Arithmetic with
scientific notation
The benefits of scientific notation do not
end with ease of writing and expression of accuracy. Such
notation also lends itself well to mathematical problems of
multiplication and division. Let's say we wanted to know how
many electrons would flow past a point in a circuit carrying
1 amp of electric current in 25 seconds. If we know the
number of electrons per second in the circuit (which we do),
then all we need to do is multiply that quantity by the
number of seconds (25) to arrive at an answer of total
electrons:
(6,250,000,000,000,000,000 electrons per
second) x (25 seconds) =
156,250,000,000,000,000,000 electrons
passing by in 25 seconds
Using scientific notation, we can write the
problem like this:
(6.25 x 1018 electrons per
second) x (25 seconds)
If we take the "6.25" and multiply it by 25,
we get 156.25. So, the answer could be written as:
156.25 x 1018 electrons
However, if we want to hold to standard
convention for scientific notation, we must represent the
significant digits as a number between 1 and 10. In this
case, we'd say "1.5625" multiplied by some power-of-ten. To
obtain 1.5625 from 156.25, we have to skip the decimal point
two places to the left. To compensate for this without
changing the value of the number, we have to raise our power
by two notches (10 to the 20th power instead of 10 to the
18th):
1.5625 x 1020 electrons
What if we wanted to see how many electrons
would pass by in 3,600 seconds (1 hour)? To make our job
easier, we could put the time in scientific notation as
well:
(6.25 x 1018 electrons per
second) x (3.6 x 103 seconds)
To multiply, we must take the two
significant sets of digits (6.25 and 3.6) and multiply them
together; and we need to take the two powers-of-ten and
multiply them together. Taking 6.25 times 3.6, we get 22.5.
Taking 1018 times 103, we get 1021
(exponents with common base numbers add). So, the answer is:
22.5 x 1021 electrons
. . . or more properly . . .
2.25 x 1022 electrons
To illustrate how division works with
scientific notation, we could figure that last problem
"backwards" to find out how long it would take for that many
electrons to pass by at a current of 1 amp:
(2.25 x 1022 electrons) / (6.25 x
1018 electrons per second)
Just as in multiplication, we can handle the
significant digits and powers-of-ten in separate steps
(remember that you subtract the exponents of divided
powers-of-ten):
(2.25 / 6.25) x (1022 / 1018)
And the answer is: 0.36 x 104, or
3.6 x 103, seconds. You can see that we arrived
at the same quantity of time (3600 seconds). Now, you may be
wondering what the point of all this is when we have
electronic calculators that can handle the math
automatically. Well, back in the days of scientists and
engineers using "slide rule" analog computers, these
techniques were indispensable. The "hard" arithmetic
(dealing with the significant digit figures) would be
performed with the slide rule while the powers-of-ten could
be figured without any help at all, being nothing more than
simple addition and subtraction.
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REVIEW:
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Significant digits are representative of
the real-world accuracy of a number.
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Scientific notation is a "shorthand"
method to represent very large and very small numbers in
easily-handled form.
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When multiplying two numbers in scientific
notation, you can multiply the two significant digit
figures and arrive at a power-of-ten by adding exponents.
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When dividing two numbers in scientific
notation, you can divide the two significant digit figures
and arrive at a power-of-ten by subtracting exponents.
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