Initial velocity required depend on the mass of projectile

AI Thread Summary
Initial velocity required for a projectile does not depend on its mass when considering ballistic trajectories. The trajectory is influenced by momentum and gravity, which accelerates all objects at the same rate regardless of mass. The distance a projectile travels is determined by its forward speed and the time it takes to fall, which remains constant for both heavy and light objects. While technically heavier objects may fall slightly faster due to their gravitational pull on the Earth, this difference is negligible and not relevant in practical terms. Overall, the principles of projectile motion indicate that mass does not affect the initial velocity needed for a specific angle and height.
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Does the Initial velocity required depend on the mass of projectile to impart a projectile of perticilar angle and perticular height?
 
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No, balistic trajectories do not depend on mass. A balistic trajectory is the course a projactile takes as its momentum is balanced against gravity, and gravity accelerates all freefalling objects at pretty much the same rate. So the forward speed of a projectile determines how far it will travel in the amount of time it takes to fall to the ground, the that amount of time is the same for heavy or light things. In fact, a balistic trjectory is a segmant of an orbit.

All this is neglecting any differences in wind resistance, of course.

Now, if one wanted to get really picky, I suppose it can be said that more massive objects do fall a tiny bit faster than lighter objects because, all though the Earth's gravitationl pull on both objects is the same, the heavier object has a stronger pull on the Earth. But that would be silly.
 
Originally posted by Techno
Now, if one wanted to get really picky, I suppose it can be said that more massive objects do fall a tiny bit faster than lighter objects because, all though the Earth's gravitationl pull on both objects is the same, the heavier object has a stronger pull on the Earth. But that would be silly.

It would be not only both silly and picky, it would be incorrect. Neglecting air resistance, the rate at which an object and the Earth accelerate toward each other is independent of the mass of the object.
 

Thread 'Derivation of Hamilton's Principle: Questions'

I have recently been really interested in the derivation of Hamiltons Principle. On my research I found that with the term ##m \cdot \frac{d}{dt} (\frac{dr}{dt} \cdot \delta r) = 0## (1) one may derivate ##\delta \int (T - V) dt = 0## (2). The derivation itself I understood quiet good, but what I don't understand is where the equation (1) came from, because in my research it was just given and not derived from anywhere. Does anybody know where (1) comes from or why from it the...
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