College Physics II – Mechanics, Sound, Oscillations, and Waves
Definition
$x_f$ represents the final position of an object in motion, indicating where the object is located after it has traveled a certain distance from its initial position. This term is crucial for understanding how position changes over time, as it allows us to calculate displacement and average velocity. By knowing the initial position and the final position, we can analyze an object's movement in a clear and systematic way.
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$x_f$ is typically measured in meters (m) and provides critical information about where an object ends up after its motion.
To find $x_f$, you often need to know both $x_i$ and the displacement of the object.
In equations of motion, $x_f$ is used to determine how far an object has moved from its starting point, which is essential for understanding motion graphs.
When analyzing motion with constant velocity, $x_f$ can be calculated using the formula $x_f = x_i + vt$, where $v$ is velocity and $t$ is time.
$x_f$ plays a key role in applications involving projectiles and free-fall motions, helping to predict where these objects will land.
Review Questions
How does $x_f$ relate to understanding the overall motion of an object?
$x_f$ helps to define an object's final position after it has undergone motion. By comparing $x_f$ to $x_i$, we can calculate displacement and better understand how far and in what direction the object has moved. This connection allows us to analyze movement patterns and determine whether an object has returned to its starting point or traveled further away.
What is the mathematical relationship between $x_f$, $x_i$, and displacement, and why is this important in physics?
The relationship can be expressed with the equation: Displacement = $x_f - x_i$. This formula highlights that displacement is not just about distance traveled but also considers direction, making it a vector quantity. Understanding this relationship is crucial because it provides insights into an object's trajectory and overall movement characteristics, which are essential for solving problems involving motion.
Evaluate how knowing both $x_f$ and $x_i$ can impact predictions made in real-world scenarios involving motion.
Knowing both $x_f$ and $x_i$ allows us to make accurate predictions about an object's future positions or determine when it will reach a specific location. For example, in engineering applications like vehicle navigation or projectile design, these measurements help ensure safety and efficiency by allowing calculations for travel time, landing points, or optimal trajectories. Analyzing these positions enables better decision-making in dynamic environments where precise positioning is critical.
Displacement is the vector quantity that represents the change in position of an object, calculated as the difference between the final and initial positions ($x_f - x_i$).
Average velocity is defined as the total displacement divided by the total time taken for that displacement, indicating how fast an object is moving in a specific direction.