Experiment 21: Race to Place
210 Chapter 4
1 8
555
1 8
555
74HC32
5V DC regulated
10K
10K
OR2
OR3
OR1
10K
S2
S3
S1
330
0.01
0.01
330
Figure 4-95. Applying the simplified schematic to a breadboard inevitably entails
a wiring layout that is less intuitively obvious and appears more complex. The
connections are the same, though.
Figure 4-96. The quiz schematic applied to a
breadboard, to test the concept prior to full-scale
implementation.
Enhancements
After you breadboard the circuit, if you proceed to build a permanent version,
I suggest that you expand it so that at least four players can participate. This
will require an OR gate capable of receiving four inputs. The 74HC4078 is the
obvious choice, as it allows up to eight. Just connect any unused inputs to
negative ground.
Alternatively, if you already have a couple of 74HC32 chips and you don’t want
to bother ordering a 74HC4078, you can gang together three of the gates in-
side a single 74HC32 so that they function like a four-input OR. Look at the
simple logic diagram in Figure 4-97 showing three ORs, and remember that
the output from each OR will go high if at least one input is high.
And while you’re thinking about this, see if you can figure out the inputs and
output of three ANDs in the same configuration.
For a four-player game, you’ll also need two additional 555 timers, of course,
and two more LEDs, and two more pushbuttons.
As for creating a schematic for the four-player game—I’m going to leave that
to you. Begin by sketching a simplified version, just showing the logic symbols.
Then convert that to a breadboard layout. And here’s a suggestion: pencil, pa-
per, and an eraser can still be quicker, initially, than circuit-design software or
graphic-design software, in my opinion.
Figure 4-97. Although a four-input OR gate
is not manufactured, its functionality can
be achieved easily by linking three 2-input
OR gates together.