Pi Approximation Day 2023: 8 Interesting facts to know

PIE DAY 2023: 8 FACTS TO KNOW

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[{"selector":"#anim-e9a2e17c-bfd7-46b6-b721-5c66c20c98d2","keyframes":{"transform":["translate3d(115.18987%, 0px, 0)","translate3d(0px, 0px, 0)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-581e1383-0dee-4b37-907e-778ace70e77f","keyframes":{"opacity":[0,1]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-ad356f5d-8540-4eaa-bf36-3bff6064a446","keyframes":{"transform":["scale(0.15)","scale(1)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"forwards"}] Ancient Babylonians approximated pi as 3,125 by calculating a hexagon's perimeter inscribed within a circle, assuming a ratio of 24/25 to the circumference. Egyptians used 256/81 (about 3.16045) Ancient Babylonians approximated pi as 3,125 by calculating a hexagon's perimeter inscribed within a circle, assuming a ratio of 24/25 to the circumference. Egyptians used 256/81 (about 3.16045)

[{"selector":"#anim-5a57a8b7-96c7-4646-90be-614b885762d7","keyframes":{"transform":["translate3d(-114.87342%, 0px, 0)","translate3d(0px, 0px, 0)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-71ab0f14-0bab-4a6e-9c82-c4e89e530549","keyframes":{"opacity":[0,1]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-9aa29c25-41e2-40ab-b934-1ee27f1bc8d5","keyframes":{"transform":["scale(0.15)","scale(1)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"forwards"}] Accurate pi came with inscribing and circumscribing regular polygons around a circle, establishing upper and lower bounds. The average, approximately 3.1418, marked notable progress in precision. Accurate pi came with inscribing and circumscribing regular polygons around a circle, establishing upper and lower bounds. The average, approximately 3.1418, marked notable progress in precision.

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[{"selector":"#anim-cde92620-167d-4575-a1aa-8178b891190d","keyframes":{"transform":["translate3d(115.55555%, 0px, 0)","translate3d(0px, 0px, 0)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-f8314b98-ecca-48b5-b470-6f235a7c5e59","keyframes":{"opacity":[0,1]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-4dc93e08-b47e-42af-85b6-41324822ac65","keyframes":{"transform":["scale(0.15)","scale(1)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"forwards"}] 20th-century mathematician Srinivasa Ramanujan revolutionized pi's calculation with efficient methods. His contributions influenced computer algorithms, enabling more accurate approximations. 20th-century mathematician Srinivasa Ramanujan revolutionized pi's calculation with efficient methods. His contributions influenced computer algorithms, enabling more accurate approximations.

[{"selector":"#anim-3dca6149-7528-46c9-a0cb-d0e1ea3081ee","keyframes":{"transform":["translate3d(-115.18988%, 0px, 0)","translate3d(0px, 0px, 0)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-cd320b2e-3afa-4458-b4e5-d3bdd4752c4c","keyframes":{"opacity":[0,1]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-e1544584-0dc2-44fb-b2ae-2c38886ac358","keyframes":{"transform":["scale(0.15)","scale(1)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"forwards"}] Computers played a crucial role, calculating pi to 31,415,926,535,897 decimal places in the early 21st century, even determining its two-quadrillionth binary digit (0). Computers played a crucial role, calculating pi to 31,415,926,535,897 decimal places in the early 21st century, even determining its two-quadrillionth binary digit (0).

[{"selector":"#anim-262d8939-bdd3-4399-9ae7-f150712ec57d","keyframes":{"transform":["translate3d(115.18987%, 0px, 0)","translate3d(0px, 0px, 0)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-875f3480-3c3f-4ef0-b07d-792242c3dff7","keyframes":{"opacity":[0,1]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"both"}] [{"selector":"#anim-72c61bf5-a2f6-464e-98f5-7e54eb487cb6","keyframes":{"transform":["scale(0.15)","scale(1)"]},"delay":0,"duration":600,"easing":"cubic-bezier(0.4, 0.4, 0.0, 1)","fill":"forwards"}] Pi finds applications in science and engineering, solving problems related to arcs, ellipses, sectors, and curved surfaces. It's essential for describing periodic phenomena like pendulum motion, string vibrations, and electric currents.