Is \( x_0 \cos(\theta) \) Misinterpreted in Radial Coordinates?

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The discussion centers on the interpretation of \( x_0 \cos(\theta) \) in the context of radial coordinates and simple harmonic motion (SHM). Participants question whether \( x_0 \) represents the vertical component of the position vector or the radial distance along the x-axis. The relationship between the maximal amplitude \( x_0 \) and its projection on the x-axis is clarified, emphasizing that \( x_0 \) applies to all points on the circle, not just a specific position. The formula \( x = x_0 \cos(\theta) \) is explained as a means to determine the x-coordinate based on the angle \( \theta \). Overall, the discussion seeks to clarify the geometric intuition behind the use of cosine in this context.
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Homework Statement


At 16:30 he writes (x sub 0)(cosine theta). Is x sub 0 the vertical component length of the position vector of the particle? When he labels x sub 0 a little while before, it looks as though x sub 0 is at the radial point along the x axis. How can you use x sub 0 cosine theta at the radial point along the x-axis when the position of the particle doesn't coincide with the point at axis?

http://ocw.mit.edu/courses/physics/8-03-physics-iii-vibrations-and-waves-fall-2004/video-lectures/lecture-1/

Also, I know this doesn't adhere to the default question set-up guidelines, but how would I go about properly asking a question like this? I don't do schoolwork. I study what my weak mind can grasp alone at a pace at which I find most comfortable. I really don't know what he meant by this.
 
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x = xocos(wt + δ) describes SHM with maximal amplitude xo(since cos never exceeds 1). Since the cos function is periodic, he represented the function as a circle with radius xo, the max amplitude. The projection of xo onto the x-axis is the xocosθ.

This is similar to how sin and cos are defined via the unit circle, except here the circle is not of radius unity.
 
CAF123 said:
The projection of xo onto the x-axis is the xocosθ.

This is similar to how sin and cos are defined via the unit circle, except here the circle is not of radius unity.

But how is the projection of the maximal amplitude on the the x-axis xocosθ? I thought you use cosine when you want to determine vector components that make up the position of a point along the circle.

He says in the video that to determine the position of the particle along the x axis, you need to take the maximal amplitude times the cosine of theta. Why? What does radius have to do with the position along the x-axis which outlines both vector components? Can you try to break this down and explain the intuition even further?
 
Wait does x_0 apply to all radii within the circle? Did he just indicate that the radius, not at the specific spot along the x axis, is x_0? If this is the case, I understand my confusion. And the formula just happens to work now.
 
SlowProgress said:
Wait does x_0 apply to all radii within the circle? Did he just indicate that the radius, not at the specific spot along the x axis, is x_0? If this is the case, I understand my confusion. And the formula just happens to work now.
Yes, any point lying on the circle is a distance xo away from the origin.
 

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