![CALCULATION OF PI || BAILEY-BORWEIN-PLOUFFE || INTERESTING MATH FACTS IMPLEMENTATION USING PYTHON || - YouTube CALCULATION OF PI || BAILEY-BORWEIN-PLOUFFE || INTERESTING MATH FACTS IMPLEMENTATION USING PYTHON || - YouTube](https://i.ytimg.com/vi/H-qJNyd1GI4/maxresdefault.jpg)
CALCULATION OF PI || BAILEY-BORWEIN-PLOUFFE || INTERESTING MATH FACTS IMPLEMENTATION USING PYTHON || - YouTube
![Fermat's Library on Twitter: "The Bailey-Borwein-Plouffe formula, discovered in 1995, allows to calculate any digit of π (in base 16) without calculating the preceding digits. https://t.co/qu2a2CF7g7" / Twitter Fermat's Library on Twitter: "The Bailey-Borwein-Plouffe formula, discovered in 1995, allows to calculate any digit of π (in base 16) without calculating the preceding digits. https://t.co/qu2a2CF7g7" / Twitter](https://pbs.twimg.com/media/DTGglPeWkAA0Mlw.jpg)
Fermat's Library on Twitter: "The Bailey-Borwein-Plouffe formula, discovered in 1995, allows to calculate any digit of π (in base 16) without calculating the preceding digits. https://t.co/qu2a2CF7g7" / Twitter
![The Bailey-Borwein-Plouffe Formula for Calculating the First n Digits of Pi – Numerical Explorations The Bailey-Borwein-Plouffe Formula for Calculating the First n Digits of Pi – Numerical Explorations](https://jamespatewilliamsjr.files.wordpress.com/2018/07/bbp-formula-bd-1000.jpg?w=840)
The Bailey-Borwein-Plouffe Formula for Calculating the First n Digits of Pi – Numerical Explorations
![∇ₖPascal ∇ₚKwanten (∛) (Πασκάλ) on Twitter: "@InertialObservr What about the practical: BBP formula (after: Bailey-Borwein-Plouffe) is a formula for calculating Pi discovered in 1995. This formula is a digit-extraction algorithm for in ∇ₖPascal ∇ₚKwanten (∛) (Πασκάλ) on Twitter: "@InertialObservr What about the practical: BBP formula (after: Bailey-Borwein-Plouffe) is a formula for calculating Pi discovered in 1995. This formula is a digit-extraction algorithm for in](https://pbs.twimg.com/media/D6qhGzdXkAAtu3r.jpg:large)
∇ₖPascal ∇ₚKwanten (∛) (Πασκάλ) on Twitter: "@InertialObservr What about the practical: BBP formula (after: Bailey-Borwein-Plouffe) is a formula for calculating Pi discovered in 1995. This formula is a digit-extraction algorithm for in
![CALCULATION OF PI || BAILEY-BORWEIN-PLOUFFE || INTERESTING MATH FACTS IMPLEMENTATION USING PYTHON || - YouTube CALCULATION OF PI || BAILEY-BORWEIN-PLOUFFE || INTERESTING MATH FACTS IMPLEMENTATION USING PYTHON || - YouTube](https://i.ytimg.com/vi/tDOsr_qfpag/maxresdefault.jpg)
CALCULATION OF PI || BAILEY-BORWEIN-PLOUFFE || INTERESTING MATH FACTS IMPLEMENTATION USING PYTHON || - YouTube
![Martin Bauer on Twitter: "I just learned that the first formula for calculating the n-th decimal digit of pi (without calculating all the preceding digits) has been found by Simon Plouffe in Martin Bauer on Twitter: "I just learned that the first formula for calculating the n-th decimal digit of pi (without calculating all the preceding digits) has been found by Simon Plouffe in](https://pbs.twimg.com/media/FmgboVtXEAABtME.png)
Martin Bauer on Twitter: "I just learned that the first formula for calculating the n-th decimal digit of pi (without calculating all the preceding digits) has been found by Simon Plouffe in
Dave Richeson on Twitter: "The BBP (Bailey-P. Borwein-Plouffe) formula was discovered by a computer in 1996. Remarkably, it can be used to compute any hexadecimal digit of π without computing any of
![Dave Richeson on Twitter: "The BBP (Bailey-P. Borwein-Plouffe) formula was discovered by a computer in 1996. Remarkably, it can be used to compute any hexadecimal digit of π without computing any of Dave Richeson on Twitter: "The BBP (Bailey-P. Borwein-Plouffe) formula was discovered by a computer in 1996. Remarkably, it can be used to compute any hexadecimal digit of π without computing any of](https://pbs.twimg.com/media/DhRkT6WV4AAgAAx.jpg:large)