Ch. 7 Forces and Motion in Two Dimensions Milbank High School
Sec. 7.1 Forces in Two Dimensions Objectives Determine the force that produces equilibrium when three forces act on an object Analyze the motion of an object on an inclined plane with and without friction
What is meant by two dimensions? Consider a golf ball being hit out of a sand trap It has a horizontal force AND a vertical force We can solve for many different things using a combination of forces and vectors Height of the ball Time in the air Velocity when it hits the ground
Equilibrant A force exerted on an object to produce equilibrium Same magnitude as the resultant force but opposite in direction
Solving problems in two dimensions Draw it out! Rearrange vectors to form a triangle if possible Solve for the resultant vector Opposite in direction Example Problem Pg. 151
Sec. 7.2 Projectile Motion Objectives Recognize that the vertical and horizontal motions of a projectile are independent Relate the height, time in the air, and the initial velocity of a projectile using its vertical motion, then determine the range. Explain how the shape of the trajectory of a moving object depends upon the frame of reference from which it is observed.
Projectiles have independent motions! Projectiles have two velocities, one in the “x” direction, and one in the “y” direction x is always constant y will be changing due to the acceleration due to gravity
Displacement y displacement x displacement x = vxot v = 25m/s y = yo - 1/2gt2 x displacement x = vxot v = 25m/s
Velocity of projectiles launched horizontally vx = initial velocity vy = (-g)t v = resultant velocity vector Example Pg. 157
Effects of air resistance We ignore the effects of air resistance for these problems Sometimes it would make a large difference, other times it wouldn’t Many projectiles modified so that they reduce air resistance
Projectiles launched at an Angle Usually given angle of launch and velocity What do we have to find? Maximum height Range Horizontal distance Flight time hang time
Projectiles Launched at an Angle Two initial velocity components vxo vyo How do we find these? vx = vo(cosθ) vy = vo(sinθ)
Projectiles Launched at an Angle tup = vyo/g ttotal = 2(tup) Peak Height y = vyot - ½gt2 Range R = vxot
Projectiles launched at an Angle The Flight of a Ball Example Problem Pg. 159
Sec. 7.3 Circular Motion Objectives Explain the acceleration of an object moving in a circle at constant speed Describe how centripetal acceleration depends upon the object’s speed and the radius of the circle Recognize the direction of the force that causes centripetal acceleration Explain how the rate of circular motion is changed by exerting torque on it.
Uniform Circular Motion Movement of an object at constant speed around a circle with a fixed radius Merry-go-round Circumference = 2*pi*Radius
Vectors
Acceleration Which direction? Always towards the center
Centripetal Force “Center seeking” Net force towards the center that causes the object to try to seek the center What force is pulling it in? As a bucket of water is tied to a string and spun in a circle, the force of tension acting upon the bucket provides the centripetal force required for circular motion.
Net Force
Example Problem Pg. 165