Introduction to Logarithms
In its simplest form, a
logarithm answers the question:
How many of one number do we multiply to get another number?
Example: How many 2s do we multiply to get 8?
Answer: 2 x 2 x 2 = 8, so we needed to multiply 3 of the 2s to get 8
So the logarithm is 3
How to Write it
We write "the number of 2s we need to multiply to get 8 is 3" as:
log2(8)
= 3
So these two things are the
same:
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The number we are multiplying is called the "base", so
we can say:
·
"the logarithm of 8
with base 2 is 3"
·
or "log base 2 of 8
is 3"
·
or "the base-2 log
of 8 is 3"
Notice
we are dealing with three numbers:
·
the base: the
number we are multiplying (a "2" in the example above)
·
how many times to use it
in a multiplication (3 times, which is the logarithm)
·
The number we want to get
(an "8")
More
Examples
Example: What is log5(625) ... ?
We are
asking "how many 5s need to be multiplied together to get 625?"
5 × 5 × 5
× 5 = 625, so we need 4 of the 5s
Answer: log5(625) = 4
Example: What is log2(64) ... ?
We are
asking "how many 2s need to be multiplied together to get 64?"
2 × 2 × 2
× 2 × 2 × 2 = 64, so we need 6 of the 2s
Answer: log2(64) = 6
Exponents
Exponents and Logarithms
are related, let's find out how?
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The exponent says how
many times to use the number in a multiplication.
In
this example: 23 = 2 × 2 × 2 = 8
(2 is used 3 times in a multiplication to get 8)
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So a logarithm answers a
question like this:
In this way:
The
logarithm tells us what the exponent is!
In that example the
"base" is 2 and the "exponent" is 3:
So the logarithm answers
the question:
What exponent do we need
(for one number to become another number) ?
(for one number to become another number) ?
The general case
is:
Example: What is log10(100) ... ?
102 = 100
So an
exponent of 2 is needed to make 10 into 100, and:
log10(100) = 2
Example: What is log3(81) ... ?
34 = 81
So an
exponent of 4 is needed to make 3 into 81, and:
log3(81) = 4
Common
Logarithms: Base 10
Sometimes a logarithm is
written without a base, like this:
log(100)
This usually means
that the base is really 10.
It is called a "common
logarithm". Engineers love to use it.
On a calculator it is the
"log" button.
It is how many times we
need to use 10 in a multiplication, to get our desired number.
Example: log(1000)
= log10(1000) = 3
Natural
Logarithms: Base "e"
Another base that is often
used is e(Euler's Number) which is about
2.71828.
This is called a
"natural logarithm". Mathematicians use this one a lot.
On a calculator it is the
"ln" button.
It is how many times we
need to use "e" in a multiplication, to get our desired number.
Example: ln(7.389) = loge(7.389) ≈ 2
Because 2.718282 ≈ 7.389
But
Sometimes There Is Confusion!
Mathematicians use
"log" (instead of "ln") to mean the natural logarithm. This
can lead to confusion:
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So, be careful when you
read "log" that you know what base they mean!
Logarithms
Can Have Decimals
All of our examples have
used whole number logarithms (like 2 or 3), but logarithms can have decimal
values like 2.5, or 6.081, etc.
Example:
what is log10(26) ... ?
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Get
your calculator, type in 26 and press log
Answer
is: 1.41497...
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The logarithm is saying that 101.41497... =
26
(10 with an exponent of 1.41497... equals 26)
(10 with an exponent of 1.41497... equals 26)
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This
is what it looks like on a graph:
See
how nice and smooth the line is.
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Read Logarithms Can Have Decimals to find out more.
Negative
Logarithms
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−
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Negative? But logarithms deal with multiplying.
What could be the opposite of multiplying? Dividing! |
A negative logarithm means how many times to divide by
the number.
We could have just one
divide:
Example: What is log8(0.125) ?
Well, 1 ÷ 8 =
0.125,
So log8(0.125) = −1
Or many divides:
Example: What is log5(0.008) ?
1 ÷ 5 ÷
5 ÷ 5 = 5−3,
So log5(0.008) = −3
It All
Makes Sense
Multiplying and Dividing
are all part of the same simple pattern.
Let us look at some Base-10
logarithms as an example:
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Number
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How
Many 10s
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Base-10
Logarithm
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..
etc..
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1000
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1 × 10 × 10 × 10
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log10(1000)
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= 3
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100
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1 × 10 × 10
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log10(100)
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= 2
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10
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1 × 10
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log10(10)
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= 1
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1
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1
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log10(1)
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= 0
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0.1
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1 ÷ 10
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log10(0.1)
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= −1
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0.01
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1 ÷ 10 ÷ 10
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log10(0.01)
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= −2
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0.001
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1 ÷ 10 ÷ 10 ÷ 10
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log10(0.001)
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= −3
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..
etc..
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Looking at that table, see
how positive, zero or negative logarithms are really part of the same (fairly
simple) pattern.
The
Word
"Logarithm" is a
word made up by Scottish mathematician John Napier (1550-1617), from the Greek
word logos meaning "proportion, ratio or word"
and arithmos meaning "number", ... which together
makes "ratio-number" !
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