3.3 Logarithmen

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{{Info|
{{Info|
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'''Content:'''
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'''Contents:'''
* Logarithms
* Logarithms
* Fundamental Laws of Logarithms
* Fundamental Laws of Logarithms
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'''Learning outcomes:'''
'''Learning outcomes:'''
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After this section, you will have learned :
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After this section, you will have learned:
*The concepts of base and exponent.
*The concepts of base and exponent.
*The meaning of the notation <math>\ln</math>, <math>\lg</math>, <math>\log</math> and <math>\log_{a}</math>.
*The meaning of the notation <math>\ln</math>, <math>\lg</math>, <math>\log</math> and <math>\log_{a}</math>.
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{{Fristående formel||<math>\begin{align*}
{{Fristående formel||<math>\begin{align*}
10^3 &= 10 \cdot 10 \cdot 10 = 1000\,,\\
10^3 &= 10 \cdot 10 \cdot 10 = 1000\,,\\
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10^{-2} &= \frac{1}{10 \cdot 10} = \frac{1}{100} = 0{,}01\,\mbox{.}
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10^{-2} &= \frac{1}{10 \cdot 10} = \frac{1}{100} = 0\textrm{.}01\,\mbox{.}
\end{align*}</math>}}
\end{align*}</math>}}
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If one only considers the exponents one can state that
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If one only considers the exponents one can state that
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:::"exponent for 1000 is 3", or
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:::"the exponent for 1000 is 3", or
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:::" exponent for 0,01 is -2".
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:::"the exponent for 0.01 is -2".
This is how logarithms are defined. One formalises this as follows:
This is how logarithms are defined. One formalises this as follows:
:::"''The logarithm'' of 1000 is 3", which is written as <math>\lg 1000 = 3</math>,
:::"''The logarithm'' of 1000 is 3", which is written as <math>\lg 1000 = 3</math>,
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:::"''The logarithm'' of 0,01 is -2", which is written as <math>\lg 0{,}01 = -2</math>.
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:::"''The logarithm'' of 0.01 is -2", which is written as <math>\lg 0\textrm{.}01 = -2</math>.
More generally, one says:
More generally, one says:
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10^{\,\bbox[#AAEEFF,1pt]{\scriptstyle\,5\vphantom{,}\,}}
10^{\,\bbox[#AAEEFF,1pt]{\scriptstyle\,5\vphantom{,}\,}}
= 100\,000</math>.</li>
= 100\,000</math>.</li>
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<li><math>\lg 0{,}0001 = -4\quad</math> because <math>
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<li><math>\lg 0\textrm{.}0001 = -4\quad</math> because <math>
10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,-4\vphantom{,}\,}}
10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,-4\vphantom{,}\,}}
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= 0{,}0001</math>.</li>
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= 0\textrm{.}0001</math>.</li>
<li><math>\lg \sqrt{10} = \frac{1}{2}\quad</math> because <math>
<li><math>\lg \sqrt{10} = \frac{1}{2}\quad</math> because <math>
10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,1/2\,}} = \sqrt{10}</math>.</li>
10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,1/2\,}} = \sqrt{10}</math>.</li>
Zeile 71: Zeile 71:
10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,78\vphantom{,}\,}}
10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,78\vphantom{,}\,}}
= 10^{78}</math>.</li>
= 10^{78}</math>.</li>
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<li><math>\lg 50 \approx 1{,}699\quad</math> because <math>
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<li><math>\lg 50 \approx 1\textrm{.}699\quad</math> because <math>
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10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,1{,}699\,}} \approx 50</math>.</li>
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10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,1\textrm{.}699\,}} \approx 50</math>.</li>
<li><math>\lg (-10)</math> does not exist because <math>
<li><math>\lg (-10)</math> does not exist because <math>
10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,a\vphantom{b,}\,}}</math> can never be -10 regardless of how <math>a</math> is chosen.</li>
10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,a\vphantom{b,}\,}}</math> can never be -10 regardless of how <math>a</math> is chosen.</li>
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</div>
</div>
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In the penultimate example, one can easily understand that <math>\lg 50</math> must lie somewhere between 1 and 2 since <math>10^1 < 50 < 10^2</math>, but to obtain a more precise value of the irrational number <math>\lg 50 = 1{,}69897\ldots</math> one needs in practice, a calculator (or table.)
+
In the penultimate example, one can easily understand that <math>\lg 50</math> must lie somewhere between 1 and 2 since <math>10^1 < 50 < 10^2</math>, but to obtain a more precise value of the irrational number <math>\lg 50 = 1\textrm{.}69897\ldots</math> one needs in practice, a calculator (or table.)
<div class="exempel">
<div class="exempel">
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One deals with logarithms which have other bases in the same way.
One deals with logarithms which have other bases in the same way.
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<div class="exempel">
<div class="exempel">
Zeile 136: Zeile 135:
==The natural logarithms ==
==The natural logarithms ==
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In practice there are two bases that are commonly used for logarithms, 10 and the number <math>e</math> <math>({}\approx 2{,}71828 \ldots\,)</math>. Logarithms using the base ''e'' are called '' natural logarithms'' and one uses the notation ln instead of <math>\log_{\,e}</math>.
+
In practice there are two bases that are commonly used for logarithms, 10 and the number <math>e</math> <math>({}\approx 2\textrm{.}71828 \ldots\,)</math>. Logarithms using the base ''e'' are called '' natural logarithms'' and one uses the notation ln instead of <math>\log_{\,e}</math>.
<div class="exempel">
<div class="exempel">
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<br>
<br>
<br>
<br>
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If we know that <math>35 \approx 10^{\,1{,}5441}</math> and <math>54 \approx 10^{\,1{,}7324}</math> (i.e. <math>\lg 35 \approx 1{,}5441</math> and <math>\lg 54 \approx 1{,}7324</math>) then we can calculate that
+
If we know that <math>35 \approx 10^{\,1\textrm{.}5441}</math> and <math>54 \approx 10^{\,1\textrm{.}7324}</math> (i.e. <math>\lg 35 \approx 1\textrm{.}5441</math> and <math>\lg 54 \approx 1\textrm{.}7324</math>) then we can calculate that
{{Fristående formel||<math>
{{Fristående formel||<math>
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35 \cdot 54 \approx 10^{\,1{,}5441} \cdot 10^{\,1{,}7324}
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35 \cdot 54 \approx 10^{\,1\textrm{.}5441} \cdot 10^{\,1\textrm{.}7324}
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= 10^{\,1{,}5441 + 1{,}7324}
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= 10^{\,1\textrm{.}5441 + 1\textrm{.}7324}
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= 10^{\,3{,}2765}</math>}}
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= 10^{\,3\textrm{.}2765}</math>}}
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and we then know that <math>10^{\,3{,}2765} \approx 1890</math> (i.e. <math>\lg 1890 \approx 3{,}2765</math>) thus we have managed to calculate the product
+
and we then know that <math>10^{\,3\textrm{.}2765} \approx 1890</math> (i.e. <math>\lg 1890 \approx 3\textrm{.}2765</math>) thus we have managed to calculate the product
{{Fristående formel||<math>35 \cdot 54 = 1890</math>}}
{{Fristående formel||<math>35 \cdot 54 = 1890</math>}}
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and this just by adding together exponents <math>1{,}5441</math> and <math>1{,}7324</math>.
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and this just by adding together exponents <math>1\textrm{.}5441</math> and <math>1\textrm{.}7324</math>.
</div>
</div>
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{{Fristående formel||<math>
{{Fristående formel||<math>
a\cdot b = 10^{\textstyle\log a} \cdot 10^{\textstyle\log b}
a\cdot b = 10^{\textstyle\log a} \cdot 10^{\textstyle\log b}
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= \left\{ \mbox{laws of powers} \right\}
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= \left\{ \mbox{laws of exponents} \right\}
= 10^{\,\bbox[#AAEEFF,1pt]{\,\log a+\log b\,}}</math>}}
= 10^{\,\bbox[#AAEEFF,1pt]{\,\log a+\log b\,}}</math>}}
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a\cdot b = 10^{\,\bbox[#AAEEFF,1pt]{\,\log (ab)\,}}\,\mbox{.}</math>}}
a\cdot b = 10^{\,\bbox[#AAEEFF,1pt]{\,\log (ab)\,}}\,\mbox{.}</math>}}
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By exploiting the laws of powers in this way can we obtain the corresponding ''laws of logarithms'':
+
By exploiting the laws of exponents in this way can we obtain the corresponding ''laws of logarithms'':
<div class="regel">
<div class="regel">
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<div class="exempel">
<div class="exempel">
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'''Exempel 8'''
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'''Example 8'''
<ol type="a">
<ol type="a">
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{{Fristående formel||<math>\ln 10^{\lg 5} = \ln 5\,\mbox{.}</math>}}
{{Fristående formel||<math>\ln 10^{\lg 5} = \ln 5\,\mbox{.}</math>}}
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With the help of the logarithm law <math>\ln a^b = b \ln a</math> the left-hand side can written as <math>\lg 5 \cdot \ln 10</math> and the equality becomes
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With the help of the logarithm law <math>\ln a^b = b \ln a</math> the left-hand side can be written as <math>\lg 5 \cdot \ln 10</math> and the equality becomes
{{Fristående formel||<math>\lg 5 \cdot \ln 10 = \ln 5\,\mbox{.}</math>}}
{{Fristående formel||<math>\lg 5 \cdot \ln 10 = \ln 5\,\mbox{.}</math>}}
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{{Fristående formel||<math>
{{Fristående formel||<math>
\lg 5 = \frac{\ln 5}{\ln 10}
\lg 5 = \frac{\ln 5}{\ln 10}
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\qquad (\approx 0{,}699\,,
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\qquad (\approx 0\textrm{.}699\,,
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\quad\text{dvs.}\ 10^{0{,}699} \approx 5)\,\mbox{.}
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\quad\text{dvs.}\ 10^{0\textrm{.}699} \approx 5)\,\mbox{.}
</math>}}</li>
</math>}}</li>
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\log_{\scriptstyle 2} 100 \cdot \lg 2 = 2\,\mbox{.}</math>}}
\log_{\scriptstyle 2} 100 \cdot \lg 2 = 2\,\mbox{.}</math>}}
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Finally dividing by <math>\lg 2</math> gives that
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Finally, dividing by <math>\lg 2</math> gives that
{{Fristående formel||<math>
{{Fristående formel||<math>
\log_{\scriptstyle 2} 100 = \frac{2}{\lg 2}
\log_{\scriptstyle 2} 100 = \frac{2}{\lg 2}
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\qquad ({}\approx 6{,}64\,,
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\qquad ({}\approx 6\textrm{.}64\,,
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\quad\text{that is}\ 2^{6{,}64}\approx 100 )\,\mbox{.}</math>}}
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\quad\text{that is}\ 2^{6\textrm{.}64}\approx 100 )\,\mbox{.}</math>}}
</ol>
</ol>
</div>
</div>
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{{Fristående formel||<math>2 = 10^{\lg 2}</math>}}
{{Fristående formel||<math>2 = 10^{\lg 2}</math>}}
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and then using one of the laws of powers
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and then using one of the laws of exponents
{{Fristående formel||<math>
{{Fristående formel||<math>
2^5 = (10^{\lg 2})^5 = 10^{5\cdot \lg 2}
2^5 = (10^{\lg 2})^5 = 10^{5\cdot \lg 2}
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\quad ({}\approx 10^{1,505}\,)\,\mbox{.}</math>}}
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\quad ({}\approx 10^{1\textrm{.}505}\,)\,\mbox{.}</math>}}
<div class="exempel">
<div class="exempel">
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{{Fristående formel||<math>10 = e^{\ln 10}</math>}}
{{Fristående formel||<math>10 = e^{\ln 10}</math>}}
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and then use the laws of powers
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and then use the laws of exponents
{{Fristående formel||<math>
{{Fristående formel||<math>
10^x = (e^{\ln 10})^x = e^{\,x \cdot \ln 10}
10^x = (e^{\ln 10})^x = e^{\,x \cdot \ln 10}
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\approx e^{2{,}3 x}\,\mbox{.}</math>}}</li>
+
\approx e^{2\textrm{.}3 x}\,\mbox{.}</math>}}</li>
<li> Write <math>e^{\,a}</math> using the base 10.
<li> Write <math>e^{\,a}</math> using the base 10.
Zeile 344: Zeile 343:
e^a = (10^{\lg e})^a
e^a = (10^{\lg e})^a
= 10^{\,a \cdot \lg e}
= 10^{\,a \cdot \lg e}
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\approx 10^{\,0{,}434a}\,\mbox{.}</math>}}
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\approx 10^{\,0\textrm{.}434a}\,\mbox{.}</math>}}
</ol>
</ol>
</div>
</div>

Version vom 11:44, 19. Aug. 2008

 

Vorlage:Vald flik Vorlage:Ej vald flik

 

Contents:

  • Logarithms
  • Fundamental Laws of Logarithms

Learning outcomes:

After this section, you will have learned:

  • The concepts of base and exponent.
  • The meaning of the notation \displaystyle \ln, \displaystyle \lg, \displaystyle \log and \displaystyle \log_{a}.
  • To calculate simple logarithmic expressions using the definition of a logarithm.
  • That logarithms are only defined for positive numbers.
  • The meaning of the number \displaystyle e.
  • To use the laws of logarithms to simplify logarithmic expressions.
  • To know when the laws of logarithms are valid.
  • To express a logarithm in terms of a logarithm with a different base.

Logarithms to the base 10

We often use powers with base \displaystyle 10 to represent large and small numbers, for example,

Vorlage:Fristående formel

If one only considers the exponents one can state that

"the exponent for 1000 is 3", or
"the exponent for 0.01 is -2".

This is how logarithms are defined. One formalises this as follows:

"The logarithm of 1000 is 3", which is written as \displaystyle \lg 1000 = 3,
"The logarithm of 0.01 is -2", which is written as \displaystyle \lg 0\textrm{.}01 = -2.

More generally, one says:

The logarithm of a number \displaystyle y is designated by \displaystyle \lg y and is the exponent in the blue box which satisfies the equality

Vorlage:Fristående formel

Note that \displaystyle y must be a positive number for the logarithm \displaystyle \lg y to be defined, since there is no power of 10 that evaluates to a negative number or for that matter zero .

Example 1

  1. \displaystyle \lg 100000 = 5\quad because \displaystyle 10^{\,\bbox[#AAEEFF,1pt]{\scriptstyle\,5\vphantom{,}\,}} = 100\,000.
  2. \displaystyle \lg 0\textrm{.}0001 = -4\quad because \displaystyle 10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,-4\vphantom{,}\,}} = 0\textrm{.}0001.
  3. \displaystyle \lg \sqrt{10} = \frac{1}{2}\quad because \displaystyle 10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,1/2\,}} = \sqrt{10}.
  4. \displaystyle \lg 1 = 0\quad because \displaystyle 10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,0\vphantom{,}\,}} = 1.
  5. \displaystyle \lg 10^{78} = 78\quad because \displaystyle 10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,78\vphantom{,}\,}} = 10^{78}.
  6. \displaystyle \lg 50 \approx 1\textrm{.}699\quad because \displaystyle 10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,1\textrm{.}699\,}} \approx 50.
  7. \displaystyle \lg (-10) does not exist because \displaystyle 10^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,a\vphantom{b,}\,}} can never be -10 regardless of how \displaystyle a is chosen.

In the penultimate example, one can easily understand that \displaystyle \lg 50 must lie somewhere between 1 and 2 since \displaystyle 10^1 < 50 < 10^2, but to obtain a more precise value of the irrational number \displaystyle \lg 50 = 1\textrm{.}69897\ldots one needs in practice, a calculator (or table.)

Example 2

  1. \displaystyle 10^{\textstyle\,\lg 100} = 100
  2. \displaystyle 10^{\textstyle\,\lg a} = a
  3. \displaystyle 10^{\textstyle\,\lg 50} = 50


Different bases

One can imagine logarithms, which use a base other than 10 (except 1!). One must clearly indicate which number is used as a base for a logarithm. If one uses a base such as 2 one uses the notation \displaystyle \log_{\,2} for a "base-2 logarithm".

Example 3

  1. \displaystyle \log_{\,2} 8 = 3\quad because \displaystyle 2^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,3\vphantom{,}\,}} = 8.
  2. \displaystyle \log_{\,2} 2 = 1\quad because \displaystyle 2^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,1\vphantom{,}\,}} = 2.
  3. \displaystyle \log_{\,2} 1024 = 10\quad because \displaystyle 2^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,10\vphantom{,}\,}} = 1024.
  4. \displaystyle \log_{\,2}\frac{1}{4} = -2\quad because \displaystyle 2^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,-2\vphantom{,}\,}} = \frac{1}{2^2} = \frac{1}{4}.

One deals with logarithms which have other bases in the same way.

Example 4

  1. \displaystyle \log_{\,3} 9 = 2\quad because \displaystyle 3^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,2\vphantom{,}\,}} = 9.
  2. \displaystyle \log_{\,5} 125 = 3\quad because \displaystyle 5^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,3\vphantom{,}\,}} = 125.
  3. \displaystyle \log_{\,4} \frac{1}{16} = -2\quad because \displaystyle 4^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,-2\vphantom{,}\,}} = \frac{1}{4^2} = \frac{1}{16}.
  4. \displaystyle \log_{\,b} \frac{1}{\sqrt{b}} = -\frac{1}{2}\quad as \displaystyle b^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,-1/2\,}} = \frac{1}{b^{1/2}} = \frac{1}{\sqrt{b}} (if \displaystyle b>0 and \displaystyle b\not=1).

If the base 10 is used, one rarely writes \displaystyle \log_{\,10}, but as we have previously seen one uses the notation lg, or simply log, which appears on many calculators.


The natural logarithms

In practice there are two bases that are commonly used for logarithms, 10 and the number \displaystyle e \displaystyle ({}\approx 2\textrm{.}71828 \ldots\,). Logarithms using the base e are called natural logarithms and one uses the notation ln instead of \displaystyle \log_{\,e}.

Example 5

  1. \displaystyle \ln 10 \approx 2{,}3\quad because \displaystyle e^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,2{,}3\,}} \approx 10.
  2. \displaystyle \ln e = 1\quad because \displaystyle e^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,1\vphantom{,}\,}} = e.
  3. \displaystyle \ln\frac{1}{e^3} = -3\quad because \displaystyle e^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,-3\vphantom{,}\,}} = \frac{1}{e^3}.
  4. \displaystyle \ln 1 = 0\quad because \displaystyle e^{\scriptstyle\,\bbox[#AAEEFF,1pt]{\,0\vphantom{,}\,}} = 1.
  5. If \displaystyle y= e^{\,a} then \displaystyle a = \ln y.
  6. \displaystyle e^{\,\bbox[#AAEEFF,1pt]{\,\ln 5\vphantom{,}\,}} = 5
  7. \displaystyle e^{\,\bbox[#AAEEFF,1pt]{\,\ln x\vphantom{,}\,}} = x

Most advanced calculators usually have buttons for 10-logarithms and natural logarithms.


Laws of Logarithms

Between the years 1617 and 1624 Henry Biggs published a table of logarithms for all integers up to 20 000, and in 1628 Adriaan Vlacq expanded the table for all integers up to 100 000. The reason such an enormous amount of work was invested in producing these tables is that with the help of logarithms one can multiply numbers together just by adding their logarithms (addition goes much faster to perform than multiplication).

Example 6

Calculate \displaystyle \,35\cdot 54.

If we know that \displaystyle 35 \approx 10^{\,1\textrm{.}5441} and \displaystyle 54 \approx 10^{\,1\textrm{.}7324} (i.e. \displaystyle \lg 35 \approx 1\textrm{.}5441 and \displaystyle \lg 54 \approx 1\textrm{.}7324) then we can calculate that

Vorlage:Fristående formel

and we then know that \displaystyle 10^{\,3\textrm{.}2765} \approx 1890 (i.e. \displaystyle \lg 1890 \approx 3\textrm{.}2765) thus we have managed to calculate the product

Vorlage:Fristående formel

and this just by adding together exponents \displaystyle 1\textrm{.}5441 and \displaystyle 1\textrm{.}7324.

This is an example of a logarithmic law which says that

Vorlage:Fristående formel

This stems from the fact that on the one hand,

Vorlage:Fristående formel

and on the other hand,

Vorlage:Fristående formel

By exploiting the laws of exponents in this way can we obtain the corresponding laws of logarithms:

The laws of logarithms apply regardless of base.

Example 7

  1. \displaystyle \lg 4 + \lg 7 = \lg(4 \cdot 7) = \lg 28
  2. \displaystyle \lg 6 - \lg 3 = \lg\frac{6}{3} = \lg 2
  3. \displaystyle 2 \cdot \lg 5 = \lg 5^2 = \lg 25
  4. \displaystyle \lg 200 = \lg(2 \cdot 100) = \lg 2 + \lg 100 = \lg 2 + 2

Example 8

  1. \displaystyle \lg 9 + \lg 1000 - \lg 3 + \lg 0{,}001 = \lg 9 + 3 - \lg 3 - 3 = \lg 9- \lg 3 = \lg \displaystyle \frac{9}{3} = \lg 3
  2. \displaystyle \ln\frac{1}{e} + \ln \sqrt{e} = \ln\left(\frac{1}{e} \cdot \sqrt{e}\,\right) = \ln\left( \frac{1}{(\sqrt{e}\,)^2} \cdot \sqrt{e}\,\right) = \ln\frac{1}{\sqrt{e}}
    \displaystyle \phantom{\ln\frac{1}{e} + \ln \sqrt{e}}{} = \ln e^{-1/2} = -\frac{1}{2} \cdot \ln e =-\frac{1}{2} \cdot 1 = -\frac{1}{2}\vphantom{\biggl(}
  3. \displaystyle \log_2 36 - \frac{1}{2} \log_2 81 = \log_2 (6 \cdot 6) - \frac{1}{2} \log_2 (9 \cdot 9)
    \displaystyle \phantom{\log_2 36 - \frac{1}{2} \log_2 81}{} = \log_2 (2\cdot 2 \cdot 3 \cdot 3) - \frac{1}{2} \log_2 (3 \cdot 3 \cdot 3 \cdot 3)
    \displaystyle \phantom{\log_2 36 - \frac{1}{2} \log_2 81}{} = \log_2 (2^2 \cdot 3^2) - \frac{1}{2} \log_2 (3^4)\vphantom{\Bigl(}
    \displaystyle \phantom{\log_2 36 - \frac{1}{2} \log_2 81}{} = \log_2 2^2 + \log_2 3^2 - \frac{1}{2} \log_2 3^4
    \displaystyle \phantom{\log_2 36 - \frac{1}{2} \log_2 81}{} = 2 \log_2 2 + 2 \log_2 3 - \frac{1}{2} \cdot 4 \log_2 3
    \displaystyle \phantom{\log_2 36 - \frac{1}{2} \log_2 81}{} = 2\cdot 1 + 2 \log_2 3 - 2 \log_2 3 = 2\vphantom{\Bigl(}
  4. \displaystyle \lg a^3 - 2 \lg a + \lg\frac{1}{a} = 3 \lg a - 2 \lg a + \lg a^{-1}
    \displaystyle \phantom{\lg a^3 - 2 \lg a + \lg\frac{1}{a}}{} = (3-2)\lg a + (-1) \lg a = \lg a - \lg a = 0


Changing the base

It sometimes can be a good idea to express a logarithm as a logarithm having another base.

Example 9

  1. Express \displaystyle \lg 5 as a natural logarithm.

    By definition, the \displaystyle \lg 5 is a number that satisfies the equality Vorlage:Fristående formel Take the natural logarithm ( ln ) of both sides. Vorlage:Fristående formel With the help of the logarithm law \displaystyle \ln a^b = b \ln a the left-hand side can be written as \displaystyle \lg 5 \cdot \ln 10 and the equality becomes Vorlage:Fristående formel Now divide both sides by \displaystyle \ln 10 giving the answer Vorlage:Fristående formel
  2. Express the 2-logarithm of 100 as a 10-logarithm lg.

    Using the definition of a logarithm one has that \displaystyle \log_2 100 formally satisfies Vorlage:Fristående formel and taking the 10-logarithm (lg) of both sides, one gets Vorlage:Fristående formel Since \displaystyle \lg a^b = b \lg a one gets \displaystyle \lg 2^{\log_2 100} = \log_{\scriptstyle 2} 100 \cdot \lg 2 and the right-hand side can be simplified to \displaystyle \lg 100 = 2. This gives the equality Vorlage:Fristående formel Finally, dividing by \displaystyle \lg 2 gives that Vorlage:Fristående formel

The general formula for changing from one base \displaystyle a to another base \displaystyle b can be derived in the same way

Vorlage:Fristående formel

If one wants to change the base of a power, one can do this by using logarithms. For instance, if we want to write \displaystyle 2^5 using the base 10 one first writes 2 as a power with the base 10; Vorlage:Fristående formel

and then using one of the laws of exponents Vorlage:Fristående formel

Example 10

  1. Write \displaystyle 10^x using the base e.

    First, we write 10 as a power of e, Vorlage:Fristående formel and then use the laws of exponents Vorlage:Fristående formel
  2. Write \displaystyle e^{\,a} using the base 10.

    The number \displaystyle e can be written as \displaystyle e=10^{\lg e} and therefore Vorlage:Fristående formel


Exercises

Study advice

The basic and final tests

After you have read the text and worked through the exercises, you should do the basic and final tests to pass this section. You can find the link to the tests in your student lounge.


Keep in mind that:

You may need to spend much time studying logarithms.

Logarithms usually are dealt with summarily in high school. Therefore, many college students tend to encounter problems when it comes to calculations with logarithms.


Reviews

For those of you who want to deepen your studies or need more detailed explanations consider the following references:

Learn more about logarithms in English Wikipedia

Learn more about the number e in The MacTutor History of Mathematics archive


Useful web sites

Experiment with logarithms and powers

Play logarithm Memory

Help the frog to jump onto his water-lily leaf in the "log" game