Both objects would strike the ground at the same moment. This is because gravity acts as an independent (unrelated to the forward movement of the car) force downwards. The force of gravity remains unchanged between both balls also.
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.
A rock that is dropped, and a apple falling from a tree.Hold a ball in your hand, stretch out your arm, and drop the ball. As it is moving towards the ground, it is in free fall.
Yes , there is a relationship between height and speed . Which is that to get fast we need to be tall . Height isn't anything weight can slow you down so speed also consists of height that is the relationship between speed and height
If it was thrown horizontally or dropped, and hit the ground 3.03 seconds later, then it hit the ground moving at a speed of 29.694 meters (97.42-ft) per second. If it was tossed at any angle not horizontal, and hit the ground 3.03 seconds later, we need to know the direction it was launched, in order to calculate the speed with which it hit the ground.
The speed of an object falling due to gravity can be calculated using the equation v = √(2gh), where g is the acceleration due to gravity (approximately 9.8 m/s²), and h is the height of the tree (100 m). Plugging in the values, we find that the sequoia cone would be moving at approximately 44.3 m/s when it reaches the ground.
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.
A rock that is dropped, and a apple falling from a tree.Hold a ball in your hand, stretch out your arm, and drop the ball. As it is moving towards the ground, it is in free fall.
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.
Yes , there is a relationship between height and speed . Which is that to get fast we need to be tall . Height isn't anything weight can slow you down so speed also consists of height that is the relationship between speed and height
Depth. To ascend is to go up, and to descend is go down. We measure the height of things above the ground and the depth of things below the ground.
If it was thrown horizontally or dropped, and hit the ground 3.03 seconds later, then it hit the ground moving at a speed of 29.694 meters (97.42-ft) per second. If it was tossed at any angle not horizontal, and hit the ground 3.03 seconds later, we need to know the direction it was launched, in order to calculate the speed with which it hit the ground.
The speed of an object falling due to gravity can be calculated using the equation v = √(2gh), where g is the acceleration due to gravity (approximately 9.8 m/s²), and h is the height of the tree (100 m). Plugging in the values, we find that the sequoia cone would be moving at approximately 44.3 m/s when it reaches the ground.
20 meters per second
The top of the hitch ball should be aprox 19-20 inches from the ground.
It is air friction. An aeroplane flying into a headwind will use up much more fuel than an aeroplane flying with a tailwind. Air friction means that a feather would take much longer to reach the ground than a lead weight dropped from the same height. Yet, if the feather and the lead weight were to be dropped in a vacuum (not subjected to air resistance) they would both reach the ground at the same time.
If a cup of water is dropped, the water will tend to stay inside the cup momentarily due to inertia. However, once the cup hits the ground and stops moving, the water will then spill out of the cup due to the lack of support from the container.
Sure. Cyclists are moving at speed, with their heads at a height above ground. If they fall, they may bang their heads.