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Experiment 17: Set Your Tone


162 Chapter 4


Experiment 17: Set Your Tone
I’m going to show you two other ways in which the 555 timer can be used.
You will need the same items as in Experiment 16, plus:


  • Additional 555 timer chip. Quantity: 1.

  • Miniature loudspeaker. Quantity: 1.

  • 100K linear potentiometer. Quantity: 1.


Procedure
Leave the components from Experiment 16 where they are on the bread-
board, and add the next section below them, as shown in Figures 4-21 and
4-22. Resistor R2 is inserted between pins 6 and 7, instead of the jumper wire
that shorted the pins together in the previous circuit, and there’s no external
input to pin 2 anymore. Instead, pin 2 is connected via a jumper wire to pin


  1. The easiest way to do this is by running the wire across the top of the chip.
    I have omitted the smoothing capacitor from the schematic in Figure 4-22,
    because I’m assuming that you’re running this circuit on the same breadboard
    as the first, where the previous smoothing capacitor is still active.
    A loudspeaker in series with a 100Ω resistor (R3) has been substituted for the
    LED to show the output from the chip. Pin 4, the reset, is disabled by connect-
    ing it to the positive voltage supply, as I’m not expecting to use the reset func-
    tion in this circuit.
    Now what happens when you apply power? Immediately, you should hear
    noise through the loudspeaker. If you don’t hear anything, you almost cer-
    tainly made a wiring error.
    Notice that you don’t have to trigger the chip with a pushbutton anymore.
    The reason is that when C1 charges and discharges, its fluctuating voltage is
    connected via a jumper wire across the top of the chip to pin 2, the trigger. In
    this way, the 555 timer now triggers itself. I’ll describe this in more detail in the
    next section “Theory: Inside the 555 timer: astable mode,” if you want to see
    exactly what is going on.
    In this mode, the chip is “astable,” meaning that it is not stable, because it flips
    to and fro endlessly, sending a stream of pulses for as long as the power is
    connected. The pulses are so rapid that the loudspeaker reproduces them as
    noise.
    In fact, with the component values that I specified for R1, R2, and C1, the 555
    chip is emitting about 1,500 pulses per second. In other words, it creates a 1.5
    KHz tone.
    Check the table on page 166 to see how different values for R2 and C1 can create
    different pulse frequencies with the chip in this astable mode. Note that the
    table assumes a fixed value of 1K for R1!

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