It will be somewherebelow 160 km from earth surface since average human terminal velocity is 160 km/hr. More detail calculation would be needed since at that height, gravity would reduce by 0.4 m/s2 and air is so thin that it had little friction and terminal velocity might be very high at that height.
It has been known since the 16th century that the mass of an object is irrelevant to how far it will fall. The main factor influencing the rate of fall is the shape of the object and, therefore, the air resistance (or buoyancy).
An object subjected to Earth's gravity of about 32.2 feet per second2 will fall 64.4 feet.distance = 1/2 At2velocity = AtAt that point, they would be traveling about 44 miles per hour, which is less than terminal velocity of about 125 miles per hour, which means that it does not significantly matter how much the person weighs, because air friction does not really enter into the picture yet.
I Don't Have Far to Fall was created in 1988-08.
When an object falls, air resistance causes it to reach a terminal velocity. After that, it does not increase the speed of falling, no matter how far it has still to fall.
Not as far as gravity is concerned. If there's any difference, it's only on account of air resistance.
One hour!
How far does light travel in one hour
around 1 hour and 30 minutes depending on the airport
In a vacuum, there is no drag, i.e. air resistance, so the coin and the piece of paper will fall the same way in a vacuum, whereas in air, the paper will flutter down while the coin will have minimal impediment due to its drag coefficient being far less than that of paper.
No all objects fall at the same speed, unless air resistance is involved
A lot of times
Using the order of operations (PEMDAS), what is the first thing that you would do when solving this equation? (4x + 3) - 5 + 10