100 Essential Things You Didn't Know You Didn't Know

Contents

Cover

About the Book

About the Author

Also by John Barrow

Dedication

Title Page

Epigraph

Preface

1. Pylon of the Month

2. A Sense of Balance

3. Monkey Business

4. Independence Day

5. Rugby and Relativity

6. Wagons Roll

7. A Sense of Proportion

8. Why Does the Other Queue Always Move Faster?

9. Two’s Company, Three’s a Crowd

10. It’s a Small World After All

11. Bridging That Gap

12. On the Cards

13. Tally Ho

14. Relationships

15. Racing Certainties

16. High Jumping

17. Superficiality

18. VAT in Eternity

19. Living in a Simulation

20. Emergence

21. How to Push a Car

22. Positive Feedback

23. The Drunkard’s Walk

24. Faking It

25. The Flaw of Averages

26. The Origami of the Universe

27. Easy and Hard Problems

28. Is This a Record?

29. A Do-It-Yourself Lottery

30. I Do Not Believe It!

31. Flash Fires

32. The Secretary Problem

33. Fair Divorce Settlements: the Win–Win Solution

34. Many Happy Returns

35. Tilting at Windmills

36. Verbal Conjuring

37. Financial Investment with Time Travellers

38. A Thought for Your Pennies

39. Breaking the Law of Averages

40. How Long are Things Likely to Survive?

41. A President who Preferred the Triangle to the Pentagon

42. Secret Codes in Your Pocket

43. I’ve Got a Terrible Memory for Names

44. Calculus Makes You Live Longer

45. Getting in a Flap

46. Your Number’s Up

47. Double Your Money

48. Some Reflections on Faces

49. The Most Infamous Mathematician

50. Roller Coasters and Motorway Junctions

51. A Taylor-made Explosion

52. Walk Please, Don’t Run!

53. Mind-reading Tricks

54. The Planet of the Deceivers

55. How to Win the Lottery

56. A Truly Weird Football Match

57. An Arch Problem

58. Counting in Eights

59. Getting a Mandate

60. The Two-headed League

61. Creating Something out of Nothing

62. How to Rig An Election

63. The Swing of the Pendulum

64. A Bike with Square Wheels

65. How Many Guards Does an Art Gallery Need?

66. . . . and What About a Prison?

67. A Snooker Trick Shot

68. Brothers and Sisters

69. Playing Fair with a Biased Coin

70. The Wonders of Tautology

71. What a Racket

72. Packing Your Stuff

73. Sent Packing Again

74. Crouching Tiger

75. How the Leopard Got His Spots

76. The Madness of Crowds

77. Diamond Geezer

78. The Three Laws of Robotics

79. Thinking Outside the Box

80. Googling in the Caribbean – The Power of the Matrix

81. Loss Aversion

82. The Lead in Your Pencil

83. Testing Spaghetti to Destruction

84. The Gherkin

85. Being Mean with the Price Index

86. Omniscience can be a Liability

87. Why People aren’t Cleverer

88. The Man from Underground

89. There are No Uninteresting Numbers

90. Incognito

91. The Ice Skating Paradox

92. The Rule of Two

93. Segregation and Micromotives

94. Not Going with the Flow

95. Venn Vill They Ever Learn

96. Some Benefits of Irrationality

97. Strange Formulae

98. Chaos

99. All Aboard

100. The Global Village

Notes

Copyright

About the Book

‘If people do not believe that mathematics is simple, it is only because they do not realize how complicated life is.’
John von Neumann

Mathematics can tell you things about the world that can’t be learned in any other way. This hugely informative and wonderfully entertaining little book answers one hundred essential questions about existence. It unravels the knotty, clarifies the conundrums and sheds light into dark corners. From winning the lottery, placing bets at the races and escaping from bears to sports, Shakepeare, Google, game theory, drunks, divorce settlements and dodgy accounting; from chaos to infinity and everything in between,
100 Essential Things You Didn’t Know You Didn’t Know
has all the answers!

About the Author

John D. Barrow is Professor of Mathematical Sciences and Director of the Millenium Mathematics Project at Cambridge University, Fellow of Clare Hall, Cambridge, a Fellow of the Royal Society, and the current Gresham Professor of Geometry at Gresham College, London. His previous books include
The Origin of the Universe
;
The Universe that Discovered Itself
;
The Book of Nothing
;
The Constants of Nature: From Alpha to Omega
;
The Infinite Book: A Short Guide to the Boundless, Timeless and Endless
;
The Artful Universe Expanded
;
New Theories of Everything
and, most recently,
Cosmic Imagery: Key Images in the History of Science
. He is also the author of the award-winning play
Infinities
.

Also by John Barrow

Theories of Everything

The Left Hand of Creation

(with Joseph Silk)

L’Homme et le Cosmos

(with Frank J. Tipler)

The Anthropic Cosmological Principle

(with Frank J. Tipler)

The World within the World

The Artful Universe

Pi in the Sky

Perchè il mondo è matematico?

Impossibility

The Origin of the Universe

Between Inner Space and Outer Space

The Universe that Discovered Itself

The Book of Nothing

The Constants of Nature:

From Alpha to Omega

The Infinite Book:

A Short Guide to the Boundless,

Timeless and Endless

Cosmic Imagery:

Key Images in the History of Science

100 Essential Things You Didn’t Know

You Didn’t Know About Sport

The Book of Universes

To
David and Emma

I continued to do arithmetic with my father, passing proudly through fractions to decimals. I eventually arrived at the point where so many cows ate so much grass, and tanks filled with water in so many hours. I found it quite enthralling.

Agatha Christie

Preface

This is a little book of bits and pieces – bits about off-beat applications of mathematics to everyday life, and pieces about a few other things not so very far away from it. There are a hundred to choose from, in no particular order, with no hidden agenda and no invisible thread. Sometimes you will find only words, but sometimes you will find some numbers as well, and very occasionally a few further notes that show you some of the formulae behind the appearances. Maths is interesting and important because it can tell you things about the world that you can’t learn in any other way. When it comes to the depths of fundamental physics or the breadth of the astronomical universe we have almost come to expect that. But I hope that here you will see how simple ideas can shed new light on all sorts of things that might otherwise seem boringly familiar or just pass by unnoticed.

Lots of the examples contained in the pages to follow were stimulated by the goals of the Millennium Mathematics Project
^fn1
, which I came to Cambridge to direct in 1999. The challenge of showing how mathematics has something to tell about most things in the world around us is one that, when met, can play an important part in motivating and informing people, young and old, to appreciate and understand the place of mathematics at the root of our understanding of the world.

I would like to thank Steve Brams, Marianne Freiberger, Jenny Gage,
John
Haigh, Jörg Hensgen, Helen Joyce, Tom Körner, Imre Leader, Drummond Moir, Robert Osserman, Jenny Piggott, David Spiegelhalter, Will Sulkin, Rachel Thomas, John H. Webb, Marc West, and Robin Wilson for helpful discussions, encouragement, and other practical inputs that contributed to the final collection of essential things you now find before you.

Finally, thanks to Elizabeth, David, Roger and Louise for their unnervingly close interest in this book. Several of these family members now often tell me why pylons are made of triangles and tightrope walkers carry long poles. Soon you will know too.

John D. Barrow

August 2008, Cambridge

fn1
www.mmp.maths.org

1

Pylon of the Month

Like Moses parting the waves, National Grid Company PLC’s 4YG8 leads his fellow pylons through this Oxfordshire housing estate towards the ‘promised land’ of Didcot Power Station.

The December 1999
Pylon of the Month

There are some fascinating websites about, but none was more beguiling than the iconic
Pylon of the Month
,
^fn1
once devoted to providing monthly pin-ups of the world’s most exciting and seductive electricity pylons. The ones shown on the website below are from Scotland. Alas,
Pylon of the Month
now seems to have become a cobweb site, but there is still something to learn from it, since for the mathematician every pylon tells a story. It is about something so prominent and ubiquitous that, like gravity, it goes almost unnoticed.

Next time you go on a train journey, look carefully at the pylons as they pass swiftly by the windows. Each is made of a network of metal struts that make use of a single recurring polygonal shape. That shape is the triangle. There are big triangles and smaller ones nested within them. Even apparent squares and rectangles are merely separate pairs of triangles. The reason forms a small part of an interesting mathematical story that began in the early nineteenth century with the work of the French mathematician Augustin-Louis Cauchy.

Of all the polygonal shapes that we could make by bolting together straight struts of metal, the triangle is special. It is the only one that is
rigid
. If they were hinged at their corners, all the others can be flexed gradually into a different shape without bending the metal. A square or a rectangular frame provides a simple example: we see that it can be deformed into a parallelogram without any buckling. This is an important consideration if you aim to maintain structural stability in the face of winds and temperature changes. It is why pylons seem to be great totems to the god of all triangles.