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Apply the methods discussed to construct free-body diagrams for the situations
described below.
4. A rightward force is applied to a book in order to move it across a desk at constant
velocity. Consider frictional forces. Neglect air resistance. Diagram the forces acting on
the book.
5. A car is parked on a sloped street.

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Block 1 (20 kg) is pulled by a rope from left to right up a ramp which is inclined 50 degrees from the horizontal. The rope pulls on block 1 with a force of 400 N parallel to the surface of the inclined plane. The coefficient of kinetic friction between the block and the surface equals 0.4. (use g = 10 m/s2) On a sheet of paper, draw the free body diagram for block 1 using the two-subscript notation from class.Assume that the x-axis is parallel to the incline and positive in the direction up the incline.After completing the free body diagram, enter below each force and its x & y-components. FORCES on BLOCK 1 Weight force on block 1 by Earth W1E = i + j N Tension force on block 1 by Rope T1R = i + j N Normal force on block 1 by Surface N1S = i + j N Frictional force on block 1 by Surface f1S = i + j N What is the acceleration a of block 1? a = i + j m/s2
Refer to the picture below.
Please draw the free diagram clear and also add any force
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