Overview of key terms, equations, and skills for simple pendulums, including how to analyze the forces on the mass.
|Simple pendulum||A mass suspended from a light string that can oscillate when displaced from its rest position.|
|Equation||Symbols||Meaning in words|
|is period, is pendulum length, and is the acceleration due to gravity||The pendulum’s period is proportional to the square root of the pendulum’s length and inversely proportional to the square root of|
Analyzing the forces on a simple pendulum
An object is a simple harmonic oscillator when the restoring force is directly proportional to displacement.
For the pendulum in Figure 1, we can use Newton's second law to write an equation for the forces on the pendulum. The only force responsible for the oscillating motion of the pendulum is the -component of the weight, so the restoring force on a pendulum is:
For angles under about , we can approximate as and the restoring force simplifies to:
Thus, simple pendulums are simple harmonic oscillators for small displacement angles.
Często spotykane błędy i nieporozumienia
Sometimes people think that a pendulum’s period depends on the displacement or the mass. Increasing the amplitude means that there is a larger distance to travel, but the restoring force also increases, which proportionally increases the acceleration. This means the mass can travel a greater distance at a greater speed. These attributes cancel each other, so amplitude has no effect on period. The pendulum’s inertia resists the change in direction, but it’s also the source of the restoring force. As a result, the mass cancels out too.
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For deeper explanations, see our video introducing pendulums.
To check your understanding and work toward mastering these concepts, check out the exercise on period and frequency of simple pendulums.