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1.9: Summary

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    127335
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    Selected Vocabulary

    matter ............................. Anything that is affected by gravity.
    light................................. Anything that can travel from one place to another through empty space and can influence matter, but is not affected by gravity.
    operational definition ........ A definition that states what operations should be carried out to measure the thing being defined.
    Système International ........ A fancy name for the metric system.
    mks system ....................... The use of metric units based on the meter, kilogram, and second. Example: meters per second is the mks unit of speed, not \(\mathrm{cm} / \mathrm{s}\) or \(\mathrm{km} / \mathrm{hr}\).
    mass ................................ A numerical measure of how difficult it is to change an object's motion.
    significant figures ............. Digits that contribute to the accuracy of a measurement.

    Notation

    m \(\_\_\_\_\) symbol for mass, or the meter, the metric distance unit
    kg \(\_\_\_\_\) kilogram, the metric unit of mass
    s \(\_\_\_\_\) second, the metric unit of time
    M- \(\_\_\_\_\) the metric prefix mega-, \(10^6\)
    k- \(\_\_\_\_\) the metric prefix kilo-, \(10^3\)
    m- \(\_\_\_\_\) the metric prefix milli-, \(10^3\)
    \(\mu-\) \(\_\_\_\_\) the metric prefix micro- \(10^{-6}\)
    n- \(\_\_\_\_\) the metric prefix nano-, \(10^9\)

    Summary

    Physics is the use of the scientific method to study the behavior of light and matter. The scientific method requires a cycle of theory and experiment, theories with both predictive and explanatory value, and reproducible experiments.

    The metric system is a simple, consistent framework for measurement built out of the meter, the kilogram, and the second plus a set of prefixes denoting powers of ten. The most systematic method for doing conversions is shown in the following example:

    \[370 \mathrm{~ms} \times \frac{10^{-3} \mathrm{~s}}{1 \mathrm{~ms}}=0.37 \mathrm{~s} \notag \]

    Mass is a measure of the amount of a substance. Mass can be defined gravitationally, by comparing an object to a standard mass on a double-pan balance, or in terms of inertia, by comparing the effect of a force on an object to the effect of the same force on a standard mass. The two definitions are found experimentally to be proportional to each other to a high degree of precision, so we usually refer simply to "mass," without bothering to specify which type.

    A force is that which can change the motion of an object. The metric unit of force is the Newton, defined as the force required to accelerate a standard \(1-\mathrm{kg}\) mass from rest to a speed of \(1 \mathrm{~m} / \mathrm{s}\) in 1 s .

    Scientific notation means, for example, writing \(3.2 \times 10^5\) rather than 320000 .
    Writing numbers with the correct number of significant figures correctly communicates how accurate they are. As a rule of thumb, the final result of a calculation is no more accurate than, and should have no more significant figures than, the least accurate piece of data.


    1.9: Summary is shared under a not declared license and was authored, remixed, and/or curated by LibreTexts.

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