Druyd:Knowledge

Pendulum Swing

Storyboard

In the case of a pendulum it is gravity that generates a torque opposite to the mass leaving the resting point. However, the torque is not proportional to the angle, there being a non-linear relationship which makes the movement more complex.Since the torque is not proportional to the angle, the oscillation frequency depends on the amplitude, which makes it difficult to apply it to mark the passage on a clock. However, the effect is minimal if the angle is small which leads to the application of the pendulum on clocks is achieved with long bars.

>Model

ID:(1426, 0)

Calculation of the Potential Energy of the Pendulum

Description

When a pendulum of length $l$ is deflected at an angle $\theta$, the mass gains height, which is calculated as

$l - l \cos\theta = l (1 - \cos\theta)$

this is associated with the gain in gravitational potential energy.

ID:(1239, 0)

Pendulum Swing

Model

In the case of a pendulum it is gravity that generates a torque opposite to the mass leaving the resting point. However, the torque is not proportional to the angle, there being a non-linear relationship which makes the movement more complex. Since the torque is not proportional to the angle, the oscillation frequency depends on the amplitude, which makes it difficult to apply it to mark the passage on a clock. However, the effect is minimal if the angle is small which leads to the application of the pendulum on clocks is achieved with long bars.

Variables

Symbol

Text

Variable

Value

Units

Calculate

MKS Value

MKS Units

$m_g$

m_g

Gravitational mass

$h$

Height in Case Pendulum

$L$

Pendulum Length

$V$

Potential Energy Pendulum

$V$

Potential Energy Pendulum, for small Angles

$\theta$

theta

Swing angle

rad

Calculations

Equation

Number

First, select the equation:

, then, select the variable:

Symbol

Equation

Solved

Translated

Calculations

Symbol

Equation

Solved

Translated

Variable

Given

Calculate

Target :

Equation

To be used

Equations

$ U = m g L (1-\cos \theta )$

U = m * g * L *(1-cos( theta ))

(ID 4513)

$ V =\displaystyle\frac{1}{2} m_g g L \theta ^2$

V = m_g * g * L * theta ^2/2

The gravitational potential energy of a pendulum with mass m, suspended from a string of length L and deflected by an angle \theta is given by

$ U = m g L (1-\cos \theta )$

where g is the acceleration due to gravity.

For small angles, the cosine function can be approximated using a Taylor series expansion up to the second term

$\cos\theta\sim 1-\displaystyle\frac{1}{2}\theta^2$

This approximation leads to the simplification of the potential energy to

$ V =\displaystyle\frac{1}{2} m_g g L \theta ^2$

(ID 4514)

$ h = L (1-\cos \theta )$

h = L * (1-cos( theta ))

(ID 4523)

Examples

Calculation of the Potential Energy of the Pendulum

When a pendulum of length $l$ is deflected at an angle $\theta$, the mass gains height, which is calculated as

$l - l \cos\theta = l (1 - \cos\theta)$

this is associated with the gain in gravitational potential energy.

(ID 1239)

ID:(1426, 0)