Electronics For Kids For Dummies. Shamieh Cathleen
electric current gives your LED the energy it needs to light up. And the 9-volt battery provides the energy (voltage) needed to push the current through the circuit.
Batteries are one type of voltage source, providing voltage to force current to flow through circuit components.
You may be familiar with LEDs if you have an LED flashlight or use LED bulbs in your home. An LED, or light-emitting diode, is a device made of a special material known as a semiconductor. A diode is the simplest type of semiconductor device (meaning, component).
Diodes and bicycle tires
Have you ever pumped air into a bicycle tire? The tire contains a valve that allows air to flow into the tire, but not out of the tire. You have to apply enough pressure to the pump to force air through the valve.
Seeing light from LEDs
LEDs also come in several shapes and sizes. The LEDs you use in the projects in this book have round, domed cases that are either 5 mm (millimeters) or 3 mm high.
There are two types of LEDs:
✓ Diffused LEDs have colored plastic cases (like tinted windows) to diffuse, or spread out, the light so it’s easier to see. The color of the plastic case is usually the same as the color of the light.
✓ Clear LEDs have clear plastic cases but still emit colored light.
All the LEDs in Figure 2-3 are clear 5 mm LEDs. Figure 2-4 shows an assortment of LEDs, including a 5 mm clear LED that gives off an orange light. (It’s the unlit version of the LED that is second from the left in Figure 2-3.)
Examine your LED
Take a good look at your LED and compare it to the LEDs shown in Figure 2-5. The actual semiconductor diode is tiny and is on a piece of metal inside the plastic case. The two stiff wires attached to the plastic case are leads that enable you to connect the tiny diode to a circuit.
✓ Compare the lengths of the leads. The shorter lead is the cathode (negative side) and the longer lead is the anode (positive side). (See Figure 2-5, left.)
✓ Peek inside the plastic case. The lead attached to the larger piece of metal inside the case is the cathode (negative side); the lead attached to the smaller piece of metal is the anode (positive side). (See Figure 2-5, left.)
✓ Look (or feel) for a flat edge on the plastic case. This flat edge is on the cathode (negative side) of the LED. (See Figure 2-5, right.)
Look at the leads of your LED. Can you tell which one is the shorter lead? Now look inside the case of your LED. (You may need to shine a flashlight on the case to see inside better.) Can you spot the larger and smaller pieces of metal? Finally, run your finger around the bottom edge of the plastic case. Can you feel a flat edge?
Orienting an LED in a circuit
To conduct current and emit light, most LEDs require between 2.0 and 3.4 volts to be applied across the leads. The exact voltage needed depends on the color of the LED. A 9-volt battery is powerful enough to push current through any LED, but a 1.5-volt battery, such as an AA or AAA battery, isn’t strong enough. For this reason, you use a 9-volt battery rather than an AA or AAA battery for your LED circuit.
To limit the current that flows from your 9-volt battery through your LED, you insert a resistor in your circuit. Resistors slow down current, like a kink in a hose slows the flow of water.
Figure 2-6 shows you a variety of resistors. Every resistor has two leads, and it doesn’t matter which way you insert a resistor into a circuit. Current flows either way through a resistor. (Resistors are not semiconductors, so they are not picky.)
Resistors don’t require a minimum voltage like LEDs