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What additional information does Hannah need in order to calculate the tangential speed of the orbiting object?
To calculate the tangential speed of an orbiting object, Hannah would need to know the distance from the object to the center of the orbit (radius) and the time taken for the object to complete one full orbit. With this information, she can use the formula for tangential speed, which is tangential speed = 2πr / T, where r is the radius and T is the time taken for one orbit.
What is the tangential speed of a passenger on a Ferris wheel that has a radius of 15 m and rotates once in 40 s?
The tangential speed of a point on the outer rim of the wheel is (circumference) divided by (time per rotation) = (30 pi) / (40) = 2.356 meters per second. (rounded) The passenger's tangential speed depends on how close to the rim he sits. Anywhere on the wheel, it has to be 2.356 meters per second or less.
How can one determine the tangential velocity of an object in motion?
To determine the tangential velocity of an object in motion, you can use the formula: tangential velocity radius x angular velocity. The tangential velocity is the speed at which an object moves along its circular path. The radius is the distance from the center of the circle to the object, and the angular velocity is the rate at which the object rotates around the center. By multiplying the radius and angular velocity, you can calculate the tangential velocity of the object.
What happens to tangential speed as rotational speed increases?
we can say that tangential speed of the object is linearly proportional to the distance from the center. Increase in the distance results in the increase in the amount of speed. As we move to the center speed decreases, and at the center speed becomes zero.
What is the relationship between tangential velocity and circular motion?
In circular motion, tangential velocity is the speed at which an object moves along the circumference of the circle. It is perpendicular to the radius of the circle at any given point. The relationship between tangential velocity and circular motion is that the tangential velocity determines how fast an object is moving around the circle, while the radius of the circle affects the magnitude of the tangential velocity.
What additional information does Hannah need in order to calculate the tangential speed of the orbiting object?
To calculate the tangential speed of an orbiting object, Hannah would need to know the distance from the object to the center of the orbit (radius) and the time taken for the object to complete one full orbit. With this information, she can use the formula for tangential speed, which is tangential speed = 2πr / T, where r is the radius and T is the time taken for one orbit.
What is the tangential speed of a passenger on a Ferris wheel that has a radius of 15 m and rotates once in 40 s?
The tangential speed of a point on the outer rim of the wheel is (circumference) divided by (time per rotation) = (30 pi) / (40) = 2.356 meters per second. (rounded) The passenger's tangential speed depends on how close to the rim he sits. Anywhere on the wheel, it has to be 2.356 meters per second or less.
How can one determine the tangential velocity of an object in motion?
To determine the tangential velocity of an object in motion, you can use the formula: tangential velocity radius x angular velocity. The tangential velocity is the speed at which an object moves along its circular path. The radius is the distance from the center of the circle to the object, and the angular velocity is the rate at which the object rotates around the center. By multiplying the radius and angular velocity, you can calculate the tangential velocity of the object.
What happens to tangential speed as rotational speed increases?
we can say that tangential speed of the object is linearly proportional to the distance from the center. Increase in the distance results in the increase in the amount of speed. As we move to the center speed decreases, and at the center speed becomes zero.
What is the relationship between tangential velocity and circular motion?
In circular motion, tangential velocity is the speed at which an object moves along the circumference of the circle. It is perpendicular to the radius of the circle at any given point. The relationship between tangential velocity and circular motion is that the tangential velocity determines how fast an object is moving around the circle, while the radius of the circle affects the magnitude of the tangential velocity.
How can one determine the tangential acceleration of an object in motion?
To determine the tangential acceleration of an object in motion, you can use the formula: tangential acceleration radius x angular acceleration. The tangential acceleration represents the rate at which the object's speed is changing along its circular path.
What is tangential velocity and tangential acceleration?
Tangential velocity is the component of velocity that is perpendicular to the radial direction in circular motion. It represents the speed at which an object is moving along the circular path. Tangential acceleration is the rate at which the tangential velocity of an object changes, causing the object to speed up or slow down in its circular motion.
What is the tangential speed of a passenger car on a ferris wheel that has a radius of 10 meters and rotates once in 30 seconds?
2.09
How is the centripetal force on a rotating body affected if you double the radius and leave the tangential velocity the same?
If you double the radius while keeping the tangential velocity constant, the centripetal force will also double. This is because the centripetal force is directly proportional to the square of the velocity and inversely proportional to the radius. Therefore, doubling the radius increases the centripetal force required to keep the body rotating at the same speed.
What is the tangential speed of a passenger on a Ferris wheel that has a radius r10m and rotates once in 2 seconds?
The tangential speed of a passenger on a Ferris wheel can be calculated using the formula v = 2πr / T, where v is the tangential speed, r is the radius (10m in this case), and T is the time taken for one rotation (2 seconds). Plugging in the values, we get v = 2π*10 / 2 = 10π m/s ≈ 31.42 m/s.
If the maximum tension the rope can withstand before breaking is 126.8 N what is the maximum tangential speed the ball can have?
Not enough information. If the ball moves in a circle, you would also need the radius of the circle, and the mass of the ball.In this case, you can: 1) Calculate the corresponding centripetal acceleration, by using Newton's Second Law (a = F/m). 2) Calculate the tangential speed, using the formula for centripetal acceleration: acceleration = velocity squared / radius.
How is rotational speed affected by the radius?
Rotational speed is inversely proportional to the radius. A smaller radius will result in higher rotational speed, while a larger radius will result in lower rotational speed. This relationship is described by the equation v = rω, where v is linear speed, r is radius, and ω is angular velocity.
