A multimeter is an instrument for measuring voltage, current or resistance.
It can tell you the values of different components and what’s going on in different parts of your circuit. Since you can’t see what’s going on inside a circuit or component, a multimeter is essential for understanding its inner workings.
In a circuit, you may have theoretically calculated the volts, amperes and resistance required for its correct operation. In real life, however, there are factors that cannot be anticipated. If one of your components fails, it can take hours to figure out where the problem lies, and the multimeter will save you a lot of time!
The multimeter is made up of several parts, which we’ll describe below to help you understand how to use it.
Alligator sockets can be very useful in a circuit for securing probes, so you don’t have to hold them while taking measurements. They can also free up your hands for other manipulations (without power, of course!).
When measuring a value, it may be negative. This is not serious, the value is correct, but the problem is that the red and black probes have been reversed in the circuit measurement. In fact, to get a positive value, you should always put the red probe on the positive side of your circuit and the black probe on the negative side.
Measuring voltage is very useful in a project to measure the voltage of a battery or the current flowing through a component. Voltage is measured in volts.
To measure voltage, you first need to make sure that the probes are plugged into the right sockets. These sockets should be labelled V for volts in the case of the red probe, and COM for ground in the case of the black probe.
You also need to turn the dial to direct current (DC), which can be represented by a V sign with a line above it.
You may have the right voltage but not enough current to light a led, for example. In this case, you need to change the dial to the correct rating: A,mA (milli-Ampere) or ⴗA (micro-Ampere).
Intensity is measured in series, i.e. the multimeter must be placed in the continuity of the components, as if the multimeter were one more component in your circuit.
Here’s an example just below:
The multimeter can also be used to measure the value of a resistor.
We’ve done a course to determine the value with the colors of the bands and we have an Arduino factory application that gives the value of the resistor.
However, if the resistance bands are a little faded, you can use a multimeter to determine its value.
To do this, set the knob to ohm or Ω and place a probe on each resistor leg.
Here’s an example just below:
Some multimeters have a continuity function. You can see it on the thumbwheel, a function characterized by a loudspeaker symbol.
It’s a continuity tester that lets you test your circuit to see if there’s a burnt-out component or a disconnected wire. The multimeter will send a small current to the red probe, and if the black probe receives the small current, then the circuit is closed and the multimeter will beep.
Here’s an example:
When testing continuity, always disconnect all power sources connected to your circuit to avoid false beeps.