Kinematics – Part A Physics 30S
What is Kinematics? Kinematics describes the motion of objects. How do things move? What is displacement, velocity and acceleration?
Outcomes S4P-1-1 Derive the special equations for constant acceleration. Include: S4P-1-2 Solve problems for objects moving in a straight line with a constant acceleration. Include: S4P-1-3 Solve relative motion problems for constant velocities using vectors.
The Big 4
Derivation of Big 4 See Derivation of Big 4.pdf Derivation Notes S4P-1-1 Derive the special equations for constant acceleration. Include:
What are the Big Ideas of the Derivation?
Problem Solving Step 1: Identify what is given Step 2: Identify what is asked Step 3: Select an equation Step 4: Solve Step 5: Sig Figs!
Question 1 An airplane accelerates from rest down a runway at 3.20 m/s2 for 32.8 s until is finally lifts off the ground. Determine the distance traveled before takeoff. a = +3.2 m/s2 t = 32.8 s vi = 0 m/s Find d = ?? d = (0 m/s)*(32.8 s)+ 0.5*(3.20 m/s2)*(32.8 s)2 d = 1720 m
Question 2 A car starts from rest and accelerates uniformly over a time of 5.21 seconds for a distance of 110 m. Determine the acceleration of the car. d = 110 m t = 5.21 s vi = 0 m/s Find: a = ?? 110 m = (0 m/s)*(5.21 s)+ 0.5*(a)*(5.21 s)2 110 m = (13.57 s2)*a a = (110 m)/(13.57 s2) a = 8.10 m/s2 a = 8.1 m/s2
Question 3 A race car accelerates uniformly from 18.5 m/s to 46.1 m/s in 2.47 seconds. Determine the acceleration of the car and the distance traveled. vi = 18.5 m/s vf = 46.1 m/s t = 2.47 s Find: d = ?? a = ?? d = (18.5 m/s+ 46.1 m/s)(0.5)(2.47 s) d = 79.8 m 46.1 m/s = 18.5 m/s + (a)(2.47 s) a = 11.2 m/s2
2 Part Questions Are there other ways to solve? Yes, but... Don’t use calculated values for 2nd part questions wherever possible! Calculation errors can carry over into later questions Can run into rounding problems if you use significant figure value
Question 4 A bike accelerates uniformly from rest to a speed of 7.10 m/s over a distance of 35.4 m. Determine the acceleration of the bike. vi = 0 m/s vf = 7.10 m/s d = 35.4 m Find: a = ?? (7.10 m/s2)2 = (0 m/s)2 + 2*(a)*(35.4 m) a = 0.712 m/s2
Homework Big 4 Problems Handout Leave out #3
Acceleration due to Gravity Acceleration due to gravity on earth: a = -9.8 m/s2 Use this value in calculations as acceleration Acceleration due to gravity is different on other planets, so watch out for location! More to come later
Question 1 Acceleration due to gravity: a = -9.8 m/s2 Upton Chuck is riding the Giant Drop at Great America. If Upton free falls for 2.6 seconds, what will be his final velocity and how far will he fall? a = -9.8 m/s2 t = 2.6 s vi = 0 m/s Find: d = ?? vf = ?? d = (0 m/s)*(2.6 s)+ 0.5*(-9.8 m/s2)*(2.6 s)2 d = 33 m vf = vi + a*t vf = 0 + (-9.8 m/s2)*(2.6 s) vf = -25.5 m/s (- indicates direction)
Question 2 A kangaroo is capable of jumping to a height of 2.62 m. Determine the takeoff speed of the kangaroo. a = -9.8 m/s2 vf = 0 m/s d = 2.62 m Find: vi = ?? (0 m/s)2 = vi2 + 2*(-9.8 m/s2)*(2.62 m) vi = 7.17 m/s
Question 3 A feather is dropped on the moon from a height of 1.40 meters. The acceleration of gravity on the moon is 1.67 m/s2. Determine the time for the feather to fall to the surface of the moon. vi = 0 m/s d = -1.40 m a = -1.67 m/s2 Find: t = ?? d = (0 m/s)*(t)+ 0.5*(-1.67 m/s2)*(t)2 t = 1.29 s
Homework Physics, Concepts and Conceptions Big 4 Handout #3
Interval Questions 2 Big 4 questions rolled into 1 Must be worked out in intervals Different accelerations during different phases of the questions What happened during the first acceleration? What happened during the second acceleration? Very important – Label your intervals clearly!
Question 1 Otto Emissions is driving his car at 25.0 m/s. Otto accelerates at 2.0 m/s2 for 5.00 seconds. Otto then maintains a constant velocity for 10.0 more seconds. Calculate the total distance traveled during the entire 15 seconds. Given: Interval 1 vi = 25.0 m/s t = 5.00 s a = 2.0 m/s2 Find: d = ?? Interval 2 t = 10.0 s a = 0.0 m/s2 d = 500. m
Question 2 Vera Side is speeding down the interstate at 45.0 m/s when she observes a pileup in the middle of the road. When she first sees the accident, she is 80.0 m from the pileup. She slows down at a rate of -10.0 m/s2. Assuming it will take her 0.0500 s to hit the brakes, determine the distance which Vera Side would travel prior to reaching a complete stop (if she did not collide with the pileup). Will Vera hit the cars in the pileup? Total distance: 104 m Since the accident pileup is less than 103 m from Vera, she will indeed hit the pileup before completely stopping (unless she veers aside).
Homework Interval Questions handout
2 Object Problems 2 different objects, each with its own velocity and acceleration Usually there is one quantity which is shared by both objects Same distance to travel, must catch up with each other, etc. Keep clear which quantities belong to which object! Draw a picture!
Question 1 Fred and his friend Barney are at opposite ends of a 1.0 km long drag strip. Fred accelerates from rest toward Barney at 2.0 m/s2. Barney travels toward Fred at a constant speed of 10 m/s. How much time elapses before Fred and Barney collide? t = 27 s
Question 2 Jack, who is running at 6.0 m/s to catch a bus, sees it start to move when he is 20.0 m away from it. If the bus accelerates at 1.0 m/s2, will Jack overtake it? If so, how long will it take him? Jack misses the bus!
Homework Physics, Concepts and Conceptions Pg.75 #66, 67, 68
Relative Motion Relative motion occurs when an object appears to have one motion to one observer and a different motion to a second observer. Observers are moving relative to each other Examples: Boat crossing a river Airplane flying through the air 2 cars on the highway
Relative Motion – What to Do? Velocity of the object relative to the ground is equal to the velocity of the object relative to the medium plus the vector sum of the velocity of the medium relative to the ground. AKA: Vector sums are back!!!!
Question 1 A sports car is travelling east on Highway #1 at 140 km/h and a semi is travelling west on the same highway at 110 km/h. a) If you were in the sports car, what is the apparent velocity of the truck? 250 km/h, W b) If you were the truck driver, what is the apparent velocity of the sports car? 250 km/h, E
Question 2 A sports car is travelling east on Highway #1 at 140 km/h and a semi is travelling east on the same highway at 110 km/h. a) If you were in the sports car, what is the apparent velocity of the truck? 30 km/h, W b) If you were the truck driver, what is the apparent velocity of the sports car? 30 km/h, E c) If you are a police office parked at the side of the road, what is the apparent velocity of both vehicles? Sports car: 140 km/h, E Semi: 110 km/h, E
What about Kinematics? Kinematics equations (and classical mechanics in general) are valid for non-inertial reference frames Can’t use if you’re accelerating and observing motion
Question 3 A boat is crossing a river at 2.00 m/s, N relative to the water. The river has a current of 2.00 m/s, E relative to the shore. What is the velocity of the boat relative to the shore?
Homework Physics, Concepts and Conceptions P. 116 #35, 36,
Review Create a foldable highlighting each of the Big 4 Equations! Outside Variables Used: Variables Not Present: Sample Problem & Solution: Inside
Review Continued Kinematics Review worksheet Relative Motion and Interval Questions handout
Where Do I Find More Questions? Derivations Go over derivations! General Big 4 Questions Big 4 Examples Handout Foldable Acceleration due to Gravity Review Worksheet Interval questions Relative Motion and Intervals Handout 2 Object Problems Big 4 Examples Handout #7 Review worksheet Relative Motion
The plan 1 – Derivation 2 – Problem Solving & 2 Part Questions 3 - Acceleration due to Gravity 4 – Interval questions 5 – 2 Object Problems 6 – Relative Motion 7 – Review 8 - Test