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Lecture 07 Dynamics and Relative Velocity Problem Solving: Dynamics Examples Relative Velocity Dynamics Problem Solving Draw a Free Body Diagram (FBD) for each Object down F = ma for each Object in each Direction Write Solve for the Unknown(s) Dynamics Example 1 Two boxes of mass 5 kg and 10 kg are pushed across a floor (with coefficient of friction of = 0.2) by a force of 50 N. What is the force each block exerts on the other and the acceleration of each block? Box 2 FBD: Box 1 FBD: FN FN y F21 FP Ff Fg F12 Ff x Fg Dynamics Example 1 Two boxes of mass 5 kg and 10 kg are pushed across a floor (with coefficient of friction of = 0.2) by a force of 60 N. What is the force each block exerts on the other and the acceleration of each block? Box 1 F=ma Box 2 F=ma x-direction: x-direction: FP – Ff – F = m1a1 F – Ff = m2a2 y y-direction: FN – Fg = 0 x y-direction: FN – Fg = 0 Dynamics Example 1 Two boxes of mass 5 kg and 10 kg are pushed across a floor (with coefficient of friction of = 0.2) by a force of 60 N. What is the force each block exerts on the other and the acceleration of each block? Box 1 Box 2 FP – Ff – F = m1a F – Ff = m2a FP – FN – F = m1a F – FN = m2a FP – m1g – F = m1a F – m2g = m2a Dynamics Example 1 Two boxes of mass 5 kg and 10 kg are pushed across a floor (with coefficient of friction of = 0.2) by a force of 50 N. What is the force each block exerts on the other and the acceleration of each block? Solve each equation for acceleration and set them equal: Solve for F (the force each block exerts on the other): Solve for a (the acceleration of the blocks): FP m1 g F F m2 g m1 m2 FP m2 F m1 m2 33.3 N FP m1 g m2 g a 1.4 m/s2 m1 m2 Dynamics Example 2 A box of mass 3 kg is pulled on a smooth (frictionless) surface by a second block of mass 2 kg hanging over a pulley. What is the acceleration of each block and tension in the string connecting them? Box 2 FBD: Box 1 FBD: FT FN y FT Fg x Fg note: the tension is the same everywhere in the string Dynamics Example 2 A box of mass 3 kg is pulled on a smooth (frictionless) surface by a second block of mass 2 kg hanging over a pulley. What is the acceleration of each block and tension in the string connecting them? Box 1 F=ma Box 2 F=ma x-direction: FT = m1a1 y-direction: FN – Fg = 0 y-direction: y FT – Fg = m2a2 x FT – m2g = m2a2 Dynamics Example 2 A box of mass 3 kg is pulled on a smooth (frictionless) surface by a second block of mass 2 kg hanging over a pulley. What is the acceleration of each block and tension in the string connecting them? Substitute the expression for tension from Box 1 into the Box 2 equation: Solve for a (the acceleration of the blocks): Solve for FT (the the tension in the string): m1a m2 g m2 a m2 g a 3.92 m/s2 m1 m2 m1m2 g FT 11.76 N m1 m2 Relative Velocity Sometimes your velocity is known relative to a reference frame that is moving relative to the earth. Example 1: a boat moving relative to water, which is then moving relative to the ground. Example 2: a plane moving relative to air, which is then moving relative to the ground. These velocities are related by vector addition: vac vab v bc » vac is the velocity of the object relative to the ground » vab is the velocity of the object relative to a moving reference frame » vbc is the velocity of the moving reference frame relative to the ground Relative Motion Example You are in a plane traveling (relative to still air) at 200 mph at an angle of 30º east of north. There is a wind blowing 50 mph due east (relative to the ground). What is the velocity of the plane with respect to the ground? 200 mph 50 mph y x 30º Relative Motion Example You are in a plane traveling (relative to still air) at 200 mph at an angle of 30º east of north. There is a wind blowing 50 mph due east (relative to the ground). What is the velocity of the plane with respect to the ground? To find the velocity with respect to the ground we just need to add the velocity of the plane with respect to the air to the velocity of the air with respect to the ground: v pg v pa v ag vag vpa vpg Relative Motion Example You are in a plane traveling (relative to still air) at 200 mph at an angle of 30º east of north. There is a wind blowing 50 mph due east (relative to the ground). What is the velocity of the plane with respect to the ground? Break the plane’s velocity (with respect to the air) into components. Add the respective components together to attain the x- and y- components of the net velocity we are looking for! x-direction: vpgx = vpax + vagx y-direction: vpgy = vpay + vagy vpgx = (200 mph)sin30º + (50 mph) vpgy = (200 mph)cos30º + (0 mph) vpgx = 150 mph vpgy = 173 mph Relative Motion Example You are in a plane traveling (relative to still air) at 200 mph at an angle of 30º east of north. There is a wind blowing 50 mph due east (relative to the ground). What is the velocity of the plane with respect to the ground? With the components of the net velocity known, find the magnitude and direction of the velocity! 150 mph 173 mph vpg Vpg = 229 mph = 41º Summary of Concepts X and Y directions are Independent! F = ma applies in both x and y direction Relative Motion (add vector components) vag 200 mph 50 mph vpg 30º 50 mph 173 mph vpg vpa