- #1
Calculate Tangential & Normal Acceleration of Particle in Elliptical Orbit
- Thread starter brasilr9
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In an elliptical orbit with uniform speed, the tangential acceleration is zero because there is no change in tangential velocity. However, normal acceleration exists due to the continuous change in the direction of velocity, even though the speed remains constant. The discussion highlights that while tangential acceleration remains constant in magnitude, it does not imply that it is zero in all cases. For circular orbits, tangential acceleration is also zero since the radial distance does not change. Overall, both tangential and normal accelerations are important in understanding the motion of a particle in an elliptical orbit.
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siddharth
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You can show your work for a start.
- #3
brasilr9
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I think I figure it out.
Since it's speed is constant, there's is no change in tangential velocity, hence tangential acceleration remain zero.
Since it's speed is constant, there's is no change in tangential velocity, hence tangential acceleration remain zero.
- #4
Hootenanny
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brasilr9 said:
That's correct.
Now what about the normal acceleration?- #5
Hootenanny
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siddharth said:
Ahh yes, I suppose constant magnitude would be an accurate term. Just re-reading through the question (and without looking at the picture obviously), I can't see the point. There is always going be tangental acceleration, and there also must always be normal acceleration, although this will change.
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siddharth
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What I posted first wasn't exactly correct
What I mean is, if
\vec{r} = r \vec{e_r}
then according to the OP's question,
|\frac{d\vec{r}}{dt}| will be constant. So, for an ellipse, this doesn't mean that \frac{d^2\vec{r}}{dt^2} along e_\phi will be 0.
In fact, for a circular orbit, since \frac{dr}{dt} =0, the tangential acceleration will be 0.
What I mean is, if
\vec{r} = r \vec{e_r}
then according to the OP's question,
|\frac{d\vec{r}}{dt}| will be constant. So, for an ellipse, this doesn't mean that \frac{d^2\vec{r}}{dt^2} along e_\phi will be 0.
In fact, for a circular orbit, since \frac{dr}{dt} =0, the tangential acceleration will be 0.
Last edited:
I multiplied the values first without the error limit. Got 19.38. rounded it off to 2 significant figures since the given data has 2 significant figures. So = 19.
For error I used the above formula. It comes out about 1.48. Now my question is. Should I write the answer as 19±1.5 (rounding 1.48 to 2 significant figures) OR should I write it as 19±1. So in short, should the error have same number of significant figures as the mean value or should it have the same number of decimal places as...
Figure 1 Overall Structure Diagram
Figure 2: Top view of the piston when it is cylindrical
A circular opening is created at a height of 5 meters above the water surface. Inside this opening is a sleeve-type piston with a cross-sectional area of 1 square meter. The piston is pulled to the right at a constant speed. The pulling force is(Figure 2): F = ρshg = 1000 × 1 × 5 × 10 = 50,000 N.
Figure 3: Modifying the structure to incorporate a fixed internal piston
When I modify the piston...
Let's declare that for the cylinder,
mass = M = 10 kg
Radius = R = 4 m
For the wall and the floor,
Friction coeff = ##\mu## = 0.5
For the hanging mass,
mass = m = 11 kg
First, we divide the force according to their respective plane (x and y thing, correct me if I'm wrong) and according to which, cylinder or the hanging mass, they're working on.
Force on the hanging mass
$$mg - T = ma$$
Force(Cylinder) on y
$$N_f + f_w - Mg = 0$$
Force(Cylinder) on x
$$T + f_f - N_w = Ma$$
There's also...
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