6.2.8 Required Practical: Investigating SHM | AQA A Level Physics Revision Notes 2017 (2024)

Revision Note

Test Yourself

Author

Ashika

Expertise

Physics Project Lead

Required Practical: Investigating SHM

Equipment List

Resolution of measuring equipment:
- Stopwatch = ±0.01 s
- Metre Ruler = ±1 mm

SHM in a Mass-Spring System

This experiment aims to calculate the spring constant of a spring in a mass-spring system
This is done by investigating how the time period of the oscillations varies with the mass
- This is just one example of how this required practical might be carried out

Variables

Independent variable = mass,m
Dependent variable = time period,T
Control variables:
- Spring constant,k
- Number of oscillations

Method

The setup of apparatus to detect oscillations of a mass-spring system

Analysing the Results

Obtain an equation for the spring constant,k
Then plot a suitable graph to obtain a value for k

Start with the time period of a mass-spring system from the equation:

Where:
- T= time period (s)
- m = mass (kg)
- k = spring constant (N m^–1)

Squaring both sides of the equation gives:

Comparing this to the equation of a straight line: y = mx
- y = T²
- x = m
- Gradient = 4π²/ k
The spring constant, k, is therefore equal to:

The graph ofT² against mass,m should look like this:
- WhereT² andmare directly proportional to each other
- The graph is a straight line with a positive gradient

The spring constant obtained can be compared with that according to Hooke's law
- Where k is found from the gradient of a force Fextension xgraph

SHM in a Simple Pendulum

This experiment aims to calculate the acceleration due to gravity of a simple pendulum
This is done by investigating how the time period of oscillations vary with length
- This is just one example of how this required practical might be carried out

Variables

Independent variable = length, L
Dependent variable = time period,T
Control variables:
- Mass of pendulum bob,m
- Number of oscillations

Method

Set up the apparatus, with the length of the pendulum at 0.2 m
Make sure the pendulum hangs vertically downwards at equilibrium and inline directly in front of the needle marker
Pull the pendulum to the side at a very small angle then let go. The pendulum will begin to oscillate
Start the stopwatch when the pendulum passes the needle marker in its equilibrium. One complete oscillation occurs when the pendulum passes through the equilibrium, to one maximum and then the other, and back to the equilibrium again (not just from side to side)
Stop the stopwatch after 10 complete oscillations and record the total time. Divide the time by 10 to obtain the time period (which is the mean)
Adjust the string to increase the length of the pendulum and the wooden block. Repeat the above for 8-10 readings. The ruler is used to measure the string. Ensure it is measured from the wooden blocks to the centre of mass of the bob.

Oscillations should be counted as follows:

An example table might look like this:

Analysing the Results

Obtain an equation for theacceleration due to gravity, g
Then plot a suitablegraphto obtain a value for g

The time period of a simple pendulum is given by:

Where:
- T = time period (s)
- L = length of the pendulum (m)
- g = acceleration due to gravity (m s^–2)
Squaring both sides of the equation gives

Comparing this to the equation of a straight line: y = mx + c
- y = T²
- x = L
- gradient m = 4π²/ g
- c = 0
The acceleration due to gravity is equal to:

The graph ofT²against length,L should look like this:
- WhereT²andL aredirectly proportionalto each other
- The graph is astraight linewith apositive gradient

The accuracy of the experiment can be determined by comparing the obtained value ofgto the accepted value of acceleration due to gravity,g = 9.81 m s⁻²

Evaluating the Experiments

Systematic Errors:

Reduce parallax error by viewing the marker at eye level

Random Errors:

Record the time taken for 10 full oscillations, then divide by 10 for one period, to reduce random errors
For the simple pendulum, the oscillations may not completely go from side to side, and the object may move in a circle. Therefore, keep the amplitudes of oscillation relatively small (only a few cm) and repeat any readings that take a different trajectory
The equation for the time period of a pendulum bob only works for small angles, so make sure the pendulum is not pulled too far out to the side for the oscillation
For the mass-spring system, the oscillations may not stay completely vertical. Therefore, keep the amplitudes relatively small (only a few cm) and repeat the readings making sure they are vertical
When setting an oscillation in motion make sure the mass is pulled to the side by the same angle every time
A motion tracker and data logger could provide a more accurate value for the time period and reduce the random errors in starting and stopping the stopwatch (due to reflex times)

Safety Considerations

Place a soft surface directly below the equipment to reduce the damage caused by a falling pendulum or spring
Only pull down the mass and spring system a few centimetres for the oscillations, as larger oscillations could cause the masses to fall off and damage the equipment
The wooden blocks must be tightly clamped together to hold the string for the pendulum in place, otherwise, the pendulum may dislodge during oscillations and fall off

Worked example

A student investigates the relationship between the time period and the mass of a mass-spring system that oscillates with simple harmonic motion. They obtain the following results: