Simple Pendulum (g), Inclined Plane Motion

11th Grade Physics: Simple Pendulum & Inclined Plane

Interactive Experiments for Determining 'g' and Studying Motion

Explore fundamental physics concepts through interactive experiments. Determine acceleration due to gravity using a simple pendulum and study motion on an inclined plane.

Help & Instructions

▼

How to Use This Learning Tool:

Simple Pendulum Experiment: Adjust pendulum length and measure time period to calculate 'g'
Inclined Plane Experiment: Change the angle of inclination and observe motion parameters
Use the data tables to record measurements and perform calculations
Compare your calculated values with theoretical predictions
Use the reset buttons to restart experiments

Learning Objectives:

Understand the relationship between pendulum length and time period
Calculate acceleration due to gravity using pendulum data
Analyze motion on an inclined plane using Newton's laws
Determine acceleration components on an inclined plane
Apply trigonometry to resolve forces on an incline

Experiment 1: Simple Pendulum - Determining 'g'

Adjust the pendulum length and measure the time period to calculate acceleration due to gravity.

Pendulum Length

1.0 m

Time Period

2.01 s

Calculated 'g'

9.80 m/s²

Oscillations

Length: 1.0 m

Period: 2.01 s

g = 9.80 m/s²

Pendulum Length: 1.0 m

Calculations:

Time Period Formula: T = 2π√(L/g)

Rearranged for g: g = 4π²L/T²

g = 4 × π² × 1.0 / (2.01)² = 9.80 m/s²

Experiment 2: Inclined Plane Motion

Adjust the angle of inclination and observe the motion of a block on the plane.

Inclination Angle

30°

Acceleration

4.90 m/s²

Time to Bottom

1.43 s

Final Velocity

7.00 m/s

Angle: 30°

Acceleration: 4.90 m/s²

Velocity: 0.00 m/s

Inclination Angle: 30°

Force Analysis:

Component of gravity along incline: mg sin(θ)

Acceleration: a = g sin(θ)

a = 9.8 × sin(30°) = 4.90 m/s²

Physics Concepts:

These experiments demonstrate fundamental principles of classical mechanics. The simple pendulum shows simple harmonic motion, while the inclined plane illustrates vector resolution of forces and kinematics.

Detailed Physics Explanations

Simple Pendulum:

The motion of a simple pendulum is an example of simple harmonic motion for small angles (<15°).

Time Period: T = 2π√(L/g) where L is length and g is acceleration due to gravity
The period is independent of the mass of the bob
The period is approximately independent of amplitude for small angles
By measuring T for different L values, we can calculate g = 4π²L/T²

Inclined Plane:

Motion on an inclined plane demonstrates vector resolution and Newton's second law.

Gravity force (mg) resolves into two components: mg sin(θ) parallel to the plane and mg cos(θ) perpendicular
Acceleration down the plane: a = g sin(θ) (assuming no friction)
Time to travel distance d: t = √(2d/a)
Final velocity: v = √(2ad)

Real-world Applications:

Understanding these concepts is essential for:

Engineering: Designing structures, roller coasters, and transportation systems
Geophysics: Measuring gravity variations to study Earth's structure
Sports: Analyzing projectile motion and optimizing performance
Safety: Designing road gradients and safety systems