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24.4: Case III- Variable force in the direction of motion

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    Now let's take another case: suppose the force \(F\) is in the direction of motion, but suppose \(F\) is not constant, but is a function of position \(x\). Now take the straight-line path over which object moves and divide it into many infinitesimal segments, each of length \(d x\). Then over distance \(d x\), the force \(F\) can be considered constant, and the work \(d W\) done over distance \(d x\) is \(F(x) d x\). To get the total work done by the force \(F\), we sum up all these contributions \(F d x\) by doing an integral:

    \[W=\int F(x) d x\]

    Example \(\PageIndex{1}\)

    For a mass on a spring, the work done by the spring force is given by Hooke's law: \(F(x)=\) \(-k x\), where \(k\) is the spring constant. Then the work done by the spring is?

    Solution

    The work done by the spring is

    \[
    \begin{align}
    W & =\int F(x) d x \\
    & =\int(-k) x d x \\
    & =-k \int x d x \\
    & =-\frac{1}{2} k x^{2}
    \end{align}
    \]

    In extending the spring a distance \(x\) from equilibrium, a work \(-k x^{2} / 2\) is done by the spring; work \(+k x^{2} / 2\) is done by you, against the spring.

    24.4: Case III- Variable force in the direction of motion is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by LibreTexts.