What are
"series" and "parallel" circuits?
Circuits
consisting of just one battery and one load resistance are very simple to
analyze, but they are not often found in practical applications. Usually, we
find circuits where more than two components are connected together.
There are two
basic ways in which to connect more than two circuit components: series
and parallel. First, an example of a series circuit:
Here, we have
three resistors (labeled R1, R2, and R3),
connected in a long chain from one terminal of the battery to the other. (It
should be noted that the subscript labeling -- those little numbers to the
lower-right of the letter "R" -- are unrelated to the resistor values
in ohms. They serve only to identify one resistor from another.) The defining
characteristic of a series circuit is that there is only one path for electrons
to flow. In this circuit the electrons flow in a counter-clockwise direction,
from point 4 to point 3 to point 2 to point 1 and back around to 4.
The equivalent
resistance of any number of resistors connected in series the sum of the
individual resistances.
For N resistors in series,
To determine the
voltage across each resistor,
Now, let's look
at the other type of circuit, a parallel configuration:
Again, we have
three resistors, but this time they form more than one continuous path for
electrons to flow. There's one path from 8 to 7 to 2 to 1 and back to 8 again.
There's another from 8 to 7 to 6 to 3 to 2 to 1 and back to 8 again. And then
there's a third path from 8 to 7 to 6 to 5 to 4 to 3 to 2 to 1 and back to 8
again. Each individual path (through R1, R2, and R3)
is called a branch.
The defining
characteristic of a parallel circuit is that all components are connected
between the same set of electrically common points. Looking at the schematic
diagram, we see that points 1, 2, 3, and 4 are all electrically common. So are
points 8, 7, 6, and 5. Note that all resistors as well as the battery are
connected between these two sets of points.
As for a parallel
circuit, the equivalent resistance of two parallel resistors is equal to the
product of their resistances divided by their sum,
Or in general,
To get the
current in a parallel circuit, we may use,
And, of course,
the complexity doesn't stop at simple series and parallel either! We can have
circuits that are a combination of series and parallel, too:
In this circuit,
we have two loops for electrons to flow through: one from 6 to 5 to 2 to 1 and
back to 6 again, and another from 6 to 5 to 4 to 3 to 2 to 1 and back to 6
again. Notice how both current paths go through R1 (from point 2 to
point 1). In this configuration, we'd say that R2 and R3
are in parallel with each other, while R1 is in series with the
parallel combination of R2 and R3.
The basic idea of a "series"
connection is that components are connected end-to-end in a line to form a
single path for electrons to flow:
The basic idea of a
"parallel" connection, on the other hand, is that all components are
connected across each other's leads. In a purely parallel circuit, there are
never more than two sets of electrically common points, no matter how many
components are connected. There are many paths for electrons to flow, but only
one voltage across all components:
Series and
parallel resistor configurations have very different electrical properties.
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