The discussion centers around the causes and implications of aerospace rotation in relation to Earth's rotation. Participants explore concepts related to jumping, momentum, and the Coriolis effect, considering both theoretical and practical implications.
Participants express a range of views on the effects of Earth's rotation on jumping and projectile motion, with no clear consensus on the implications of these effects. Some agree on the relevance of Coriolis force, while others challenge the significance of various factors like wind resistance and the scale of jumps.
Limitations include assumptions about wind resistance, the scale of jumps, and the idealization of conditions (e.g., airless scenarios). The discussion also reflects varying interpretations of how Earth's rotation influences motion in different contexts.
You mean the atmosphere? Most of the atmosphere was formed rotating, like the rest of the Earth. And there is also friction resisting relative movement.thegodof3d said:What is the cause of aerospace rotation whit the earth?
If there is no wind, the floating body will stay over the same point of the surface, obviously.thegodof3d said:Thanks
I mean , if a body was suspensed on the air , may Earth rotates and the body stayd
You can jump to other places, or jump in place.thegodof3d said:and if we jump and Earth rotates and when we arrivrd on the ground we are in another place!
DaveC426913 said:Or try jumping while on a train moving 60mph. When you jump, you don't drop from 60mph to 0. You carry the momentum with you that was imparted to you by the train.
Well, yes. Where I live, the Earth is rotating at about 700mph about its centre. Because I'm attached to the Earth (as is everything around me), we are all rotating around the centre at that speed. If I jump up and down, I retain that speed.thegodof3d said:Amazing!
You mean the primary speed of th Earth thanks .
thegodof3d said:Thanks
I mean , if a body was suspensed on the air , may Earth rotates and the body stayd...
and if we jump and Earth rotates and when we arrivrd on the ground we are in another place!
It depends on how you jump. You can certainly jump in such a way, that you land on exactly the same spot.mmeftahpour said:I say when you jump on the earth, we fall in different point because of Earth rotation.
That would be impossible to determine based upon a leg-powerd jump, though; the microscopic difference would be far overshadowed just by the fact that nobody can jump absolutely straight.A.T. said:you won't land on exactly the same spot
The Earth is large enough that it can essentially be treated as an inertial frame of reference. It only changes by 15 minutes of arc every minute. You'd have to jump (or fall) from more than two miles to experience a quarter of a degree of rotation.mmeftahpour said:Dear Dave
that's true for train, because the the train is Constant-Velocity, Non rotating Systems.
but I think it is not applicable for a system on the Earth surface.(with variable velocity direction and also axis direction.
So wait, you're going to ignore wind resistance? That's going to have an order of magnitude larger effect on your landing position than the rotation of the Earth. It's kind of the mathematical equivalent of "penny-wise, pound foolish".mmeftahpour said:for example if you shoot gun vertically, and bullet goes up 10 km. it fall in the same point? (consider there is no wind.)
mmeftahpour said:if we release a ball from tower with 400 m height there is 17 cm eastward deflection.(free fall in rotating idealized, airless Earth - page 8)
For long range shooting Coriolis acceleration becomes relevant.mmeftahpour said:for example if you shoot gun vertically, and bullet goes up 10 km. it fall in the same point? (consider there is no wind.)