd-speak for ‘I told you so’. Also sometimes “quod erat demonstrandum” (Latin for ‘…which needed to be proved’)

  • Back in Utrecht

    My wife has decided that she wants to split up with me, so I have moved back to my old home in Utrecht (the Netherlands). I am very sad, because I really saw a future for us together in Sweden, and writing this actually brings tears to my eyes. When I am as sad as I am now, I often try to think of Monty Python’s song ‘Always look on the bright side of life’. But this time that thought provides little comfort, because ‘Always look on the bright side of life’ is the song that was played during our marriage ceremony, so the song reminds me of her smiling and singing.

    Having said that, I think there is a lot of brightness awaiting me. I have started teaching a course on electromagnetism at a university in Amsterdam, I’m writing a popular book on relativity theory which will appear in May (with a foreword written by Nobel prizewinner Gerard ‘t Hooft), and the Dutch climbing & mountaineering federation has made me Dutch paraclimbing ambassador!

    And what about Sweden? I’m not letting go of my mission to spread paraclimbing in Scandinavia. In October I have given a talk about paraclimbing in Norway, and at the end of April there will be a sports camp in Sweden, where a wide variety of parasports (adaptive sports) are represented. I have been invited by the Swedish climbing federation to come and represent paraclimbing. You haven’t heard the last of me yet!

     

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    Dutch open nationals, Sittard; November 2019

  • Changes!

    I have great news! No, I’m not pregnant, I’m moving to Sweden. My wife accepted a job as a teacher at an international school in Älmhult (near Malmö), so from August 1 I’ll be driving my tricycle in Viking-country.

    One remark before I tell you more about my plans for Sweden: this will be my last blogpost on paraklimmer.wordpress.com; from now on I’ll only post on my English paraclimbing website so follow this link, and click ‘Follow Blog via Email’ to keep getting updates!

     

    What am I going to do in Sweden? I’m going to continue my job as an editor for a journal in physics (Foundations of Physics) and I’ll continue to do research in the philosophy of physics at the Linnaeus University in Växjö.

    And what about the climbing? Will that come to an end?

    Of course not! I’m going to start a new chapter of my mission – to spread the word about paraclimbing. When I started paraclimbing in the Netherlands three years ago, there was only one other paraclimber, now there’s eight of us (see image below). At the moment there are only two paraclimbers in Sweden, that will change!

     

    But before I move to Sweden, there are two things that I have to take care of:

    1. I’m organising an international conference in honour of the Nobel laureate Gerard ‘t Hooft, to be held at the university of Utrecht July 11-13 (hey, that’s Thursday!)
    2. The morning after the conference dinner on Saturday I’m traveling to Briançon (Fra) to compete in the Worldchampionship paraclimbing!
  • WK 2019: Briançon, 16/17 juli

    De organisatie van het WK paraklimmen 2019 heeft bekend gemaakt dat het WK dit jaar toch niet in Tokio zal zijn. Het wordt gehouden in Briançon (Fr), en niet in augustus, maar op 16/17 juli. Ik vind dat jammer en vervelend: jammer omdat ze in Tokio waarschijnlijk maar weinig blonde Friezen te zien krijgen; en vervelend omdat mijn trainingsplanning nu in de soep loopt.

    Maar wat dit alles volgens mij nog het duidelijkst laat zien is dat paraklimmen nog niet ‘één van de grote jongens’ is: ik kan me moeilijk voorstellen dat het WK voetbal zo kort van tevoren een maandje en 1000 km wordt verplaatst. Het is dus wel duidelijk dat mijn missie – ervoor zorgen dat paraklimmen serieuzer, groter en bekender wordt – nog in de kinderschoenen staat.

    Op dat front is trouwens ook succes geboekt. Toen ik in 2015/16 begon met paraklimmen, bestond het Nederlandse paraklimteam uit twee personen. Inmiddels zijn we met veel meer (we hebben zelfs alweer een nieuw teamlid dat niet op de foto staat; binnenkort meer daarover):

    Heb je zelf een handicap en zou je graag een keertje mee willen trainen, of ken je iemand die daar misschien in geïnteresseerd zou zijn? Schrijf je hier in voor de open training op 8 mei bij Mountain Network Nieuwegein.

     

    Voor wie niet iedere dag RTV Utrecht kijkt: ze hebben een reportage over me gemaakt (klik hier)!

  • The Order of Rovelli’s Time – does time exist?

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  • WK Innsbruck 2018 – Resultaat

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    Ik ben helaas tijdens het klimmen van de tweede route gediskwalificeerd omdat ik op een metalen bout ging staan (zie foto; kijk goed onder de rechter voet).

    Door mijn slechte zicht en kleurenblindheid had ik de bout aangezien voor de rode greep die er bij in de buurt zit.

    Dat was jammer, want tot daar aan toe ging de route best goed.

    Ik ben daardoor geëindigd op positie nummer tien van de veertien.

    Zoals we in Friesland zeggen: koe minder!

    (kon slechter)

  • WK Paraklimmen, Innsbruck 2018

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    Het NL Paraklimteam (Renske Nugter, Mees Vooijs, onze coach Berber Brouns en ikzelf) is zondag in alle vroegte afgereisd naar het Oostenrijkse Innsbruck, in het bergachtige Tirol.

    In Tirol doen we mee aan het Wereldkampioenschap paraklimmen.

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    Op de foto hiernaast is de wand te zien waarop de routes zijn uitgezet die we morgen (dinsdag) moeten klimmen.

    Renske en ik moeten morgen de rode route klimmen, en Mees op woensdag. De wand is behoorlijk overhangend (zo’n 35 graden), dus het zal een behoorlijke uitdaging worden!

    Als deze twee kwalificatieroutes goed genoeg gaan, hebben we een plaats in de finale, die op donderdag is.