Is there an instantaneous angular acceleration for a conical pendulm?

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jason12345
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For a conical pendulum, there is an instantaneous centripetal acceleration. Does this mean there is an instantaneous angular acceleration of the pendulum towards the center?
 
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olivermsun said:
Can you define what your angle and center refer to?

The angle is between the string and the axis of symmetry the pendulum rotates around.
 
I see, you're talking about a pendulum which swings about the center axis in a cone.

Your angle, as defined, rotates with the pendulum string and remains constant, so I would say "no."
 
olivermsun said:
I see, you're talking about a pendulum which swings about the center axis in a cone.

Your angle, as defined, rotates with the pendulum string and remains constant, so I would say "no."

Thanks for your reply, although I disagree with it :) I could also argue that the radius of the circular motion is constant and so there isn't an acceleration towards the centre - but there is: v^2/r
 
There is an acceleration (which happens to be toward the center) because the radius vector is not constant. Only the radius magnitude is constant.

As far as I can tell, the angular velocity is constant if defined around the axis of symmetry.
 
olivermsun said:
There is an acceleration (which happens to be toward the center) because the radius vector is not constant. Only the radius magnitude is constant.

I think you mean velocity where you state radius.

As far as I can tell, the angular velocity is constant if defined around the axis of symmetry.

I agree that angular velocity is constant.
 
jason12345 said:
I think you mean velocity where you state radius.

You're right. Change in radius vector per time (velocity) changes.
 
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How does the radius vector not change? Doesn't it's magnitude stay the same, however the direction is changing?
 
The radius does change (dr/dt is nonzero), so that there is a velocity, but he was talking about whether or not there is an acceleration. There is, since d^2/dt^2 = dv/dt is nonzero. A changing radius vector isn't enough to imply an acceleration, although it is enough that the magnitude stays the same while the direction is changing (as you say).