Archive for the 'Occasional' Category

The Online Encyclopedia of Integer Sequences

Published June 25, 2020 Occasional Leave a Comment
Tags: , ,

Suppose that, in the course of an investigation, you stumble upon a string of whole numbers. You are convinced that there must be a pattern, but you cannot find it. All you have to do is to type the string into a database called OEIS — or simply “Slone’s” — and, if the string is recognized, an entire infinite sequence is revealed. If the string belongs to several sequences, several choices are offered. OEIS is a great boon to both professional mathematicians and applied scientists in fields like physics, chemistry, astronomy and biology.

OEIS-Homepage

The Home page of OEIS: https://oeis.org

Continue reading ‘The Online Encyclopedia of Integer Sequences’

Dimension Reduction by PCA

Published June 11, 2020 Occasional Leave a Comment
Tags: ,

We live in the age of “big data”. Voluminous data collections are mined for information using mathematical techniques. Problems in high dimensions are hard to solve — this is called “the curse of dimensionality”. Dimension reduction is essential in big data science. Many sophisticated techniques have been developed to reduce dimensions and reveal the information buried in mountains of data.

Correlated-Variables

Continue reading ‘Dimension Reduction by PCA’

The Monte-Carlo Method

Published May 28, 2020 Occasional Leave a Comment
Tags: ,

Learning calculus at school, we soon find out that while differentiation is relatively easy, at least for simple functions, integration is hard. So hard indeed that, in many cases, it is impossible to find a nice function that is the integral (or anti-derivative) of a given one. Thus, given {f(x)} we can usually find {d f /d x}, whereas we may not be able to find {\int f(x)\,d x}.

Monte-Carlo-Wide-4panel

Continue reading ‘The Monte-Carlo Method’

A New Perspective on Perspective

Published May 14, 2020 Occasional Leave a Comment
Tags:

The development of perspective in the early Italian Renaissance opened the doors of perception just a little wider. Perspective techniques enabled artists to create strikingly realistic images. Among the most notable were Piero della Francesca and Leon Battista Alberti, who invented the method of perspective drawing.

School-of-Athens-MidRes

School of Athens, a fresco painted by Raphael in 1509-11 illustrates the power of perspective.

Continue reading ‘A New Perspective on Perspective’

Order in the midst of Chaos

Published April 30, 2020 Occasional Leave a Comment
Tags: ,

We open with a simple mathematical puzzle that is easily solved using only elementary reasoning. Imagine a party where some guests are friends while others are unacquainted. Then the following is always true:

No matter how many guests there are at the party, there are
always two guests with the same number of friends present.

If you wish, try proving this before reading on. The proof is outlined at the end of this post.

Complete-Graphs-6-10

Complete graphs with 6 to 10 vertices.

Continue reading ‘Order in the midst of Chaos’

John Horton Conway: a Charismatic Genius

Published April 23, 2020 Occasional Leave a Comment
Tags: , , , ,

J-H-Conway-2009-Denise-Applewhite-Princeton-Univ

John H Conway in 2009
[image Denise Applewhite, Princeton University].

John Horton Conway was a charismatic character, something of a performer, always entertaining his fellow-mathematicians with clever magic tricks, memory feats and brilliant mathematics. A Liverpudlian, interested from early childhood in mathematics, he studied at Gonville & Caius College in Cambridge, earning a BA in 1959. He obtained his PhD five years later, after which he was appointed Lecturer in Pure Mathematics.

 

In 1986, Conway moved to Princeton University, where he was Professor of Mathematics and John Von Neumann Professor in Applied and Computational Mathematics. He was awarded numerous honours during his career. Conway enjoyed emeritus status from 2013 until his death just two weeks ago on 11 April.

Continue reading ‘John Horton Conway: a Charismatic Genius’

The Ross-Littlewood Paradox

Published April 9, 2020 Occasional Leave a Comment
Tags:

Ross-Littlewood-01

Ross-Littlewood Paradox [Image from Steemit website:  here. ]

A most perplexing paradox appeared in Littlewood’s book A Mathematician’s Miscellany. It was later analysed in detail by Sheldon Ross in his 1988 book A First Course in Probability.

Continue reading ‘The Ross-Littlewood Paradox’

Bang! Bang! Bang! Explosively Large Numbers

Published March 26, 2020 Occasional Leave a Comment
Tags: ,

Bang-1224578

Typical Comic-book `bang’ mark [Image from vectorstock ].

Enormous numbers pop up in both mathematics and physics. The order of the monster group, the largest of the 26 sporadic groups, is

\displaystyle 808,017,424,794,512,875,886,459,904,961,710,757,005,754,368,000,000,000

which is approximately {8\times 10^{53}}. The number of atoms in the universe is estimated to be about {10^{80}}. When we consider permutations of large sets, even more breadth-taking numbers emerge.

Continue reading ‘Bang! Bang! Bang! Explosively Large Numbers’

Samuel Haughton and the Twelve Faithless Hangmaids

Published March 12, 2020 Occasional Leave a Comment
Tags:

In his study of humane methods of hanging, Samuel Haughton (1866) considered the earliest recorded account of execution by hanging (see Haughton’s Drop on this site). In the twenty-second book of the Odyssey, Homer described how the twelve faithless handmaids of Penelope “lay by night enfolded in the arms of the suitors” who were vying for Penelope’s hand in marriage. Her son Telemachus, with the help of his comrades, hanged all twelve handmaids on a single rope.

Hangmaids-05-COL

Continue reading ‘Samuel Haughton and the Twelve Faithless Hangmaids’

Zhukovsky’s Airfoil

Published February 27, 2020 Occasional Leave a Comment
Tags: ,

A simple transformation with remarkable properties was used by Nikolai Zhukovsky around 1910 to study the flow around aircraft wings. It is defined by

\displaystyle \omega = \textstyle{\frac{1}{2}}\displaystyle{\left(z +\frac{1}{z}\right)}

and is usually called the Joukowsky Map. We begin with a discussion of the theory of fluid flow in two dimensions. Readers familiar with 2D potential flow may skip to the section Joukowsky Airfoil.

Zhukovsky-Animation

Visualization of airflow around a Joukowsky airfoil. Image generated using code on this website.

Continue reading ‘Zhukovsky’s Airfoil’

A Ring of Water Shows the Earth’s Spin

Published February 13, 2020 Occasional Leave a Comment
Tags: ,

Around 1913, while still an undergraduate, American physicist Arthur Compton described an experiment to demonstrate the rotation of the Earth using a simple laboratory apparatus.

Comptons-Generator-SciAm2

Continue reading ‘A Ring of Water Shows the Earth’s Spin’

The Rambling Roots of Wilkinson’s Polynomial

Published January 30, 2020 Occasional Leave a Comment
Tags: ,

Finding the roots of polynomials has occupied mathematicians for many centuries. For equations up to fourth order, there are algebraic expressions for the roots. For higher order equations, many excellent numerical methods are available, but the results are not always reliable.

Wilkinson-Polynomial

A 10th-order polynomial (blue) and a slightly perturbed version, with the coefficient of {x^9} changed by one part in a million.

Continue reading ‘The Rambling Roots of Wilkinson’s Polynomial’

Adjoints of Vector Operators

Published January 23, 2020 Occasional Leave a Comment
Tags: ,

We take a fresh look at the vector differential operators grad, div and curl. There are many vector identities relating these. In particular, there are two combinations that always yield zero results:

\displaystyle \begin{array}{rcl} \mathbf{curl}\ \mathbf{grad}\ \chi &\equiv& 0\,, \quad \mbox{for all scalar functions\ }\chi \\ \mathrm{div}\ \mathbf{curl}\ \boldsymbol{\psi} &\equiv& 0\,, \quad \mbox{for all vector functions\ }\boldsymbol{\psi} \end{array}

Question: Is there a connection between these identities?

CurlGradAndDivCurl

Continue reading ‘Adjoints of Vector Operators’

Grad, Div and Curl on Weather Maps: a Gateway to Vector Analysis

Published January 9, 2020 Occasional Leave a Comment
Tags: ,

Vector analysis can be daunting for students. The theory can appear abstract, and operators like Grad, Div and Curl seem to be introduced without any obvious motivation. Concrete examples can make things easier to understand. Weather maps, easily obtained on the web, provide real-life applications of vector operators.

GradDivCurl-MSLP

Fig. 1. An idealized scalar field representing the mean sea-level atmospheric pressure over the North Atlantic area.

Continue reading ‘Grad, Div and Curl on Weather Maps: a Gateway to Vector Analysis’

Divergent Series Yield Valuable Results

Published December 26, 2019 Occasional Leave a Comment
Tags:

Mathematicians have traditionally dealt with convergent series and shunned divergent ones. But, long ago, astronomers found that divergent expansions yield valuable results. If these so-called asymptotic expansions are truncated, the error is bounded by the first term omitted. Thus, by stopping just before the smallest term, excellent approximations may be obtained.

Continue reading ‘Divergent Series Yield Valuable Results’

The Intermediate Axis Theorem

Published December 12, 2019 Occasional Leave a Comment
Tags:

In 1985, cosmonaut Vladimir Dzhanibekov commanded a mission to repair the space station Salyut-7. During the operation, he flicked a wing-nut to remove it. As it left the end of the bolt, the nut continued to spin in space, but every few seconds, it turned over through {180^\circ}. Although the angular momentum did not change, the rotation axis moved in the body frame. The nut continued to flip back and forth, although there were no forces or torques acting on it.

Dzhanibekov-00

Flipping nut [image from Veritasium].

Continue reading ‘The Intermediate Axis Theorem’

Archimedes and the Volume of a Sphere

Published November 28, 2019 Occasional Comment
Tags: ,

One of the most remarkable and important mathematical results obtained by Archimedes was the determination of the volume of a sphere. Archimedes used a technique of sub-dividing the volume into slices of known cross-sectional area and adding up, or integrating, the volumes of the slices. This was essentially an application of a technique that was — close to two thousand years later — formulated as integral calculus.

SphConCyl-5

Cone, sphere and cylinder on the same base. The volumes are in the ratios  1 : 2 : 3 [image from mathigon.org].

Continue reading ‘Archimedes and the Volume of a Sphere’

Elliptic Trigonometry: Fun with “sun”, “cun” and “dun”

Published November 14, 2019 Occasional Leave a Comment
Tags: ,

Introduction

The circular functions arise from ratios of lengths in a circle. In a similar manner, the elliptic functions can be defined by means of ratios of lengths in an ellipse. Many of the key properties of the elliptic functions follow from simple geometric properties of the ellipse.

Originally, Carl Gustav Jacobi defined the elliptic functions {\mathop\mathrm{sn} u}, {\mathop\mathrm{cn} u}, {\mathop\mathrm{dn} u} using the integral

\displaystyle u = \int_0^{\phi} \frac{\mathrm{d}\phi}{\sqrt{1-k^2\sin^2\phi}} \,.

He called {\phi} the amplitude and wrote {\phi = \mathop\mathrm{am} u}. It can be difficult to understand what motivated his definitions. We will define the elliptic functions {\mathop\mathrm{sn} u}, {\mathop\mathrm{cn} u}, {\mathop\mathrm{dn} u} in a more intuitive way, as simple ratios associated with an ellipse.

Continue reading ‘Elliptic Trigonometry: Fun with “sun”, “cun” and “dun”’

An Attractive Spinning Toy: the Phi-TOP

Published October 31, 2019 Occasional Leave a Comment
Tags:

It is fascinating to watch a top spinning. It seems to defy gravity: while it would topple over if not spinning, it remains in a vertical position as long as it is spinning rapidly.

There are many variations on the simple top. The gyroscope has played a vital role in navigation and in guidance and control systems. Many similar rotating toys have been devised. These include rattlebacks, tippe-tops and the Euler disk. The figure below shows four examples.

Spinning-Tops-4

(a) Simple top, (b) Rising egg, (c) Tippe-top, (d) Euler disk. [Image from website of Rod Cross.]

Continue reading ‘An Attractive Spinning Toy: the Phi-TOP’

Some Fundamental Theorems of Maths

Published October 24, 2019 Occasional Leave a Comment
Tags: , ,

Every branch of mathematics has key results that are so
important that they are dubbed fundamental theorems.

The customary view of mathematical research is that of establishing the truth of propositions or theorems by rigorous deduction from axioms and definitions. Mathematics is founded upon axioms, basic assumptions that are taken as true. Logical reasoning is then used to deduce the consequences of those axioms with each major result designated as a theorem.

As each new theorem is proved, it provides a basis for the establishment of further results. The most important and fruitful theorem in each area of maths is often named as the fundamental theorem of that area. Thus, we have the fundamental theorems of arithmetic, algebra and so on. For example, the fundamental theorem of calculus gives the relationship between differential calculus and integral calculus.

Continue reading ‘Some Fundamental Theorems of Maths’

The Wonders of Complex Analysis

Published October 10, 2019 Occasional Leave a Comment
Tags:

AugustinLouis-Cauchy

Augustin-Louis Cauchy (1789–1857)

If you love mathematics and have never studied complex function theory, then you are missing something wonderful. It is one of the most beautiful branches of maths, with many amazing results. Don’t be put off by the name: complex does not mean complicated. With elementary calculus and a basic knowledge of imaginary numbers, a whole world of wonder is within your grasp.

In the early nineteenth century, Augustin-Louis Cauchy (1789–1857) constructed the foundations of what became a major new branch of mathematics, the theory of functions of a complex variable.

Continue reading ‘The Wonders of Complex Analysis’

Zeroing in on Zeros

Published September 26, 2019 Occasional Leave a Comment
Tags: ,

Given a function {f(x)} of a real variable, we often have to find the values of {x} for which the function is zero. A simple iterative method was devised by Isaac Newton and refined by Joseph Raphson. It is known either as Newton’s method or as the Newton-Raphson method. It usually produces highly accurate approximations to the roots of the equation {f(x) = 0}.

Newton-Raphson-00

A rational function with five real zeros and a pole at x = 1.

Continue reading ‘Zeroing in on Zeros’

Spiralling Primes

Published September 12, 2019 Occasional Leave a Comment
Tags: ,

SacksSpiral100k

The Sacks Spiral.

The prime numbers have presented mathematicians with some of their most challenging problems. They continue to play a central role in number theory, and many key questions remain unsolved.

Order and Chaos

The primes have many intriguing properties. In his article “The first 50 million prime numbers”, Don Zagier noted two contradictory characteristics of the distribution of prime numbers. The first is the erratic and seemingly chaotic way in which the primes “grow like weeds among the natural numbers”. The second is that, when they are viewed in the large, they exhibit “stunning regularity”.

Continue reading ‘Spiralling Primes’

ToplDice is Markovian

Published August 29, 2019 Occasional Leave a Comment
Tags: , ,

Many problems in probability are solved by assuming independence of separate experiments. When we toss a coin, it is assumed that the outcome does not depend on the results of previous tosses. Similarly, each cast of a die is assumed to be independent of previous casts.

However, this assumption is frequently invalid. Draw a card from a shuffled deck and reveal it. Then place it on the bottom and draw another card. The odds have changed: if the first card was an ace, the chances that the second is also an ace have diminished.

Continue reading ‘ToplDice is Markovian’

The curious behaviour of the Wilberforce Spring.

Published August 22, 2019 Occasional Leave a Comment
Tags: ,

The Wilberforce Spring (often called the Wilberforce pendulum) is a simple mechanical device that illustrates the conversion of energy between two forms. It comprises a weight attached to a spring that is free to stretch up and down and to twist about its axis.

Wilberforce-Spring

Wilberforce spring [image from Wikipedia Commons].}

In equilibrium, the spring hangs down with the pull of gravity balanced by the elastic restoring force. When the weight is pulled down and released, it immediately oscillates up and down.

However, due to a mechanical coupling between the stretching and torsion, there is a link between stretching and twisting motions, and the energy is gradually converted from vertical oscillations to axial motion about the vertical. This motion is, in turn, converted back to vertical oscillations, and the cycle continues indefinitely, in the absence of damping.

The conversion is dependent upon a resonance condition being satisfied: the frequencies of the stretching and twisting modes must be very close in value. This is usually achieved by having small adjustable weights mounted on the pendulum.

There are several videos of a Wilberforce springs in action on YouTube. For example, see here.

Continue reading ‘The curious behaviour of the Wilberforce Spring.’

Billiards & Ballyards

Published July 25, 2019 Occasional Leave a Comment
Tags:

In (mathematical) billiards, the ball travels in a straight line between impacts with the boundary, when it changes suddenly and discontinuously We can approximate the hard-edged, flat-bedded billiard by a smooth sloping surface, that we call a “ballyard”. Then the continuous dynamics of the ballyard approach the motions on a billiard.

SAMSUNG

Elliptical tray in the form of a Ballyard.

Continue reading ‘Billiards & Ballyards’

Boxes and Loops

Published July 11, 2019 Occasional Leave a Comment
Tags: ,

We will describe some generic behaviour patterns of dynamical systems. In many systems, the orbits exhibit characteristic patterns called boxes and loops. We first describe orbits for a simple pendulum, and then look at some systems in higher dimensions.

SimplePendulum-PhasePortrait-Colour

Phase portrait for a simple pendulum. Each line represents a different orbit.

Continue reading ‘Boxes and Loops’

Cumbersome Calculations in Ancient Rome

Published June 27, 2019 Occasional Comment
Tags: ,

Arithmetica-WoodcutTypus Arithmeticae” is a woodcut from the book Margarita Philosophica by Gregor Reisch of Freiburg, published in 1503. In the centre of the figure stands Arithmetica, the muse of mathematics. She is watching a competition between the Roman mathematician Boethius and the great Pythagoras. Boethius is crunching out a calculation using Hindu-Arabic numerals, while Pythagoras uses a counting board or abacus (tabula) and – presumably – a less convenient number system. Arithmetica is looking with favour towards Boethius. He smiles smugly while Pythagoras is looking decidedly glum.

The figure aims to show the superiority of the Hindu-Arabic number system over the older Greek and Roman number systems. Of course, it is completely anachronistic: Pythagoras flourished around 500 BC and Boethius around AD 500, while the Hindu-Arabic numbers did not arrive in Europe until after AD 1200.

Continue reading ‘Cumbersome Calculations in Ancient Rome’

Bernard Bolzano, a Voice Crying in the Wilderness

Published June 13, 2019 Occasional Leave a Comment
Tags: ,

Bernard-Bolzano

Bernard Bolzano (1781-1848)

Bernard Bolzano, born in Prague in 1781, was a Bohemian mathematician with Italian origins. Bolzano made several profound advances in mathematics that were not well publicized. As a result, his mathematical work was overlooked, often for many decades after his death. For example, his construction of a function that is continuous on an interval but nowhere differentiable, did not become known. Thus, the credit still goes to Karl Weierstrass, who found such a function about 30 years later. Boyer and Merzbach described Bolzano as “a voice crying in the wilderness,” since so many of his results had to be rediscovered by other workers.

Continue reading ‘Bernard Bolzano, a Voice Crying in the Wilderness’

Symplectic Geometry

Published May 30, 2019 Occasional Comment
Tags: , ,

Albert-EinsteinFor many decades, a search has been under way to find a theory of everything, that accounts for all the fundamental physical forces, including gravity. The dictum “physics is geometry” is a guiding principle of modern theoretical physics. Einstein’s General Theory of Relativity, which emerged just one hundred years ago, is a crowning example of this synergy. He showed how matter distorts the geometry of space and this geometry determines the motion of matter. The central idea is encapsulated in an epigram of John A Wheeler:

\displaystyle \mbox{Matter tells space how to curve. Space tells matter how to move.}

Continue reading ‘Symplectic Geometry’

Chase and Escape: Pursuit Problems

Published May 23, 2019 Occasional Leave a Comment
Tags:

Jolly-RogerFrom cheetahs chasing gazelles, through coastguards saving shipwrecked sailors, to missiles launched at enemy aircraft, strategies of pursuit and evasion play a role in many areas of life (and death). From pre-historic times we have been solving such pursuit problems. The survival of our early ancestors depended on their ability to acquire food. This involved chasing and killing animals, and success depended on an understanding of relative speeds and optimal pursuit paths.

Continue reading ‘Chase and Escape: Pursuit Problems’

Bouncing Billiard Balls Produce Pi

Published May 9, 2019 Occasional Leave a Comment
Tags: , ,

There are many ways of evaluating {\pi}, the ratio of the circumference of a circle to its diameter. We review several historical methods and describe a recently-discovered and completely original and ingenious method.

Archimedes-Polygons

Continue reading ‘Bouncing Billiard Balls Produce Pi’

K3 implies the Inverse Square Law.

Published April 25, 2019 Occasional Leave a Comment
Tags: ,

Kepler-DDR-Stamp-1971

Johannes Kepler. Stamp issued by the German Democratic Republic in 1971, the 400th anniversary of Kepler’s birth.

Kepler formulated three remarkable laws of planetary motion. He deduced them directly from observations of the planets, most particularly of the motion of Mars. The first two laws appeared in 1609 in Kepler’s Astronomia Nova. The first law (K1) describes the orbit of a planet as an ellipse with the Sun at one focus. The second law (K2) states that the radial line from Sun to planet sweeps out equal areas in equal times; we now describe this in terms of conservation of angular momentum.

The third law (K3), which appeared in 1619 in Kepler’s Harmonices Mundi, is of a different character. It does not relate to a single planet, but connects the motions of different planets. It states that the squares of the orbital periods vary in proportion to the cubes of the semi-major axes. For circular orbits, the period squared is proportional to the radius cubed.

Continue reading ‘K3 implies the Inverse Square Law.’

Massive Collaboration in Maths: the Polymath Project

Published April 11, 2019 Occasional Leave a Comment
Tags:

Sometimes proofs of long-outstanding problems emerge without prior warning. In the 1990s, Andrew Wiles proved Fermat’s Last Theorem. More recently, Yitang Zhang announced a key result on bounded gaps in the prime numbers. Both Wiles and Zhang had worked for years in isolation, keeping abreast of developments but carrying out intensive research programs unaided by others. This ensured that they did not have to share the glory of discovery, but it may not be an optimal way of making progress in mathematics.

Polymath

Timothy-Gowers-2012-Half

Timothy Gowers in 2012 [image Wikimedia Commons].

Is massively collaborative mathematics possible? This was the question posed in a 2009 blog post by Timothy Gowers, a Cambridge mathematician and Fields Medal winner. Gowers suggested completely new ways in which mathematicians might work together to accelerate progress in solving some really difficult problems in maths. He envisaged a forum for the online discussion of problems. Anybody interested could contribute to the discussion. Contributions would be short, and could include false routes and failures; these are normally hidden from view so that different workers repeat the same mistakes.

Continue reading ‘Massive Collaboration in Maths: the Polymath Project’

A Chirping Elliptic Rocker

Published March 28, 2019 Occasional Leave a Comment
Tags:

Sitting at the breakfast table, I noticed that a small cereal bowl placed within another larger one was rocking, and that the period became shorter as the amplitude died down. What was going on? 

Rocking-Bowl

A small bowl with its handles resting on the rim of a larger bowl. The handles are approximately elliptical in cross-section.

Continue reading ‘A Chirping Elliptic Rocker’

The Kill-zone: How to Dodge a Sniper’s Bullet

Published March 14, 2019 Occasional Leave a Comment
Tags: ,

Under mild simplifying assumptions, a projectile follows a parabolic trajectory. This results from Newton’s law of motion. Thus, for a fixed energy, there is an accessible region around the firing point comprising all the points that can be reached. We will derive a mathematical description for this kill-zone (the term kill-zone, used for dramatic effect, is the region embracing all the points that can be reached by a sniper’s bullet, given a fixed muzzle velocity).

Sniper-Killzone-1 Family of trajectories with fixed initial speed and varying launch angles. Two particular trajectories are shown in black. Continue reading ‘The Kill-zone: How to Dodge a Sniper’s Bullet’

Folding Maps: A Simple but Unsolved Problem

Published February 14, 2019 Occasional Leave a Comment
Tags:

Paper-folding is a recurring theme in mathematics. The art of origami is much-loved by many who also enjoy recreational maths. One particular folding problem is remarkably easy to state, but the solution remains elusive:

Given a map with M × N panels, how many different ways can it be folded?

Each panel is considered to be distinct, so two foldings are equivalent only when they have the same vertical sequence of the L = M × N layers.

Continue reading ‘Folding Maps: A Simple but Unsolved Problem’

Our Dearest Problems

Published January 31, 2019 Occasional Comments
Tags: ,

A Colloquium on Recreational Mathematics took place in Lisbon this week. The meeting, RMC-VI (G4GEurope), a great success, was organised by the Ludus Association, with support from several other agencies: MUHNAC, ULisboa, CMAF-IO, CIUHCT, CEMAPRE, and FCT. It was the third meeting integrated in the Gathering for Gardner movement, which celebrates the great populariser of maths, Martin Gardner. For more information about the meeting, see http://ludicum.org/ev/rm/19 .

Continue reading ‘Our Dearest Problems’

From a Wide Wake to the Width of the World

Published January 24, 2019 Occasional Leave a Comment
Tags: ,

The finite angular width of a ship’s turbulent wake at the horizon enables the Earth’s radius to be estimated.

By ignoring evidence, Flat-Earthers remain secure in their delusions. The rest of us benefit greatly from accurate geodesy. Satellite communications, GPS navigation, large-scale surveying and cartography all require precise knowledge of the shape and form of the Earth and a precise value of its radius.


Continue reading ‘From a Wide Wake to the Width of the World’

Really, 0.999999… is equal to 1. Surreally, this is not so!

Published January 10, 2019 Occasional Leave a Comment
Tags: ,

The value of the recurring decimal 0.999999 … is a popular topic of conversation amongst amateur mathematicians of various levels of knowledge and expertise. Some of the discussions on the web are of little value or interest, but the topic touches on several subtle and deep aspects of number theory.

999999

[Image Wikimedia Commons]

Continue reading ‘Really, 0.999999… is equal to 1. Surreally, this is not so!’

Gaussian Curvature: the Theorema Egregium

Published December 27, 2018 Occasional Comments
Tags: ,

ShapeOfUniverse

Surfaces of positive curvature (top), negative curvature (middle) and vanishing curvature (bottom) [image credit: NASA].

One of greatest achievements of Carl Friedrich Gauss was a theorem so startling that he gave it the name Theorema Egregium or outstanding theorem. In 1828 he published his “Disquisitiones generales circa superficies curvas”, or General investigation of curved surfaces. Gauss defined a quantity that measures the curvature of a two-dimensional surface. He was inspired by his work on geodesy, surveying and map-making, which involved taking measurements on the surface of the Earth. The total curvature — or Gaussian curvature — depends only on measurements within the surface and Gauss showed that its value is independent of the coordinate system used. This is his Theorema Egregium. The Gaussian curvature {K} characterizes the intrinsic geometry of a surface.

Continue reading ‘Gaussian Curvature: the Theorema Egregium

The 3 : 2 Resonance between Neptune and Pluto

Published December 13, 2018 Occasional Comment
Tags:

For every two orbits of Pluto around the Sun, Neptune completes three orbits. This 3 : 2 resonance has profound consequences for the stability of the orbit of Pluto.

Nep-Plu-Orbits-AB

Unstable (left) and stable (right) orbital configurations.

Continue reading ‘The 3 : 2 Resonance between Neptune and Pluto’

The Two Envelopes Fallacy

Published November 29, 2018 Occasional Comment
Tags: ,

During his Hamilton lecture in Dublin recently, Fields medalist Martin Hairer made a passing mention of the “Two Envelopes Paradox”. This is a well-known problem in probability theory that has led to much misunderstanding. It was originally developed in 1912 by the leading German number theorist Edmund Landau (see Gorroochurn, 2012). It is frequently discussed on the web, with much misunderstanding and confusion. I will try to avoid adding to that.

Two-Envelopes

Continue reading ‘The Two Envelopes Fallacy’

Gravitational Waves & Ringing Teacups

Published November 22, 2018 Occasional Leave a Comment
Tags: , ,

Newton’s law of gravitation describes how two celestial bodies orbit one another, each tracing out an elliptical path. But this is imprecise: the theory of general relativity shows that two such bodies radiate energy away in the form of gravitational waves (GWs), and spiral inwards until they eventually collide.

GW-Warning-Sign

Warning sign, described by Thomas Moore as a “geeky insider GR joke” [image from Moore, 2013].

Continue reading ‘Gravitational Waves & Ringing Teacups’

Listing the Rational Numbers III: The Calkin-Wilf Tree

Published November 8, 2018 Occasional Leave a Comment
Tags: ,

Calkin-Wilf-TreeThe rational numbers are countable: they can be put into one-to-one correspondence with the natural numbers. In previous articles we showed how the rationals can be presented as a list that includes each rational precisely once. One approach leads to the Farey Sequences. A second, related, approach gives us the Stern-Brocot Tree. Here, we introduce another tree structure, The Calkin-Wilf Tree.

Continue reading ‘Listing the Rational Numbers III: The Calkin-Wilf Tree’

Saving Daylight with Hip-hop Time: a Modest Proposal

Published October 25, 2018 Occasional Leave a Comment
Tags:

At 2:00 AM on Sunday 28 October the clocks throughout Europe will be set back one hour, reverting to Standard Time. In many countries, the clocks are put forward one hour in Spring and set back to Standard Time in the Autumn. Daylight saving time gives brighter evenings in Summer.

Hiphop-Time-Banner

In Summer, the mornings are already bright before most of us wake up but, in Winter, the mornings would be too dark unless we reverted to Standard Time.

Continue reading ‘Saving Daylight with Hip-hop Time: a Modest Proposal’

Listing the Rational Numbers II: The Stern-Brocot Tree

Published October 11, 2018 Occasional Leave a Comment
Tags: ,

The rational numbers are countable: they can be put into one-to-one correspondence with the natural numbers. But it is not obvious how to construct a list that is sure to contain every rational number precisely once. In a previous post we described the Farey Sequences. Here we examine another, related, approach.

Mediant-red Continue reading ‘Listing the Rational Numbers II: The Stern-Brocot Tree’

Listing the Rational Numbers: I. Farey Sequences

Published September 27, 2018 Occasional Leave a Comment
Tags: ,

We know, thanks to Georg Cantor, that the rational numbers — ratios of integers — are countable: they can be put into one-to-one correspondence with the natural numbers.

Rational-Numbers-Small

Continue reading ‘Listing the Rational Numbers: I. Farey Sequences’

A Trapezoidal Prism on the Serpentine

Published September 13, 2018 Occasional Leave a Comment
Tags:

Walking in Hyde Park recently, I spied what appeared to be a huge red pyramid in the middle of the Serpentine. On closer approach, and with a changing angle of view, it became clear that it was prismatic in shape, composed of numerous barrels in red, blue and purple.

Christo-Mastaba-00

Changing perspective on approach to the Mastaba

Continue reading ‘A Trapezoidal Prism on the Serpentine’

A Zero-Order Front

Published August 30, 2018 Occasional Leave a Comment
Tags: , ,

DosTemp18

Sharp gradients known as fronts form in the atmosphere when variations in the wind field bring warm and cold air into close proximity. Much of our interesting weather is associated with the fronts that form in extratropical depressions.

Below, we describe a simple mechanistic model of frontogenesis, the process by which fronts are formed.

Continue reading ‘A Zero-Order Front’

Last 50 Posts

Categories