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Main Authors: Nagao, Keiko I., Sakano, Yuga, Shinohara, Takashi, Matsuda, Yuji, Takami, Hisashi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.14561
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author Nagao, Keiko I.
Sakano, Yuga
Shinohara, Takashi
Matsuda, Yuji
Takami, Hisashi
author_facet Nagao, Keiko I.
Sakano, Yuga
Shinohara, Takashi
Matsuda, Yuji
Takami, Hisashi
contents In this study, we conducted an experiment to estimate $π$ using body-to-body and body-to-wall collisions. By geometrically analyzing the system's motion, we first review how the collision count corresponds to the digits of $π$. This method utilizes the property that the number of collisions corresponds to $π$ to the $n$-th decimal place by setting the mass ratio of bodies to $1:100^n$ under ideal conditions. In particular, when the mass ratio is $1:100$ -- which is the case we tested experimentally -- the number of collisions is 31, and $π$ to the tenths decimal place (3.1) can be derived. In the experiments, a suspended apparatus was developed to minimize energy losses such as friction and air resistance. We also devised the shape and material of the colliding bodies' surface and the characteristics of the suspension string, aiming for measurements under stable conditions. Based on the experimental results, we reproduced the number of collisions consistent with the theoretical values and confirmed that estimating $π$ to the tenths decimal place is possible under realistic conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2510_14561
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Estimation of $π$ via experiment
Nagao, Keiko I.
Sakano, Yuga
Shinohara, Takashi
Matsuda, Yuji
Takami, Hisashi
General Physics
In this study, we conducted an experiment to estimate $π$ using body-to-body and body-to-wall collisions. By geometrically analyzing the system's motion, we first review how the collision count corresponds to the digits of $π$. This method utilizes the property that the number of collisions corresponds to $π$ to the $n$-th decimal place by setting the mass ratio of bodies to $1:100^n$ under ideal conditions. In particular, when the mass ratio is $1:100$ -- which is the case we tested experimentally -- the number of collisions is 31, and $π$ to the tenths decimal place (3.1) can be derived. In the experiments, a suspended apparatus was developed to minimize energy losses such as friction and air resistance. We also devised the shape and material of the colliding bodies' surface and the characteristics of the suspension string, aiming for measurements under stable conditions. Based on the experimental results, we reproduced the number of collisions consistent with the theoretical values and confirmed that estimating $π$ to the tenths decimal place is possible under realistic conditions.
title Estimation of $π$ via experiment
topic General Physics
url https://arxiv.org/abs/2510.14561