You did not exactly finish your question. Are you looking for velocity, force or some sort of bounce? Velocity can be found with v2 = v1t + 1/2at2 or v2 = acceleration times distance Kinetic energy is KE= 1/2mv2
Neglecting air resistance, a body falling freely near the earth's surface falls with an acceleration of 9.8 meters (32.2 feet) per second per second, regardless of how big, small, light, or heavy it is.
The gravitational pull on the falling man and the wind resistance acting against the fall.
A falling elephant encounters a greater force of air resistance than a falling feather does. The force of air resistance can't be greater than the weight of the falling object. When the force of air resistance is equal to the weight of the falling object, the object stops accelerating, its falling speed becomes constant, and the force of air resistance doesn't get any bigger. So the force of air resistance against a falling feather can't be greater than the weight of the feather. But the force of air resistance against a falling elephant can be, and undoubtedly is, greater than the weight of a feather.
Yes falling objects do have air resistance. They have even more if they have a larger surface area.
The speed when falling objects no longer accelerates due to air resistance is the maximum falling velocity.
Neglecting air resistance his velocity after 1 second will be 9.81 m/sec or 32.2 ft/sec.
storm in which there is considerable falling and blowing snow
The object will be falling at 49 m/s.This is solved by multiplying the force of gravity (9.8 m/s) by the time you're calculating (5s).
Neglecting the effect of air resistance, the speed of any falling object ... including ice cubes ... is always 32.2 feet per second greater than it was one second earlier.
The speed at which a 200 pound man falls from a 3-story building would be approximately 53 meters per second when neglecting air resistance. This speed is calculated using the formula v = sqrt(2gh), where v is the final velocity, g is the acceleration due to gravity (9.81 m/s^2), and h is the height of the building (around 9 meters for a 3-story building).
Neglecting air resistance, a body falling freely near the earth's surface falls with an acceleration of 9.8 meters (32.2 feet) per second per second, regardless of how big, small, light, or heavy it is.
The gravitational pull on the falling man and the wind resistance acting against the fall.
A falling elephant encounters a greater force of air resistance than a falling feather does. The force of air resistance can't be greater than the weight of the falling object. When the force of air resistance is equal to the weight of the falling object, the object stops accelerating, its falling speed becomes constant, and the force of air resistance doesn't get any bigger. So the force of air resistance against a falling feather can't be greater than the weight of the feather. But the force of air resistance against a falling elephant can be, and undoubtedly is, greater than the weight of a feather.
distance = 1/2 g t^2 = 1/2 x 32.2 x 5 x 5 = 405 feet (neglecting air resistance)
Air resistance creates friction and slows a falling object.
Blizzard
it is a blizzard