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Radius

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College Physics I – Introduction

Definition

The radius is the distance from the center of a circle or sphere to its circumference or surface. It is a fundamental geometric property that defines the size and shape of circular and spherical objects.

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5 Must Know Facts For Your Next Test

  1. The radius is a crucial parameter in the calculation of centripetal acceleration, which is the acceleration experienced by an object moving in a circular path.
  2. The centripetal acceleration of an object is inversely proportional to its radius, meaning that as the radius increases, the centripetal acceleration decreases.
  3. The radius of a circular motion determines the path the object takes, with a larger radius resulting in a wider, less curved path.
  4. The radius of a circular motion is a key factor in determining the centripetal force required to maintain the circular trajectory, with a larger radius requiring less centripetal force.
  5. The radius of a circular motion is also a factor in the period and frequency of the circular motion, with a larger radius corresponding to a longer period and lower frequency.

Review Questions

  • Explain how the radius of a circular motion affects the centripetal acceleration experienced by the object.
    • The radius of a circular motion is inversely proportional to the centripetal acceleration experienced by the object. As the radius increases, the centripetal acceleration decreases, and vice versa. This is because the centripetal acceleration is calculated as $v^2/r$, where $v$ is the velocity of the object and $r$ is the radius of the circular path. Therefore, a larger radius results in a lower centripetal acceleration, while a smaller radius leads to a higher centripetal acceleration.
  • Describe how the radius of a circular motion influences the centripetal force required to maintain the circular trajectory.
    • The radius of a circular motion is a key factor in determining the centripetal force required to maintain the circular trajectory. The centripetal force is calculated as $m v^2 / r$, where $m$ is the mass of the object, $v$ is the velocity, and $r$ is the radius of the circular path. As the radius increases, the centripetal force required to maintain the circular motion decreases, as the object can 'swing out' more without leaving the circular path. Conversely, a smaller radius requires a greater centripetal force to keep the object moving in the circular trajectory.
  • Analyze the relationship between the radius of a circular motion and the period and frequency of the motion.
    • The radius of a circular motion is also related to the period and frequency of the motion. The period, which is the time it takes for one complete revolution, is proportional to the radius, as described by the formula $T = 2\pi r / v$, where $T$ is the period, $r$ is the radius, and $v$ is the velocity. Similarly, the frequency, which is the number of revolutions per unit of time, is inversely proportional to the radius, as $f = 1/T$. Therefore, a larger radius corresponds to a longer period and lower frequency, while a smaller radius results in a shorter period and higher frequency of the circular motion.
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