Tracker Pendulum Collision Model

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Author: video: pohhuiyinaomi, model: lookang
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Document Brief: Pendulum Collision with a Flying Object Using Tracker

This document explores the dynamics of a pendulum colliding with a flying object, modeled and analyzed using Tracker software. The interaction captures energy and momentum transfer, demonstrating how the pendulum’s motion is influenced before and after the collision. Angular displacement ( $θ$ , angular velocity ( $ω$ ), and angular acceleration ( $α$ ) are examined to describe the dynamics.

Purpose:

To study the interaction between a pendulum and a flying object, focusing on energy conservation, momentum transfer, and oscillatory motion post-collision.

Key Features:

Visualization of the pendulum’s oscillatory motion before and after the collision.
Analysis of angular displacement, velocity, and acceleration during the collision event.
Examination of the collision's effect on the pendulum’s oscillatory dynamics.

Study Guide: Modeling Pendulum Collision with a Flying Object

Learning Objectives:

Understand momentum and energy transfer during a pendulum-object collision.
Analyze changes in angular displacement $θ$ , velocity $ω$ , and acceleration $α$ due to the collision.
Validate the conservation laws using experimental data and theoretical predictions.

Step-by-Step Guide:

Setup and Calibration:
- Import the video of the pendulum-object collision into Tracker.
- Calibrate the scale using visible references for accurate motion tracking.
Tracking Motion:
- Track the motion of both the pendulum and the flying object frame by frame.
- Focus on their positions and velocities during the collision.
Collision Modeling:
- Analyze the pre-collision and post-collision phases.
- Apply the conservation of angular momentum: $Linitial=Lfinal,L=I\cdotω$ where $I$ is the moment of inertia and $ω$ is the angular velocity.
- For elastic collisions, use: $KEinitial=KEfinal$
Graphical Analysis:
- Plot θ, ω and α\alpha vs. t:
  - Observe changes in motion pre- and post-collision.
  - Analyze the damping effects and energy dissipation after the collision.
Applications:
- Investigate collision dynamics in physics and engineering contexts.
- Study oscillatory systems influenced by external impacts.

Tips for Success:

Ensure accurate tracking of both objects during the collision.
Compare theoretical conservation laws with experimental observations for validation.

FAQ: Pendulum Collision with a Flying Object

1. What happens during the collision?

The pendulum exchanges momentum and energy with the flying object, altering its motion post-collision. The nature of the interaction depends on whether the collision is elastic or inelastic.

2. How is angular momentum conserved?

Angular momentum is conserved during the collision:

$Linitial=Lfinal,L=I\cdotω$

where $II$ is the moment of inertia and $ω\omega$ is angular velocity.

3. How do you identify energy loss during the collision?

Compare the kinetic energy before and after the collision:

$Energy Loss=KEinitial-KEfinal$

Energy loss indicates inelasticity and damping effects.

4. What do the graphs of $ω\omega$ and $α\alpha$ indicate?

Angular velocity $ω$ shows the speed of rotation and any changes due to the collision.
Angular acceleration $α$ highlights the forces during and after the collision.

5. What are the practical applications of this model?

Understanding energy and momentum transfer in collisions.
Designing systems involving impacts, such as safety equipment.
Exploring oscillatory behavior in mechanical systems influenced by external forces.

6. Can this model include external damping forces?

Yes, damping can be included using a force proportional to $ω\omega$ , such as $Fd=-b\cdotω$ , where $b$ is the damping coefficient.

7. What factors influence the pendulum’s motion post-collision?

The mass and velocity of the flying object.
The elasticity of the collision.
External forces like air resistance and friction.

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Details: Parent Category: 02 Newtonian Mechanics; Category: 09 Oscillations; Published: 09 September 2015; Created: 09 September 2015; Last Updated: 27 December 2024; Hits: 4520

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