2.Newtonian Dynamics:A 3.0kg weight W is initially atrest on incline AB, which israised 40° above the horizontal.The effective coefficient isu=0.3. Through frictionlesspulley and strings of negligiblemass, a small mass P, 400g, is atrest on a 200g weighting pan.Draw a free body diagram representing the situation, and use itto determine the acceleration of the system.Use the value of acceleration calculated to determine therelative weight of P in pounds.

Given: The mass on the inclined plane is m=3 kg. The friction coefficient is μ=0.3. The inclination…

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Pls answer asap. Thank you Note: Computation must be complete and answer in 2 decimal places.
A 2.00-kg object B is connected with a string to a 3.00-kgobject A, which is connected with a second string over a massless, frictionless pulley to a 8.00-kg object C. The strings have negligible mass and do not stretch, and the level tabletop is frictionless. Calculate the tension ?1. ?1= N Calculate the tension ?2. ?2= N Calculate the acceleration ? of the system. ?= m/s2
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1) The block on a 60° inclined plane weighs 100 pound and is held by the minimum possible force T as shown in the figure. The coefficient of both static and kinetic friction between the block and the inclined plane is 0.2, and the pulleys are frictionless. T а. Draw the free body diagram (FBD) of the block showing all forces and their directions acting on it. b. Compute all unknown forces including T shown in your FBD. Now if you want to move the block upward on the inclined plane С. by applying minimum possible force T then draw the FBD of the block showing all forces with directions acting on it. d. Now assume the pulleys are stuck (do not rotate any more) and the 60° rope slides over the stuck pulleys as the block moves up. the coefficient of both static and kinetic friction between the pulley surface and the rope is 0.1. Draw the FBD of the block showing all forces with directions acting on the block when the block is pulled upward by the minimum rope force T. е. For the stuck…