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How could the experiment be modified to study the acceleration of a free falling body?
To study the acceleration of a free-falling body, you could modify the experiment by using a motion sensor to measure the position of the falling object at different time intervals. By collecting data on the position of the object over time, you can calculate the acceleration using the formula a = 2*(d/t^2), where a is acceleration, d is distance fallen, and t is time elapsed. This data can help you analyze the acceleration of the free-falling body accurately.
How fast is the acceleration of a falling body?
The acceleration of a falling body due to gravity is approximately 9.81 m/s^2, often rounded to 10 m/s^2 for simplicity. This means that the speed of a falling body increases by 9.81 meters per second every second.
How do you calculate the acceleration of gravity?
The acceleration of gravity can be calculated using the formula a = 9.81 m/s^2, where "a" represents the acceleration due to gravity. This value is a constant for objects falling in Earth's gravitational field.
How do you calculate the acceleration of falling objects?
You can calculate the acceleration of a falling object using the formula a = g, where "a" is the acceleration and "g" is the acceleration due to gravity (approximately 9.81 m/s^2 on Earth). This formula assumes the object is in free fall with no other forces acting on it.
What is constant for freely falling body?
The acceleration due to gravity is constant for a freely falling body. This means that the object will experience a constant acceleration of 9.81 m/s^2 (on Earth) in the downward direction, regardless of its mass. This allows us to predict the motion of the object using equations of motion.
What is the acceleration of falling body at 0.5 seconds?
acceleration of a falling body is 9.8m/s*s and its direction is vertically downward.
How could the experiment be modified to study the acceleration of a free falling body?
To study the acceleration of a free-falling body, you could modify the experiment by using a motion sensor to measure the position of the falling object at different time intervals. By collecting data on the position of the object over time, you can calculate the acceleration using the formula a = 2*(d/t^2), where a is acceleration, d is distance fallen, and t is time elapsed. This data can help you analyze the acceleration of the free-falling body accurately.
Is the constant acceleration of a free falling body?
YES
How fast is the acceleration of a falling body?
The acceleration of a falling body due to gravity is approximately 9.81 m/s^2, often rounded to 10 m/s^2 for simplicity. This means that the speed of a falling body increases by 9.81 meters per second every second.
How do you calculate the acceleration of gravity?
The acceleration of gravity can be calculated using the formula a = 9.81 m/s^2, where "a" represents the acceleration due to gravity. This value is a constant for objects falling in Earth's gravitational field.
What is the formula for the acceleration of a free falling body?
A - 9.8m/s2
How do you calculate the acceleration of falling objects?
You can calculate the acceleration of a falling object using the formula a = g, where "a" is the acceleration and "g" is the acceleration due to gravity (approximately 9.81 m/s^2 on Earth). This formula assumes the object is in free fall with no other forces acting on it.
What is the direction of the acceleration of a freely falling body?
9.8 m/s2
What is constant for freely falling body?
The acceleration due to gravity is constant for a freely falling body. This means that the object will experience a constant acceleration of 9.81 m/s^2 (on Earth) in the downward direction, regardless of its mass. This allows us to predict the motion of the object using equations of motion.
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.
Are the directions of the velocity and acceleration of a falling body the same?
Yes, both are directed downward.
What is the effect of distance of freely falling body from the centre of earth on gravitational acceleration?
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