Still accelerating til it hits earth. ====================================== The height from which she dropped the ball is irrelevant. In any case, the ball was most likely moving at the greatest speed just as it hit the ground. The answer to the question is: zero.
The drag force exerted by the water on the diver rapidly decelerates the diver's speed after entering the water. This force opposes the motion of the diver and causes a quick decrease in speed. Additionally, the change in medium from air to water also affects the diver's speed.
This is completely unrelated to the height. An object at that mass, and speed, can be at any height.This is completely unrelated to the height. An object at that mass, and speed, can be at any height.This is completely unrelated to the height. An object at that mass, and speed, can be at any height.This is completely unrelated to the height. An object at that mass, and speed, can be at any height.
92 or 91.5 meters would be the maximum height.
16.1 or 16^^^ GIVE US AN ANSWER, NOT A OPTION. DOUBLE YOU- TEE- EFF
Initial upward speed = 7.61 m/sFinal upward speed (at the point of maximum height) = 0Time to reach maximum height = (7.61) / (9.8) = 0.77653 secondAverage speed during that time = 1/2 ( 7.61 + 0) = 3.805 m/sHeight = 3.805 x 0.77653 = 2.9547 meters (rounded) = about 9.7 feetDoesn't seem like much of a height for a strong toss; but the math looks OK.
The speed of an object falling from a great height is measured in meters per second per second until it reaches terminal velocity (maximum downward speed).
Well, let's take a moment to appreciate the beauty of this question. If we have a distance of 50 meters and it takes 5 seconds to cover that distance, we can find the speed by dividing the distance by the time. So, 50 meters divided by 5 seconds gives us a speed of 10 meters per second. Isn't that just a happy little calculation?
1000000 m
The height of a wave is the vertical distance between the wave's crest and trough. It is typically measured in meters, from peak to trough. The height of a wave can vary depending on factors such as wind speed, duration, and fetch.
The diver's potential energy at the top of the platform can be calculated using the formula: Potential Energy = mass x gravity x height. In this case, it will be: PE = 70 kg x 9.81 m/s^2 x 3.0 m = 2053.1 J. At the top of the diving platform, the diver's potential energy is at its maximum and his kinetic energy is zero.
The speed of sound at 12000 meters above sea level is approximately 295 meters per second. Sound travels faster in colder temperatures and lower pressures, which are characteristics of higher altitudes.