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How is free fall related to acceleration?
during free fall of body the gravity of earth tries to attract the body as it applied equally to whole body ... so body do not experience any gravitational force and there is nothing present in the atmosphere to oppose the fall which results it have maximum acceleration during free fall....
What is the theory of the acceleration due to gravity?
The theory of acceleration due to gravity states that all objects near the Earth's surface fall towards it with an acceleration of approximately 9.81 m/s^2. This acceleration is constant for all objects regardless of their mass, as long as air resistance is negligible. This theory is a fundamental concept in physics and explains the motion of objects in free fall.
What was the acceleration of the shuttlecock during its fall?
The acceleration of the shuttlecock during its fall would be equal to the acceleration due to gravity, which is approximately 9.8 m/s^2 in the absence of air resistance. This means that the shuttlecock would accelerate at a rate of 9.8 m/s^2 towards the ground.
Does acceleration increase or decrease during free fall?
Acceleration remains constant during free fall at approximately 9.81 m/s^2, assuming no significant air resistance. This is due to the force of gravity acting on the falling object, resulting in a uniform acceleration towards the Earth.
In free fall do all objects fall with the same acceleration?
yes, objects fall at a rate of 9.8m/swith acceleration. For every second in free fall you must add 9.8m/s to get the acceleration of an object.
Can an object in free fall have zero acceleration?
well if you consider the ISS as constantly falling at the same time its moving away from the earth so it dosnt hit the ground all objects have to be in acceleration for that sort of free fall. but a parajumper in a free fall dose not have any acceleration but using there body they can use arms and legs to direct the air in away that it pushes them forward or backward.
How does the mass of an object affect it' s acceleration during free fall?
The acceleration of an object during free fall is not affected by its mass. All objects near the surface of the Earth experience the same acceleration due to gravity, which is approximately 9.8 m/s^2. This means that regardless of their mass, objects will accelerate at the same rate when falling freely.
How would the observed value of acceleration be affected if the falling body used were heavier?
Your question describes it as a "falling body", so I'm assuming that you're asking about a body with no force on it except for the gravitational force. This is an important assumption. If it's true, then the mass (weight) of the falling body has no effect at all on its acceleration. Except for the effect of air resistance, all bodies fall with the same acceleration.
How does an object affect its accelration during free fall?
Without propellers, jets, or a parachute, an object can't to anything to affect its acceleration when it's falling. "Free fall" means moving under the influence of gravity only, with not even any air resistance. In that situation, on or near the surface of the Earth, acceleration is constant, regardless of the size, shape, mass, weight, or gender of the falling object. That number is 9.8 meters (32.2 feet) per second2 ... known as the acceleration of gravity on Earth.
What is Free Fall Balance?
A free fall balance is a device used to measure the acceleration due to gravity. It works by dropping a mass and measuring the time it takes to fall a certain distance. By analyzing this data, the acceleration due to gravity at that location can be calculated.
What is the effect of mass of freely falling body on the gravitational acceleration?
No effect whatsoever. Without air to interfere with the effects of gravity, a small feather and a large rock fall with the same acceleration.
How is the acceleration of an object in free-fall related to the acceleration due to gravity?
The acceleration of an object in free-fall is equal to the acceleration due to gravity, which is approximately 9.8 m/s^2 on the surface of the Earth. This means that objects in free-fall will experience an acceleration of 9.8 m/s^2 downwards, regardless of their mass.
