The card needs to be black so that the signal recorded in PicoScope is sharp due to the light beam being interrupted cleanly. It is also necessary to fix two blobs of Blu-Tack to the card to give it some ballast in order for the card to fall straight.

The output from the Lascells light gate is fed directly into the voltage input and ground of the DrDAQ, from within PicoScope it is immediately possible to see how blocking the light gate effects the voltage levels.

Carrying out the experiment

PicoScope is set up to trigger upon the change in voltage from the light gate, 1000 mV. A pre-trigger is added to show the effect the card has on the light gate in better detail.

Theory

The velocity of the card as it passes through the light gate can be calculated by dividing the distance over the time. The distance is a constant, i.e. the card length does not change, however the speed for it to pass through the light gate will depend on the height. The following equation is used:

Where the length is a constant (10 cm) and the time will vary, depending on the time taken for the card to pass through the light gate.

Results

If this is plotted on a graph the relationship can be seen quite clearly:

Discussion of results

This experiment clearly shows the relationship between acceleration and height fallen. It also demonstrates that the higher the card falls from the greater the final velocity when it passes through the light gate. From the graph it is possible to predict the maximum speed that the card is likely to fall at from the curve of the graph.