Because this is a free fall questions, the equation d=1/2gt² can be used. Gravity is a given, 9.8 m/s² and the time is your 15 seconds of free fall.
d=1/2(9.8m/s²)(15s)²= 1,102.5m. To find feet multiply 3.28084 to answer because that is how many feet are in a meter.
45.5 mph
At the end of 3 seconds, a falling object is falling at 65.8 mph faster than when it was released, ignoring air resistance.
depends on weight of object and wind strength.normally heavy objects will drop down faster than lighter objects.
H = 1/2 G T2 = 1/2 (32.2) (1.5)2 = 36.23 feet
If they're not falling through air, then a bean and a battleship both fall 692 feetin 6.556 seconds. The weight of the object makes no difference.If the object IS falling through air, then in order to answer the question, we need toknow the object's shape, size, and volume, plus the temperature, humidity, density,and pressure of the air, at every altitude between the ground and 692 feet.
An object dropped from rest will have a downward velocity of (9 g) = 88.2 meters per second after 9 seconds. Ignoring air resistance, the mass of the object is irrelevant. All masses fall with the same acceleration, and have the same downward velocity after any given period of time.
An object dropped from rest will have a downward velocity of (9 g) = 88.2 meters per second after 9 seconds. Ignoring air resistance, the mass of the object is irrelevant. All masses fall with the same acceleration, and have the same downward velocity after any given period of time.
59m/s
59m/s
A planet orbiting the Sun.A heavy object, released, to let it fall (for the first few seconds; later, air resistance may be significant).A planet orbiting the Sun.A heavy object, released, to let it fall (for the first few seconds; later, air resistance may be significant).A planet orbiting the Sun.A heavy object, released, to let it fall (for the first few seconds; later, air resistance may be significant).A planet orbiting the Sun.A heavy object, released, to let it fall (for the first few seconds; later, air resistance may be significant).
29 m/s
576 feet
object to fall with an approximate acceleration of 9.8 seconds.
If it is a tall object, it could fall over.
4 Seconds
45.5 mph
On object falling under the force of gravity (9.8 m/s2) would, in a vacuum, fall a distance of 706 metres in 12 seconds. In a non-vacuum, i.e. air, the object would fall less distance in the same time due to drag.xt = 0.5 (9.8) t2