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A 63 kg skier is coasting up the hill shown below with speed vi = 14 m/s. Figure 7.37 The skier's initial kinetic energy is partially used in coasting to the top of a rise. What is the final speed on top of the rise assuming that there is no friction acting? m/s. Instead, assume that friction acts only on the straight line part of the rise and that the coefficient of friction is 0.21. What is the length of the straight line part of the rise? m. What is the normal force acting on skier during the straight line part of the rise? N. What is the final speed on top of the rise assuming that friction acts only during the straight line part? m/s.

A 63 kg skier is coasting up the hill shown below with speed vi = 14 m/s. Figure 7.37 The skier's initial kinetic energy is partially used in coasting to the top of a rise. What is the final speed on top of the rise assuming that there is no friction acting? m/s. Instead, assume that friction acts only on the straight line part of the rise and that the coefficient of friction is 0.21. What is the length of the straight line part of the rise? m. What is the normal force acting on skier during the straight line part of the rise? N. What is the final speed on top of the rise assuming that friction acts only during the straight line part? m/s.

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A 63 k g skier is coasting up the hill shown below with speed vi = 14 m / s . Figure 7.37 The skier's initial kinetic energy is partially used in coasting to the top of a rise.
What is the final speed on top of the rise assuming that there is no friction acting?
Number m / s .
Instead, assume that friction acts only on the straight line part of the rise and that the coefficient of friction is 0.21 .
What is the length of the straight line part of the rise? Number m.
What is the normal force acting on skier during the straight line part of the rise? Number N .
What is the final speed on top of the rise assuming that friction acts only during the straight line part? Number m / s .

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