Presentation is loading. Please wait.

Presentation is loading. Please wait.

Solving Word Problems Using Kinematics Equations.

Published byAnabel Chambers Modified over 8 years ago

Similar presentations

Presentation on theme: "Solving Word Problems Using Kinematics Equations."— Presentation transcript:

1 Solving Word Problems Using Kinematics Equations

2 Example Problem A fan cart takes 7.5 seconds to travel 4.0m from a standing start. How long will it take this same car to travel 6.0m, again from a standing start?

3 Equations Duration  t = t f – t i Displacement  x = x f –x i Avg Speed S avg = d /  t Avg Velocity v avg =  x/  t Avg Acceleration a avg =  v/  t

4 Kinematics Equations For Constant Acceleration  x = v i t + ½ at 2 v f = v i + at  x = ½(v i + v f )t V f 2 = v i 2 + 2a  x

5 Terms – Definitions -time- -duration- -position- -distance- -displacement- -speed- -velocity- -acceleration- Which of these terms relates two other terms?

6 Ex. From a stand-still, a train can cover 100m in 20 seconds. – What is the train’s acceleration? (assume it is constant) – With the same constant acceleration, how long would it take the train to complete 400m (a quarter mile) from a standing start?

7 Ex In the automotive industry, a 0.5g panic stop is the name for a situation when a driver slows the vehicle by ½ the acceleration due to gravity. That means the car is slowed by 4.9m/s/s. How far will it take a driver to execute a 0.5g panic stop from: – 25 mph? – 50 mph?

8 Motion With Constant Acceleration Part 2 1.a) a = 2m/s/s b) a = 4m/s/s 2. a = 0.4m/s/s 3.a) a = 3m/s/s b) a = 3m/s/s c) a = 3m/s/s 4.Invalid question! 5.Invalid Question!  t = 1.02s

9 Motion With Constant Acceleration Part 3 1.a) a=2m/s/s b) a=2m/s/s 2.a=-1.6m/s/s 3.a) a=-3.5m/s/s b)  x = 63m c)  x = 252m 4.v f = 56.4m/s 5.a = -5m/s/s OR 5m/s/s west 6.a) a = -6.67m/s/s b) S avg =20m/s c) t = 1.5s

Download ppt "Solving Word Problems Using Kinematics Equations."

Similar presentations

Motion and Force A. Motion 1. Motion is a change in position

Motion and Force A. Motion 1. Motion is a change in position
I have to solve for WHAT? Kinematics Equations.

I have to solve for WHAT? Kinematics Equations.
Area under a velocity-time graph Car travelling at 70 mph for 2 hours Area = This is the distance travelled, 140 miles 2  70 = 140 v mph t hours 0 2 70.

Area under a velocity-time graph Car travelling at 70 mph for 2 hours Area = This is the distance travelled, 140 miles 2  70 = 140 v mph t hours
Kinematics- Acceleration Chapter 5 (pg. 81-103) A Mathematical Model of Motion.

Kinematics- Acceleration Chapter 5 (pg ) A Mathematical Model of Motion.
2.2 Acceleration Physics A.

2.2 Acceleration Physics A.
Displacement Speed and Velocity Acceleration Equations of Kinematics with Constant A Freely Falling Bodies Graphical Analysis of Velocity and Acceleration.

Displacement Speed and Velocity Acceleration Equations of Kinematics with Constant A Freely Falling Bodies Graphical Analysis of Velocity and Acceleration.
Speed vs.Velocity Speed (s) is the distance an object travels per unit of time (rate). Speed (s) is the distance an object travels per unit of time (rate).

Speed vs.Velocity Speed (s) is the distance an object travels per unit of time (rate). Speed (s) is the distance an object travels per unit of time (rate).
Speed, Velocity and Acceleration What is speed? How is velocity different than speed? What is acceleration? Today’s Goal: Be able to use the proper equations.

Speed, Velocity and Acceleration What is speed? How is velocity different than speed? What is acceleration? Today’s Goal: Be able to use the proper equations.
Motion and Acceleration Notes Chapter 2 Section 1 and 2.

Motion and Acceleration Notes Chapter 2 Section 1 and 2.
Acceleration & Speed How fast does it go?. Definition of Motion Event that involves a change in the position or location of something.

Acceleration & Speed How fast does it go?. Definition of Motion Event that involves a change in the position or location of something.
Kinematics- Acceleration Chapter 5 (pg. 81-103) A Mathematical Model of Motion.

Kinematics- Acceleration Chapter 5 (pg ) A Mathematical Model of Motion.
Linear Motion. Objectives Understand the concept of relative motion. Know the distinction between distance and displacement. Understand the concepts of.

Linear Motion. Objectives Understand the concept of relative motion. Know the distinction between distance and displacement. Understand the concepts of.
How Far? _________ (d) ______________________________________ To get to the store go 2-miles east, turn right and go 3-miles south. How far will you travel.

How Far? _________ (d) ______________________________________ To get to the store go 2-miles east, turn right and go 3-miles south. How far will you travel.
 Acceleration is the rate that velocity changes over time.  An object is accelerating if ◦ Its speed changes ◦ Its direction changes ◦ Both its speed.

 Acceleration is the rate that velocity changes over time.  An object is accelerating if ◦ Its speed changes ◦ Its direction changes ◦ Both its speed.
Physics Physics: The study of forces, motion and energy Motion: Change in position over time compared to a reference point Reference Point: object used.

Physics Physics: The study of forces, motion and energy Motion: Change in position over time compared to a reference point Reference Point: object used.
STARTER During a road trip, in 6 hours you travel 300 miles. What is your average velocity? Average Velocity = distance travelled/time taken = 300 miles/6.

STARTER During a road trip, in 6 hours you travel 300 miles. What is your average velocity? Average Velocity = distance travelled/time taken = 300 miles/6.
Review av Are you going up or down? Are you speeding up or slowing down? What will your velocity be in 1 second?

Review av Are you going up or down? Are you speeding up or slowing down? What will your velocity be in 1 second?
Relationship between time, displacement, velocity, acceleration. Kinematic.

Relationship between time, displacement, velocity, acceleration. Kinematic.
 You can use weighted averages to solve uniform motion problems when the objects you are considering are moving at constant rates or speeds.

 You can use weighted averages to solve uniform motion problems when the objects you are considering are moving at constant rates or speeds.
Motion Chapter 2. What is motion? Describing Motion.

Motion Chapter 2. What is motion? Describing Motion.

Similar presentations

Ads by Google