1 / 31

Babylonian mathematics

Babylonian mathematics. Eleanor Robson University of Cambridge. Outline. Introducing ourselves Going to school in ancient Babylonia Learning about Babylonian numbers Learning about Babylonian shapes Question time. Who were the Babylonians?. Where did they live? When did they live?

dai
Télécharger la présentation

Babylonian mathematics

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Babylonian mathematics Eleanor Robson University of Cambridge

  2. Outline • Introducing ourselves • Going to school in ancient Babylonia • Learning about Babylonian numbers • Learning about Babylonian shapes • Question time

  3. Who were the Babylonians? • Where did they live? • When did they live? • What were their lives like?

  4. We live here The Babylonians lived here, 5000-2000 years ago

  5. Babylonia, 1900–1650 BC • Cities and writing for 1500 years already • Brick-built cities on rivers and canals • Wealth through farming: barley and sheep • Central temples, to worship many gods • King Hammurabi (1792–1750 BC) • Most children didn’t go to school

  6. Babylonian men and women

  7. Cuneiform writing • Wedges on clay • Whole words • Syllables • Word types • 600 different signs • Sumerian language • No known relatives • Akkadian language • Related to Hebrew, Arabic, and other modern Middle Eastern languages

  8. Cuneiform objects

  9. Employed by: Temples Palaces Courts of law Wealthy families Status: Slaves Senior officials Nobility In order to write: Receipts and lists Monthly and annual accounts Loans, leases, rentals, and sales Marriage contracts, dowries, and wills Royal inscriptions Records of legal disputes Letters Professional scribes

  10. I’m an archaeologist of maths • Archaeology is the study of rubbish • To discover how people lived and died • To discover how people made and used objects to work with and think with • Doing maths leaves a trail of rubbish behind • I study the mathematical rubbish of the ancient Babylonians

  11. Imagine an earthquake destroys your school in the middle of the night … • An archaeologist comes to your school 500 years from now … • What mathematical things might she find in your school? • What would they tell her about the maths you do?

  12. Some mathematical things in modern schools • Text books and exercise books • Scrap paper and doodles • Mathematical instruments from rulers to calculators • Mathematical displays from models to posters • Computer files and hardware

  13. But isn’t maths the same everywhere? • Two different ways of thinking about maths: • Maths is discovered, like fossils • Its history is just about who discovered what, and when • Maths is created by people, like language • Its history is about who thought and used what, and why

  14. Looking at things in context tells us far more than studying single objects What sort of people wrote those tablets and why? Tablets don’t rot like paper or papyrus do They got lost, thrown away, or re-used Archaeologists dig them up just like pots, bones or buildings The archaeology of Babylonian maths

  15. The ancient city of Nippur

  16. Maths at school: House F • A small house in Nippur, 10m x 5m • Excavated in 1951 • From the 1740s BC • 1400 fragments of tablets with school exercises • Tablets now in Chicago, Philadelphia, and Baghdad • Tablet recycling bin • Kitchen with oven • Room for a few students

  17. The House F curriculum • Wedges and signs • People’s names • Words for things (wood, reed, stone, metal, …) • How cuneiform works • Weights, measures, and multiplications • Sumerian sentences • Sumerian proverbs • Sumerian literature

  18. Babylonian numbers • Different: cuneiform signs pressed into clay • Vertical wedges 1–9 • Arrow wedges 10–50 • Different/same: in base 60 • What do we still count in base 60? • Same: order matters • Place value systems • Different: no zero – and no boundary between whole numbers & fractions

  19. 1 52 30

  20. Playing with Babylonian numbers • Try to write: • 32 • 23 • 18 • 81 • 107 • 4 1/2 • Think of a number for your friend to write. Did they do it right?

  21. Multiplication tables • 1 30 • 2 1 • 3 1 30 • 4 2 • 5 2 30 • 6 3 • 7 3 30 • 8 4 • 9 4 30 • 10 5 • 11 5 30 • [12] 6 • 13 6 30 …

  22. … continued • [14 7] • [15 7 30] • 16 [8] • 17 [8 30] • 18 9 • 20-1 9 30 • 20 10 • 30 15 • 40 20 • 50 25

  23. Practicing calculations 5 155 1527 33 45 5.25x 5.25 27.5625 or 325x 325= 105,625

  24. Was Babylonian maths so different from ours? • Draw or imagine a triangle

  25. Two Babylonian triangles

  26. Cultural preferences • Horizontal base • Vertical axis of symmetry • Equilateral • Left-hand vertical edge • Hanging right-angled triangle or horizontal axis of symmetry • Elongated

  27. A Babylonian maths book back front

  28. What are these shapes? • The side of the square is 60 rods. Inside it are: • 4 triangles, • 16 barges, • 5 cow's noses. • What are their areas? "Triangle" is actually santakkum "cuneiform wedge" — and doesn't have to have straight edges

  29. Barge and cow’s nose

  30. A father praises his son’s teacher: • “My little fellow has opened wide his hand, and you made wisdom enter there. You showed him all the fine points of the scribal art; you even made him see the solutions of mathematical and arithmetical problems.”

More Related