Concept Questions
... tangent to the circle of radius r as shown in the figure below with v 0 The angular velocity vector points in the k̂ direction, given by r z k̂ (v / r) k̂ ...
... tangent to the circle of radius r as shown in the figure below with v 0 The angular velocity vector points in the k̂ direction, given by r z k̂ (v / r) k̂ ...
Chapter 2 KINETICS OF PARTICLES: NEWTON`S SECOND LAW
... There should be a force in a different direction than the radial direction F ...
... There should be a force in a different direction than the radial direction F ...
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... accelerate around ist own CM under the influence of gravitational force and it only can have linear (translational) acceleration. If we now choose another pivot point that does not coincide with CM, then the torque will be nonzero, the lever arm being defined by the distance between CM and the pivot ...
... accelerate around ist own CM under the influence of gravitational force and it only can have linear (translational) acceleration. If we now choose another pivot point that does not coincide with CM, then the torque will be nonzero, the lever arm being defined by the distance between CM and the pivot ...
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... vA2 x vB 2 x 300 m/s 2 320 m/s The 0.150 kg glider (A) is moving to the left at 3.20 m/s and the 0.300 kg glider (B) is moving to the left at 0.20 m/s. EVALUATE: We can use our v A2 x and vB 2 x to show that Px is constant and K1 K2 IDENTIFY: When the spring is compressed the maximum amou ...
... vA2 x vB 2 x 300 m/s 2 320 m/s The 0.150 kg glider (A) is moving to the left at 3.20 m/s and the 0.300 kg glider (B) is moving to the left at 0.20 m/s. EVALUATE: We can use our v A2 x and vB 2 x to show that Px is constant and K1 K2 IDENTIFY: When the spring is compressed the maximum amou ...
