Describing the Motion of a Particle Along a Unit Circle

In summary, a unit circle is a circle with a radius of one unit commonly used in mathematics and physics to describe the motion of a particle. This motion is described using polar coordinates, which includes the angle and distance from the center of the circle. The significance of the unit circle lies in simplifying complex motion into a single dimension and providing a standard reference point. The velocity of a particle along a unit circle can be calculated by finding the derivative of the angle with respect to time. Other related concepts include angular acceleration, centripetal force, and tangential velocity.
  • #1
mit_hacker
92
0

Homework Statement


Each of the following paths describes the motion of a particle having the same path, namely the unit circle x^2 + y^2 =1. Although the path for each particle is the same, the behavior of each particle is different. For each particle, answer the following questions:

i. ...
ii ...
iii Does the particle move counterclockwise or clockwise?
iiii ...

Homework Equations





The Attempt at a Solution



The logic I used to answer part 3 for each particle was to check the position at t=0 and then again at t=pi/2. The change in position will tell me whether it has moved clockwise or counterclockwise. What I need help is n confirming whether or not my method is correct or whether there is some other neater way to do this question.

Thank-you all for the help!
 
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  • #2
?? You haven't given the formula for the motion so it is not clear whether your method works or not. It is possible that the particle is moving clockwise at t= 0, then before t= pi/2, turns and moves back counter clockwise. If the particle is moving either always counterclockwise or always clockwise, as is implied by the fact that the question does not ask about a particular time, yes, that method works. But what if it had asked which way the particle was moving at t= 0?
 
  • #3
It is "always"

It is always moving in the same direction. For instance, one of the formulas was
(Cos t)i - (Sin t)j.

You raised an interesting question. What if the question asked which way is the particle moving at t=0. What method would you apply in that case? Please tell me if I am right:

You find the tangent to the curve at that point and find the direction of that vector with respect to the xy-plane.

Am I right?
 
  • #4
mit_hacker said:
It is always moving in the same direction. For instance, one of the formulas was
(Cos t)i - (Sin t)j.
It would have helped if you told us that to begin with!

You raised an interesting question. What if the question asked which way is the particle moving at t=0. What method would you apply in that case? Please tell me if I am right:

You find the tangent to the curve at that point and find the direction of that vector with respect to the xy-plane.

Am I right?[/QUOTE]
Yes, that would work. Another way would be to just look at one component: y= -sin(t) so y'= cos(t). At t= 0, the point is (1, 0) and y is increasing: counter-clockwise.
 

1. What is a unit circle?

A unit circle is a circle with a radius of one unit. It is often used in mathematics and physics to provide a reference point for describing the motion of a particle.

2. How is the motion of a particle along a unit circle described?

The motion of a particle along a unit circle is described using polar coordinates. This includes the angle (measured in radians) that the particle has rotated around the circle, as well as the distance from the center of the circle to the particle.

3. What is the significance of the unit circle in describing motion?

The unit circle is significant because it allows us to simplify complex motion into a single dimension (the angle) and provides a standard reference point for measuring the motion of a particle.

4. How is the velocity of a particle along a unit circle calculated?

The velocity of a particle along a unit circle can be calculated by finding the derivative of the angle with respect to time. This gives us the angular velocity, which can then be converted to linear velocity using the radius of the circle.

5. What other concepts are related to describing the motion of a particle along a unit circle?

Other related concepts include angular acceleration, centripetal force, and tangential velocity. These all play a role in understanding and describing the movement of a particle along a unit circle.

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