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1.4.13: Logarithms

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    Learning Objectives

    • Compute logs using different bases
    • Perform basic arithmetic operations using logs
    • State the relationship between logs and proportional change

    The log transformation reduces positive skew. This can be valuable both for making the data more interpretable and for helping to meet the assumptions of inferential statistics.

    Basics of Logarithms (Logs)

    Logs are, in a sense, the opposite of exponents. Consider the following simple expression:

    \[10^2 = 100\]

    Here we can say the base of \(10\) is raised to the second power. Here is an example of a log:

    \[\log_{10}(100) = 2\]

    This can be read as: The log base ten of \(100\) equals \(2\). The result is the power that the base of \(10\) has to be raised to in order to equal the value (\(100\)). Similarly,

    \[\log_{10}(1000) = 3\]

    since \(10\) has to be raised to the third power in order to equal \(1,000\).

    These examples all used base \(10\), but any base could have been used. There is a base which results in "natural logarithms" and that is called \(e\) and equals approximately \(2.718\). It is beyond the scope here to explain what is "natural" about it. Natural logarithms can be indicated either as: \(\ln (x)\; or\; \log_e(x)\).

    Changing the base of the log changes the result by a multiplicative constant. To convert from \(\log _{10}\) to natural logs, you multiply by \(2.303\). Analogously, to convert in the other direction, you divide by \(2.303\).

    \[ \ln X =2.303 \log_{10} X \]

    Taking the \(\text{antilog}\) of a number undoes the operation of taking the \(\log\). Therefore, since \(\log_{10}(1000) = 3\), the \(antilog_{10}\) of \(3\) is \(10^3 = 1,000\). Taking the \(\text{antilog}\) of a number simply raises the base of the logarithm in question to that number.

    Logs and Proportional Change

    A series of numbers that increase proportionally will increase in equal amounts when converted to logs. For example, the numbers in the first column of Table \(\PageIndex{1}\)
    increase by a factor of \(1.5\) so that each row is \(1.5\) times as high as the preceding row. The \(\log_{10}\) transformed numbers increase in equal steps of \(0.176\).

    Table \(\PageIndex{1}\): Proportional raw changes are equal in log units
    Raw Log
    4.0 0.602
    6.0 0.778
    9.0 0.954
    13.5 1.130

    As another example, if one student increased their score from \(100\) to \(200\) while a second student increased theirs from \(150\) to \(300\), the percentage change (\(100\%\)) is the same for both students. The log difference is also the same, as shown below.

    \[Log_{10}(100) = 2.000\\ \log_{10}(200) = 2.301\\ Difference: 0.301\\ \; \\ \log_{10}(150) = 2.176\\ \log_{10}(300) = 2.477\\ Difference: 0.301\]

    Arithmetic Operations

    Rules for logs of products and quotients are shown below.

    \[\log(AB) = \log(A) + \log(B)\]

    \[\log\left(\dfrac{A}{B}\right) = \log(A) - \log(B)\]

    For example,

    \[\log_{10}(10 \times 100) = \log_{10}(10) + \log_{10}(100) = 1 + 2 = 3.\]


    \[\log_{10}\left(\dfrac{100}{10}\right) = \log_{10}(100) - \log_{10}(10) = 2 - 1 = 1.\]

    Contributors and Attributions

    • Online Statistics Education: A Multimedia Course of Study ( Project Leader: David M. Lane, Rice University.

    • David M. Lane

    This page titled 1.4.13: Logarithms is shared under a Public Domain license and was authored, remixed, and/or curated by David Lane via source content that was edited to the style and standards of the LibreTexts platform; a detailed edit history is available upon request.