Finding Normal and Tangential Acceleration Components in 2D Motion

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In summary, the problem involves finding the normal and tangential acceleration components of a particle in motion, given acceleration and velocity equations. The problem is in 2 dimensions and the dot product of the acceleration and velocity can be used to find the tangential component. Additionally, knowing the velocity vector allows for the creation of a unit vector in the direction of the velocity.
  • #1
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Homework Statement


ive reduced a problem down to one last part, and where i need the normal and tangential acceleration components of a moving particle. we are given the following: $$a=xi+yj$$ and $$v=ui+zj$$ where a and v are acceleration and velocity and the x,y,u,z are the components.

note we are only in 2 dimensions

i can't think of any way to proceed. thanks for any help!
 
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  • #2
So when you say you want the tangential acceleration then that would be the a component in the direction of v

So look at the dot product of a with v

In a similar vein you should now know how to get the normal component.
 
  • #3
If you have the equation for the velocity vector v, then you should be able to write down an equation for a unit vector in the direction of the velocity vector. What is that equation?
 

Related to Finding Normal and Tangential Acceleration Components in 2D Motion

1. What is the difference between normal and tangential acceleration?

Normal acceleration is the component of acceleration that is perpendicular to the object's motion. Tangential acceleration is the component of acceleration that is parallel to the object's motion.

2. How are normal and tangential acceleration related?

Normal and tangential acceleration are two components of the total acceleration of an object. The total acceleration is the vector sum of the two components.

3. How can normal and tangential acceleration be calculated?

Normal and tangential acceleration can be calculated using the equations:an = v2/r and at = d(v)/dt, where v is the object's velocity, r is the radius of curvature, and d(v)/dt is the derivative of velocity with respect to time.

4. What is the physical significance of normal and tangential acceleration?

Normal acceleration is responsible for the change in direction of an object's motion, while tangential acceleration is responsible for the change in speed. Together, they determine the total acceleration and the resulting motion of the object.

5. How does normal and tangential acceleration affect an object in circular motion?

In circular motion, the normal acceleration is directed towards the center of the circle, while the tangential acceleration is directed tangentially to the circle. These two components work together to keep the object moving in a circular path.

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