Computer Program Detail Page
written by Andrew Duffy
This simulation allows students to compare the motion of free falling objects with and without the influence of air resistance. Air resistance is the result of collisions of the object's leading surface with air molecules. On Earth, objects falling through the air usually encounter some sort of air resistance, though the amount is dependent upon several factors. In this model, a blue ball falls under the influence of gravity alone. A falling red ball is subject to both gravity and air resistance. The user can adjust the amount of air resistance with a slider. When the simulation is played, graphs are simultaneously plotted that show position vs. time, velocity vs. time, and acceleration vs. time for both falling balls.
See Annotations Below for an editor-recommended, interactive tutorial that further explains free fall and air resistance.
This item was created with Easy Java Simulations (EJS), a modeling tool that allows users without formal programming experience to generate computer models and simulations. To run the simulation, simply click the Java Archive file below. To modify or customize the model, See Related Materials for detailed instructions on installing and running the EJS Modeling and Authoring Tool.
Please note that this resource requires at least version 1.5 of Java (JRE).
View the source code document attached to this resource
AAAS Benchmark Alignments (2008 Version)
4. The Physical Setting
4G. Forces of Nature
9. The Mathematical World
9B. Symbolic Relationships
11. Common Themes
Common Core State Standards for Mathematics Alignments
High School — Functions (9-12)
Interpreting Functions (9-12)
Linear, Quadratic, and Exponential Models? (9-12)
The Physics Classroom: Free Fall and Air Resistance (Editor: Caroline Hall)
This editor-recommended interactive tutorial from The Physics Classroom will help students understand the factors that cause air resistance and how this impacts the motion of free fall. The tutorial engages students with animations, free-body diagrams of an elephant and a mouse in free-fall, and a glimpse of terminal velocity. Students will also do simple calculations.
This resource is part of a Physics Front Topical Unit.
Topic: Kinematics: The Physics of Motion
Unit Title: Motion in One Dimension
How does air resistance affect the motion of a free-falling object? In this model, a blue ball falls under the influence of gravity alone. The red ball is subject to both gravity and air resistance. Adjust the amount of air resistance with a slider, then watch the changes in the motion graphs.Link to Unit:
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Free Fall Air Resistance Model:
Simulates Physics Classroom: Free Fall and Air Resistance
An editor-recommended interactive tutorial that explores the influence of air resistance on free-falling objects and introduces the concept of terminal velocity.relation by Caroline Hall
Is Based On Easy Java Simulations Modeling and Authoring Tool
The Easy Java Simulations Modeling and Authoring Tool is needed to explore the computational model used in the Free Fall Air Resistance Model.relation by Mario Belloni
Covers the Same Topic As http://www.physicsclassroom.com/Class/newtlaws/u2l3e.cfm
This editor-recommended interactive tutorial provides content support on factors causing air resistance and how this affects the motion of free fall.relation by Caroline Hall
Is a Teaching Guide For Physics Classroom: Free Fall and Air Resistance
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