While watching the clouds pass by, you notice a European swallow flying horizontally at a height h = 21.1 m above you. When the swallow is directly overhead, it drops an m = 10.2 kg coconut. From your ornithological studies, you know that the air-speed of this particular species of swallow while carrying such a load is v0 = 7.97 m/s. In this problem you may neglect air friction. Refer to the diagram. Assume the origin of the coordinate system there is at your head. Calculate the magnitude of the angular momentum L, in kg ⋅ m2/s, of the coconut as observed by you at the moment it is released directly overhead
While watching the clouds pass by, you notice a European swallow flying horizontally at a height h = 21.1 m above you. When the swallow is directly overhead, it drops an m = 10.2 kg coconut. From your ornithological studies, you know that the air-speed of this particular species of swallow while carrying such a load is v0 = 7.97 m/s. In this problem you may neglect air friction. Refer to the diagram. Assume the origin of the coordinate system there is at your head. Calculate the magnitude of the angular momentum L, in kg ⋅ m2/s, of the coconut as observed by you at the moment it is released directly overhead
While watching the clouds pass by, you notice a European swallow flying horizontally at a height h = 21.1 m above you. When the swallow is directly overhead, it drops an m = 10.2 kg coconut. From your ornithological studies, you know that the air-speed of this particular species of swallow while carrying such a load is v0 = 7.97 m/s. In this problem you may neglect air friction. Refer to the diagram. Assume the origin of the coordinate system there is at your head. Calculate the magnitude of the angular momentum L, in kg ⋅ m2/s, of the coconut as observed by you at the moment it is released directly overhead
While watching the clouds pass by, you notice a European swallow flying horizontally at a height h = 21.1 m above you. When the swallow is directly overhead, it drops an m = 10.2 kg coconut. From your ornithological studies, you know that the air-speed of this particular species of swallow while carrying such a load is v0 = 7.97 m/s. In this problem you may neglect air friction. Refer to the diagram. Assume the origin of the coordinate system there is at your head.
Calculate the magnitude of the angular momentumL, in kg ⋅ m2/s, of the coconut as observed by you at the moment it is released directly overhead.
Calculate the magnitude of the angular momentum L, in kg ⋅ m2/s, of the coconut as observed by you one second after it is released directly overhead (t = 1 s).
Calculate the magnitude of the angular momentum L, in kg ⋅ m2/s,of the coconut as observed by you immediately before it hits the ground.
Definition Definition Product of the moment of inertia and angular velocity of the rotating body: (L) = Iω Angular momentum is a vector quantity, and it has both magnitude and direction. The magnitude of angular momentum is represented by the length of the vector, and the direction is the same as the direction of angular velocity.
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