Computational Orbital Mechanics of Marble Motion on a 3D Printed Surface -- 1. Formal Basis

Computational Orbital Mechanics of Marble Motion on a 3D Printed Surface -- 1. Formal Basis

Simulating curvature due to gravity through warped surfaces is a common visualization aid in Physics education. We reprise a recent experiment exploring orbital trajectories on a precise 3D-printed surface to mimic Newtonian gravity, and elevate this analogy past the status of a mere visualization t...

Full description

Saved in:
Bibliographic Details
Main Authors: Bhambhu, Pooja, Preety, Goel, Paridhi, Chinkey, Siwach, Manisha, Kumari, Ananya, Sudarshana, Yadav, Sanjana, Yadav, Shikha, Bharti, Poonam, Anshumali, Vijayan, Athira, Pathak, Divakar
Format: Journal Article
Language:English
Published: 23-02-2023
Subjects:
Physics - Physics Education
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Simulating curvature due to gravity through warped surfaces is a common visualization aid in Physics education. We reprise a recent experiment exploring orbital trajectories on a precise 3D-printed surface to mimic Newtonian gravity, and elevate this analogy past the status of a mere visualization tool. We present a general analysis approach through which this straightforward experiment can be used to create a reasonably advanced computational orbital mechanics lab at the undergraduate level, creating a convenient hands-on, computational pathway to various non-trivial nuances in this discipline, such as the mean, eccentric, and true anomalies and their computation, Laplace-Runge-Lenz vector conservation, characterization of general orbits, and the extraction of orbital parameters. We show that while the motion of a marble on such a surface does not truly represent a orbital trajectory under Newtonian gravity in a strict theoretical sense, but through a proposed projection procedure, the experimentally recorded trajectories closely resemble the Kepler orbits and approximately respect the known conservation laws for orbital motion. The latter fact is demonstrated through multiple experimentally-recorded elliptical trajectories with wide-ranging eccentricities and semi-major axes. In this first part of this two-part sequence, we lay down the formal basis of this exposition, describing the experiment, its calibration, critical assessment of the results, and the computational procedures for the transformation of raw experimental data into a form useful for orbital analysis.
DOI:10.48550/arxiv.2302.12643