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| course_planning:course_notes:constantv [2014/07/03 16:48] – caballero | course_planning:course_notes:constantv [2014/07/08 13:20] (current) – [Speed and Velocity] caballero | ||
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| - | ===== The Constant Velocity | + | ===== Constant Velocity |
| Our job in mechanics is to predict motion. So, all the models and tools that we develop are aimed at achieving this goal. | Our job in mechanics is to predict motion. So, all the models and tools that we develop are aimed at achieving this goal. | ||
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| **Velocity: | **Velocity: | ||
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| + | === Average Velocity === | ||
| Average Velocity ($\vec{v}_{avg}$) describes how an object changes its displacement in a given time. To compute an object' | Average Velocity ($\vec{v}_{avg}$) describes how an object changes its displacement in a given time. To compute an object' | ||
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| where $t_f - t_i$ is always positive, but $x_f-x_i$ can be positive, negative, or zero because it represents the displacement in the x-direction, | where $t_f - t_i$ is always positive, but $x_f-x_i$ can be positive, negative, or zero because it represents the displacement in the x-direction, | ||
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| + | === Approximate Average Velocity === | ||
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| + | The average velocity is defined as the displacement over a given time, but what about the // | ||
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| + | The arithmetic average velocity is a approximation to the average velocity. | ||
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| + | $$v_{x,avg} = \dfrac{\Delta x}{\Delta t} \approx \dfrac{v_{ix} + v_{fx}}{2}$$ | ||
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| + | This equation only hold exactly if the velocity changes linearly with time (constant force motion). It might be a very poor approximation if velocity changes in other ways. | ||
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| + | === Instantaneous Velocity === | ||
| Instantaneous velocity ($\vec{v}$) describes how quickly an object is moving a specific point in time. If you consider the displacement over shorter and shorter $\Delta t$'s, your computation will give a reasonable approximation for the instantaneous velocity. In the limit that $\Delta t$ goes to zero, your computation would be exact. Mathematically, | Instantaneous velocity ($\vec{v}$) describes how quickly an object is moving a specific point in time. If you consider the displacement over shorter and shorter $\Delta t$'s, your computation will give a reasonable approximation for the instantaneous velocity. In the limit that $\Delta t$ goes to zero, your computation would be exact. Mathematically, | ||
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| **Speed:** A scalar quantity that describes that distance (not the displacement) traveled over an elapsed time. | **Speed:** A scalar quantity that describes that distance (not the displacement) traveled over an elapsed time. | ||
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| + | === Average speed === | ||
| Average speed ($s$) describes how quickly an object covers a given distance in a given amount of time. So, you can think of it as //average speed = total distance traveled divided by total time elapsed//. Mathematically, | Average speed ($s$) describes how quickly an object covers a given distance in a given amount of time. So, you can think of it as //average speed = total distance traveled divided by total time elapsed//. Mathematically, | ||
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| Notice that the instantaneous velocity is equivalent to the magnitude of the velocity vector and, therefore, is a positive scalar quantity. | Notice that the instantaneous velocity is equivalent to the magnitude of the velocity vector and, therefore, is a positive scalar quantity. | ||
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| ==== Predicting the motion of objects ==== | ==== Predicting the motion of objects ==== | ||