Electronics 

Most electrical or electronic circuits use the voltage across the circuit components to perform some task. This includes motors, sensors, speakers, computer chips, LEDs and diode lasers, communications antennas (e.g. in mobile phones), heaters, turbines, and mains electricity delivery to houses and industry.

It is important to know how to control the voltages in these circuits to make the applications work! The simplest circuit to start to understand this is the potential divider, which is made up of two resistors in series. Other circuits may be made of more advanced components but often use the same principles of voltage (i.e. ‘potential’) division. For example: two transistors in opposite high or low resistance states and connected in series are used to define whether a ‘logic gate’ is set to a digital (Boolean) value of 1 or 0, and are a fundamental building block of how a digital computer processor works.

Sensors can be made from a fixed resistor and a component that has a resistance that depends on whatever is being sensed connected, e.g. a thermistor for sensing heat or a light-dependent resistor for sensing light. A voltage applied to the two components in series allows the voltage across the fixed resistor to be a measure of the resistance of the sensing element’s resistance. This approach can avoid some difficulties of just using the single element, such as high power consumption.

Electrical heaters (including room heaters, cookers and hair dryers) use a fixed resistance heating element (e.g. a coil of wire) and a variable resistance transistor in series. The resistance of the transistor then controls how much voltage is across the heating element and, therefore, how much electrical heating is produced!

This experiment allows you to gain a good understanding of the potential divider. It also allows you to reinforce your understanding of Ohm’s law, how resistor coloured bands code for resistance, and how to use digital multimeters (DMMs), which you may have already met in the FlashyScience Ohm’s Law experiment.

Use this experiment to find out more!

​Download the file below for the quick guide for the Potential Divider experiment (requires login) or follow these brief instructions:

To measure resistance:

• On the right-hand Digital Multimeter (DMM) rotate the switch to resistance measurement.
• Click and drag the clips on the wires attached to the right-hand DMM so that they snap to the wires either side of either or both resistors (make sure the power supply is turned off).
• Note the resistance value shown on the DMM screen.

To change a resistor:

• Click the resistor you wish to change to move to the Selection screen.
• Click on the colour band you wish to change.
• Click on the palette colour you wish to select.
• Click on the resistor wire to return to the main screen.

To measure voltage and current:

• Turn on the power supply (right hand side of screen) and turn the dial to set the voltage.
• To measure current through the resistor – turn the left-hand DMM dial to DC current.
• To measure the voltage across the resistor – turn the right-hand DMM dial to DC voltage.
• NOTE: the output voltage of the power supply is also shown on its display.

Download the file below for full instructions for the Potential Divider experiment (requires log in).

Download the file below for activities for the Potential Divider experiment (requires login).

• ACTIVITY 1: Investigate how the resistances of resistors in series combine
• ACTIVITY 2: Investigate how the current in a potential divider is controlled
• ACTIVITY 3: Explore how voltage in a potential divider depends on the resistor values
• ACTIVITY 4: Consider the voltage ratios across resistors in a potential divider
• ACTIVITY 5: Achieve certain voltages by changing the resistor values
• ACTIVITY 6: Explore power consumption in a potential divider
• ACTIVITY 7: Achieving particular property values in potential dividers
• ACTIVITY 8: Design a potential divider heating element
• ACTIVITY 9: Design a volume control element
• ACTIVITY 10: Design a sensor circuit

(Available as separate downloads or all activities)

Download the file below for the background science behind the Potential Divider experiment (requires log in).

Electronic materials are crucial to our life today, and electrical ‘resistivity’ tells us how good or poor a material is at conducting electricity.

We use materials with low electrical resistivity to transmit electrical power from generators, across grid distribution networks, and to homes and workplaces for use. Designers of electrical devices rely on knowing the resistivity of wire used in order to calculate the resistance of components.

These devices range in size from enormous machines such as wind turbines or industrial lifting equipment; motors or engines in electric vehicles and all-new electric aircraft; consumer products such as washing machines, hair dryers and ovens; and the nanoscale components within the computer chips found in smart devices, laptops, and mobile phones.  

In fact, modern computing is based on controlling the resistivity of semiconductor materials in a type of transistor (known as ‘field effect transistors’ using ‘CMOS’ technology).

Measuring electrical resistivity helps us to understand the properties of materials, to monitor manufacturing processes, and to select the best material for an application.

Use this experiment to find out more!

Download the file below for the quick guide for the Resistivity of a Wire experiment (requires login) or follow these brief instructions:

1. Click on the right hand wire post to move to the Select Wire screen.
2. Open the micrometer by dragging the thumbwheel down.
3. Choose a material and drag the unlabelled wire into the micrometer.
4. Close the micrometer and measure the wire's width.
5. Click on the wire while it's in the micrometer to return to the main screen.
6. Click on the switch to turn it on.
7. Measure voltage and current for a variety of contact positions on the wire.
8. Calculate resistance for each contact position. 
9. Plot resistance vs contact position and calculate the gradient of a line of best fit.
10. Multiply the line's gradient by the wire's cross-sectional area to obtain the wire's electrical resistivity.

Download the file below for full instructions for the Resistivity of a Wire experiment (requires log in).

Download the file below for activities for the Resitivity of a Wire experiment (requires login).

• QUICK ACTIVITIES: 5 quick activities to try
• ACTIVITY 1: Different wire lengths

(Available as separate downloads or all activities)

Download the file below for the background science behind the Resitivity of a Wire experiment (requires log in).