183_notes:center_of_mass

Differences

This shows you the differences between two versions of the page.

Link to this comparison view

Both sides previous revision Previous revision
Next revision		 Previous revision
183_notes:center_of_mass [2018/05/29 21:07] hallstein183_notes:center_of_mass [2022/12/22 15:43] (current) hallstein
Line 3: Line 3:
 ===== The Motion of the Center of Mass ===== ===== The Motion of the Center of Mass =====
  
-In a system of multiple particles, each particle has its own motion. But often, its useful to think about the collective motion of these objects. By "collective motion", you are looking to understand how the whole system is moving: Is it stationary and objects rotate around? Is there some net translation (movement to the right or left)? Or something more peculiar? In these notes you will read about the concept of the center of mass, which helps us track the overall motion of a system. +In a system of multiple particles, each particle has its own motion. But often, its useful to think about the collective motion of these objects. By "collective motion", you are looking to understand how the whole system is moving: Is it stationary and objects rotate around? Is there some net translation (movement to the right or left)? Or something more peculiar? **In these notes you will read about the concept of the center of mass, which helps us track the overall motion of a system. 
 +**
 ==== Lecture Video ==== ==== Lecture Video ====
 {{youtube>5qwW8WI1gkw?large}} {{youtube>5qwW8WI1gkw?large}}
  
-==== The center of mass ====+\\ 
 + 
 + 
 +==== The Center of Mass ====
  
 The center of mass is a concept that helps us understand how the motion of a multi-particle system evolves with time. It is connected very strongly to the total momentum of a system as you will read. The center of mass is a concept that helps us understand how the motion of a multi-particle system evolves with time. It is connected very strongly to the total momentum of a system as you will read.
 +
 +\\
 +
 +
  
 === Flocking birds === === Flocking birds ===
Line 16: Line 23:
  
 {{youtube>Oxk-ptOJUdU?large}} {{youtube>Oxk-ptOJUdU?large}}
 +\\
 +
 +//(This video is intended for visual learning assistance. Auditory Components are not necessary.)//
 +
 +\\
 +
 +
 It's hard to think about what the motion of a system of objects means without some sort of example. The video above shows the motion of a flock of birds. Each individual bird flies in with its own direction and speed, but the flock (or the bulk) moves in a particular way (it appears to move in a circle or ellipse) that your eye can follow. What you are paying attention to is the motion of the "center" of the bulk. It is this concept that you are going to read about below. It's hard to think about what the motion of a system of objects means without some sort of example. The video above shows the motion of a flock of birds. Each individual bird flies in with its own direction and speed, but the flock (or the bulk) moves in a particular way (it appears to move in a circle or ellipse) that your eye can follow. What you are paying attention to is the motion of the "center" of the bulk. It is this concept that you are going to read about below.
  
Line 21: Line 35:
 === Calculating the center of mass === === Calculating the center of mass ===
  
-The center of mass of a system is the weighted average of the particles in that system. Consider a set of three particles with different mass ($m_i$), which are all located a different locations relative to the origin ($\vec{r}_i$). For these three particles, the center of mass of that system is the vector sum,+The center of mass of a system is the weighted average of the particles in that system. Consider a set of three particles with different mass ($m_i$), which are all located a different locations relative to the origin ($\vec{r}_i$). For these three particles, the center of mass of that system is the vector sum.
  
 $$\vec{r}_{cm} = \dfrac{m_1 \vec{r}_1+m_2 \vec{r}_2+m_3 \vec{r}_3}{m_1+m_2+m_3} = \dfrac{1}{M_{tot}} \left(m_1 \vec{r}_1+m_2 \vec{r}_2+m_3 \vec{r}_3\right)$$ $$\vec{r}_{cm} = \dfrac{m_1 \vec{r}_1+m_2 \vec{r}_2+m_3 \vec{r}_3}{m_1+m_2+m_3} = \dfrac{1}{M_{tot}} \left(m_1 \vec{r}_1+m_2 \vec{r}_2+m_3 \vec{r}_3\right)$$
Line 57: Line 71:
 The simulation below shows a binary star (red star and yellow star) system where the total momentum of the system is non-zero, but because there are no external forces to the two particle system, the center of mass moves with constant momentum (green sphere and line). The simulation below shows a binary star (red star and yellow star) system where the total momentum of the system is non-zero, but because there are no external forces to the two particle system, the center of mass moves with constant momentum (green sphere and line).
  
 +/*
 {{url>http://www.pa.msu.edu/~caballero/teaching/simulations/BinaryStarWithCM.html 675px,455px|Model of a solid}} {{url>http://www.pa.msu.edu/~caballero/teaching/simulations/BinaryStarWithCM.html 675px,455px|Model of a solid}}
 +*/
 +
 +{{youtube>sNMPr1xi0DA?XLarge 675px,455px|}}
  
 ==== Examples ===== ==== Examples =====
  
   * [[:183_notes:examples:Walking in a Boat]]   * [[:183_notes:examples:Walking in a Boat]]
  • 183_notes/center_of_mass.1527628064.txt.gz
  • Last modified: 2018/05/29 21:07
  • by hallstein