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Unit 5 Notes. ∑F = ma ∑F y = Upward Forces – Downward Forces = ma y ∑F x = Forces to Right – Forces to Left = ma x (∑ means the summation) ∑F is the net.

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Presentation on theme: "Unit 5 Notes. ∑F = ma ∑F y = Upward Forces – Downward Forces = ma y ∑F x = Forces to Right – Forces to Left = ma x (∑ means the summation) ∑F is the net."— Presentation transcript:

1 Unit 5 Notes

2 ∑F = ma ∑F y = Upward Forces – Downward Forces = ma y ∑F x = Forces to Right – Forces to Left = ma x (∑ means the summation) ∑F is the net force.

3 ∑F = F net ∑F = ma *Keep in mind that a positive net force means acceleration in the positive direction *A negative net force means acceleration in the negative direction

4 Example: A 50kg person in an elevator accelerates upward at 2 m/s 2. Solve for the normal force. ∑F y = F N + F g =ma F N + (50kg * -9.8N/kg) = 50kg * 2 m/s 2 F N – 490N = 100N F N = 590N

5 Example 2 A 70 kg para-sailer gets pulled by a cable that makes a 45 degree angle with horizontal. If the person’s acceleration is 3m/s/s straight forward, and the tension in the cable is 500N, solve for the drag force. What is the lift provided by the parachute?

6 ∑F x = F x + F wind/Person = ma x -500N * cos(45) + F wind/Person = 70kg * -3m/s/s -353N + F wind/Person = -210N F wind/Person = 243N

7 ∑F y = F y + F parachute/Person + F g = 0 -500N * sin(45) + F parachute/Person + 70*9.8 = 0 -353N + F parachute/Person + 686N = 0 F parachute/Person = 333N

8 Forces and Kinematics

9 Example A 50kg track star uniformly accelerates as he runs the first 25m in his race. Calculate the force necessary for him to run this in 4s. Since we’re calculating force, we should start with kinematics.

10 a=? x=40m x 0 =0 v 0 =0 t=4s

11 Two-Body Problems If two objects are connected so that they have the same acceleration, it can be useful to think of them as a system. ∑F system = m sys a

12 Example A 2kg mass hangs off a table. A 6kg block is on the table. Assume friction is negligible. 1) Solve for the acceleration of the block and mass. 2) Solve for the tension in the cable.

13 The force causing the block and mass to accelerate is the force of gravity on the hanging mass, so ∑F system = F g,mass = m sys a (2kg)(-9.8N/kg) = (8kg)a a=-2.45m/s/s

14 To solve for the tension, look at either the individual mass or the individual block. I chose the block. ∑F block = m block a = F Cable/block F Cable/block = (2kg) (-2.45m/s/s) F Cable/block = -4.9N

15 Alternatively, using the mass should yield the same result. Be careful of the signs. The mass is accelerating downward, which I have defined to be negative in this case. ∑F mass = F g + F Cable/mass =m a (2kg)(-9.8N/kg) + F Cable/mass =(2kg)(-2.45m/s/s) -19.6N + F Cable/mass = -4.9N F Cable/mass = 24.5N

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