The Discovery That Transformed Pi

Veritasium

16 Mar 202118:40

Summary

TLDRThis video delves into the history of calculating Pi, from ancient methods involving polygons to Isaac Newton's revolutionary approach. The video explains how early mathematicians like Archimedes calculated Pi using inscribed and circumscribed polygons, progressively increasing the number of sides for greater accuracy. However, it was Newton's application of the binomial theorem to negative and fractional powers that drastically simplified Pi's calculation. His use of infinite series, combined with integration techniques, allowed for rapid and highly precise calculations of Pi, transforming mathematical methods and effectively ending the polygonal approach.

Takeaways

😀 Pi has been historically difficult to calculate, with methods like Archimedes' polygon approximation being painstakingly slow and tedious.
😀 Isaac Newton revolutionized the calculation of Pi by using infinite series, effectively 'speed-running' the process.
😀 Pi represents the ratio of a circle's circumference to its diameter, but also appears in many other mathematical formulas, such as the area of a circle (Pi * R^2).
😀 Archimedes improved the initial method of calculating Pi by using polygons with an increasing number of sides, reaching an estimate of Pi between 3.1408 and 3.1429.
😀 Over the centuries, mathematicians like Francois Viete and Ludolph van Ceulen took this method further, but only achieved up to 35 decimal places of Pi after decades of effort.
😀 Newton introduced an alternative approach by extending Pascal's triangle and applying the binomial theorem to negative and fractional powers, uncovering a faster method for Pi calculation.
😀 The binomial theorem could be applied to non-integer exponents, leading to infinite series expansions for functions like (1 + X) raised to fractional powers.
😀 Newton applied these expansions to calculate Pi, ultimately deriving an infinite series for the area under a quarter circle and thus finding Pi.
😀 Newton's genius was in modifying the binomial expansion to apply to fractional exponents, allowing him to quickly approximate values like the square root of 3 and the value of Pi.
😀 Newton used integration and series expansions to refine his Pi calculation, ultimately achieving greater precision than previous polygon-based methods, calculating Pi to more than 35 decimal places with just a few terms.
😀 The method of bisecting polygons was obsolete after Newton’s work, marking a dramatic shift in mathematical tools and efficiency for calculating constants like Pi.

Q & A

How did people originally calculate Pi before Isaac Newton's contribution?
-For over 2000 years, mathematicians calculated Pi by inscribing and circumscribing polygons within a circle. The most famous method was Archimedes' approach, where he used polygons with increasing numbers of sides, calculating their perimeters to narrow down Pi's value.
How did Archimedes improve the method of calculating Pi?
-Archimedes began with a hexagon and progressively doubled the number of sides of the inscribed and circumscribed polygons, up to a 96-sided polygon. This process allowed him to estimate Pi to be between 3.1408 and 3.1429, significantly refining earlier estimates.
What was Ludolph van Ceulen's contribution to calculating Pi?
-Ludolph van Ceulen spent 25 years calculating Pi to 35 decimal places by working with a polygon with over four quintillion sides. His work was so celebrated that the digits of Pi he computed were inscribed on his tombstone.
What was the breakthrough made by Isaac Newton in 1666?
-Isaac Newton introduced the use of infinite series to calculate Pi, using his newly developed method of calculus. He applied the binomial theorem to fractional powers, allowing for a much more efficient and precise calculation of Pi.
What is Pascal's triangle and how did it help Isaac Newton?
-Pascal's triangle is a pattern of numbers where each number is the sum of the two numbers directly above it. Newton used the coefficients in Pascal's triangle to extend the binomial theorem to fractional powers, which became central to his method of calculating Pi.
What was unique about Newton's application of the binomial theorem?
-Newton extended the binomial theorem, which was originally used for positive integers, to work for negative integers and even fractional exponents, such as one-half. This led to the discovery of infinite series that could be used to calculate Pi.
How did Newton's series allow for a more efficient calculation of Pi?
-Newton's series involved an alternating sum of terms with powers of X. By integrating this series, Newton could calculate Pi to a high degree of accuracy quickly, with only a few terms needed to achieve precision.
What was the significance of Newton integrating from zero to one-half instead of zero to one?
-By integrating from zero to one-half, Newton was able to make each term in the series shrink faster, leading to a quicker convergence and more efficient calculation of Pi. This approach reduced the number of terms needed to achieve high accuracy.
How did Newton calculate Pi using a quarter circle?
-Newton recognized that the area of a unit circle is Pi, and by integrating the function for the top half of the circle (from zero to one), he computed Pi/4. This allowed him to derive Pi efficiently using an infinite series.
How does the story of calculating Pi illustrate the importance of new mathematical techniques?
-The transition from bisecting polygons to using infinite series with calculus demonstrates how mathematical innovation can dramatically improve efficiency and accuracy. Newton's methods marked the end of the old, tedious approaches and set the stage for modern calculations of Pi.