Presentation is loading. Please wait.

Presentation is loading. Please wait.

Oct. 29, 2012 AGENDA: 1 – Bell Ringer 2 – Kinematics Equations 3 – Exit Ticket Today’s Goal: Students will be able to identify which kinematic equation.

Published bySilvester Montgomery Modified over 9 years ago

Similar presentations

Presentation on theme: "Oct. 29, 2012 AGENDA: 1 – Bell Ringer 2 – Kinematics Equations 3 – Exit Ticket Today’s Goal: Students will be able to identify which kinematic equation."— Presentation transcript:

1 Oct. 29, 2012 AGENDA: 1 – Bell Ringer 2 – Kinematics Equations 3 – Exit Ticket Today’s Goal: Students will be able to identify which kinematic equation to apply in each situation Homework 1. Pages 4-5

2 CHAMPS for Bell Ringer C – Conversation – No Talking H – Help – RAISE HAND for questions A – Activity – Solve Bell Ringer on binder paper. Homework out on desk M – Materials and Movement – Pen/Pencil, Notebook or Paper P – Participation – Be in assigned seats, work silently S – Success – Get a stamp! I will collect!

3 October 29th (p. 13) Objective: Students will be able to identify which kinematic equation to apply in each situation Bell Ringer: Let’s say two people are racing: The first person has a large initial velocity (20 m/s) but a slow acceleration (1 m/s 2 ). The other has a small initial velocity (0 m/s) but a large Acceleration (5 m/s 2 ). Who will win the race and why?

4 4 MINUTES REMAINING…

5 October 29th (p. 13) Objective: Students will be able to identify which kinematic equation to apply in each situation Bell Ringer: Let’s say two people are racing: The first person has a large initial velocity (20 m/s) but a slow acceleration (1 m/s 2 ). The other has a small initial velocity (0 m/s) but a large Acceleration (5 m/s 2 ). Who will win the race and why?

6 3 MINUTES REMAINING…

7 October 29th (p. 13) Objective: Students will be able to identify which kinematic equation to apply in each situation Bell Ringer: Let’s say two people are racing: The first person has a large initial velocity (20 m/s) but a slow acceleration (1 m/s 2 ). The other has a small initial velocity (0 m/s) but a large Acceleration (5 m/s 2 ). Who will win the race and why?

8 2 MINUTES REMAINING…

9 October 29th (p. 13) Objective: Students will be able to identify which kinematic equation to apply in each situation Bell Ringer: Let’s say two people are racing: The first person has a large initial velocity (20 m/s) but a slow acceleration (1 m/s 2 ). The other has a small initial velocity (0 m/s) but a large Acceleration (5 m/s 2 ). Who will win the race and why?

10 1minute Remaining…

11 October 29th (p. 13) Objective: Students will be able to identify which kinematic equation to apply in each situation Bell Ringer: Let’s say two people are racing: The first person has a large initial velocity (20 m/s) but a slow acceleration (1 m/s 2 ). The other has a small initial velocity (0 m/s) but a large Acceleration (5 m/s 2 ). Who will win the race and why?

12 30 Seconds Remaining…

13 October 29th (p. 13) Objective: Students will be able to identify which kinematic equation to apply in each situation Bell Ringer: Let’s say two people are racing: The first person has a large initial velocity (20 m/s) but a slow acceleration (1 m/s 2 ). The other has a small initial velocity (0 m/s) but a large Acceleration (5 m/s 2 ). Who will win the race and why?

14 BELL- RINGER TIME IS UP!

15 October 29th (p. 13) Objective: Students will be able to identify which kinematic equation to apply in each situation Bell Ringer: Let’s say two people are racing: The first person has a large initial velocity (20 m/s) but a slow acceleration (1 m/s 2 ). The other has a small initial velocity (0 m/s) but a large Acceleration (5 m/s 2 ). Who will win the race and why?

16 Shout Outs Period 5 – Period 7 –

17 Oct. 29, 2012 AGENDA: 1 – Bell Ringer 2 – Kinematics Equations 3 – Exit Ticket Today’s Goal: Students will be able to identify which kinematic equation to apply in each situation Homework 1. Pages 4-5

18 Week 8 Weekly Agenda Monday – Kinematic Equations I Tuesday – Kinematic Equations II Wednesday – Kinematic Equations III Thursday – Review Friday – Review Unit Test in 2 weeks!

19 CHAMPS for Problems p. 4-6 C – Conversation – No Talking unless directed to work in groups H – Help – RAISE HAND for questions A – Activity – Solve Problems on Page 4-6 M – Materials and Movement – Pen/Pencil, Packet Pages 4-6 P – Participation – Complete Page 4-6 S – Success – Understand all Problems

20 Notes: Kinematic Equations The Four Kinematic Equations: v f = v i + a Δ t Δx = v i Δt + aΔt 2 2 v f 2 = v i 2 + 2a Δx Δx = (v f + v i )Δt 2

21 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

22 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

23 Solving Problems (p. 4) 1. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. What is the final velocity of the Road Runner?

24 Solving Problems (p. 4) 1. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. What is the final velocity of the Road Runner?

25 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

26 Solving Problems (p. 4) 1. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. What is the final velocity of the Road Runner?

27 Solving Problems (p. 4) 1. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. What is the final velocity of the Road Runner? vi = 0 m/s a = 3 m/s 2 Δt = 10 seconds

28 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

29 Solving Problems (p. 4) 1. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. What is the final velocity of the Road Runner? vi = 0 m/s a = 3 m/s 2 Δt = 10 seconds

30 Solving Problems (p. 4) 1. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. What is the final velocity of the Road Runner? vi = 0 m/s a = 3 m/s 2 Δt = 10 seconds vf = ?

31 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

32 Notes: Kinematic Equations The Four Kinematic Equations: v f = v i + a Δ t Δx = v i Δt + aΔt 2 2 v f 2 = v i 2 + 2a Δx Δx = (v f + v i )Δt 2

33 Notes: Kinematic Equations The Four Kinematic Equations: v f = v i + a Δ t Δx = v i Δt + aΔt 2 2 v f 2 = v i 2 + 2a Δx Δx = (v f + v i )Δt 2

34 Solving Problems (p. 4) 2. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. How far does the Road Runner travel during the ten second time interval?

35 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

36 Solving Problems (p. 4) 2. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. How far does the Road Runner travel during the ten second time interval?

37 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

38 Solving Problems (p. 4) 2. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. How far does the Road Runner travel during the ten second time interval?

39 Solving Problems (p. 4) 2. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. How far does the Road Runner travel during the ten second time interval? vi = 0 m/s a = 3 m/s 2 Δt = 10 seconds

40 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

41 Solving Problems (p. 4) 2. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. How far does the Road Runner travel during the ten second time interval? vi = 0 m/s a = 3 m/s 2 Δt = 10 seconds

42 Solving Problems (p. 4) 2. Starting from rest, the Road Runner accelerates at 3 m/s 2 for ten seconds. How far does the Road Runner travel during the ten second time interval? vi = 0 m/s a = 3 m/s 2 Δt = 10 seconds Δx = ?

43 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

44 Notes: Kinematic Equations The Four Kinematic Equations: v f = v i + a Δ t Δx = v i Δt + aΔt 2 2 v f 2 = v i 2 + 2a Δx Δx = (v f + v i )Δt 2

45 Notes: Kinematic Equations The Four Kinematic Equations: v f = v i + a Δ t Δx = v i Δt + aΔt 2 2 v f 2 = v i 2 + 2a Δx Δx = (v f + v i )Δt 2

46 Solving Problems (p. 4) 3. A bullet starting from rest accelerates at 40,000 m/s 2 down a 0.5 m long barrel. What is the velocity of the bullet as it leaves the barrel of the gun?

47 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

48 Solving Problems (p. 4) 3. A bullet starting from rest accelerates at 40,000 m/s 2 down a 0.5 m long barrel. What is the velocity of the bullet as it leaves the barrel of the gun?

49 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

50 Solving Problems (p. 4) 3. A bullet starting from rest accelerates at 40,000 m/s 2 down a 0.5 m long barrel. What is the velocity of the bullet as it leaves the barrel of the gun?

51 Solving Problems (p. 4) 3. A bullet starting from rest accelerates at 40,000 m/s 2 down a 0.5 m long barrel. What is the velocity of the bullet as it leaves the barrel of the gun? vi = 0 m/s a = 40,000 m/s 2 Δx = 0.5 m

52 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

53 Solving Problems (p. 4) 3. A bullet starting from rest accelerates at 40,000 m/s 2 down a 0.5 m long barrel. What is the velocity of the bullet as it leaves the barrel of the gun? vi = 0 m/s a = 40,000 m/s 2 Δx = 0.5 m

54 Solving Problems (p. 4) 3. A bullet starting from rest accelerates at 40,000 m/s 2 down a 0.5 m long barrel. What is the velocity of the bullet as it leaves the barrel of the gun? vi = 0 m/s a = 40,000 m/s 2 Δx = 0.5 m vf = ?

55 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

56 Solving Problems (p. 4) 3. A bullet starting from rest accelerates at 40,000 m/s 2 down a 0.5 m long barrel. What is the velocity of the bullet as it leaves the barrel of the gun? vi = 0 m/s a = 40,000 m/s 2 Δx = 0.5 m vf = ?

57 Notes: Kinematic Equations The Four Kinematic Equations: v f = v i + a Δ t Δx = v i Δt + aΔt 2 2 v f 2 = v i 2 + 2a Δx Δx = (v f + v i )Δt 2

58 Notes: Kinematic Equations The Four Kinematic Equations: v f = v i + a Δ t Δx = v i Δt + aΔt 2 2 v f 2 = v i 2 + 2a Δx Δx = (v f + v i )Δt 2

59 Solving Problems (p. 4) 4. A car traveling at 20 m/s applies its brakes and comes to a stop in four seconds. What is the acceleration of the car?

60 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

61 Solving Problems (p. 4) 4. A car traveling at 20 m/s applies its brakes and comes to a stop in four seconds. What is the acceleration of the car?

62 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

63 Solving Problems (p. 4) 4. A car traveling at 20 m/s applies its brakes and comes to a stop in four seconds. What is the acceleration of the car?

64 Solving Problems (p. 4) 4. A car traveling at 20 m/s applies its brakes and comes to a stop in four seconds. What is the acceleration of the car? vi = 20 m/s vf = 0 m/s Δt = 4 seconds

65 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

66 Solving Problems (p. 4) 4. A car traveling at 20 m/s applies its brakes and comes to a stop in four seconds. What is the acceleration of the car? vi = 20 m/s vf = 0 m/s Δt = 4 seconds

67 Solving Problems (p. 4) 4. A car traveling at 20 m/s applies its brakes and comes to a stop in four seconds. What is the acceleration of the car? vi = 20 m/s vf = 0 m/s Δt = 4 seconds a = ?

68 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

69 Solving Problems (p. 4) 4. A car traveling at 20 m/s applies its brakes and comes to a stop in four seconds. What is the acceleration of the car? vi = 20 m/s vf = 0 m/s Δt = 4 seconds a = ?

70 Notes: Kinematic Equations The Four Kinematic Equations: v f = v i + a Δ t Δx = v i Δt + aΔt 2 2 v f 2 = v i 2 + 2a Δx Δx = (v f + v i )Δt 2

71 Notes: Kinematic Equations The Four Kinematic Equations: v f = v i + a Δ t Δx = v i Δt + aΔt 2 2 v f 2 = v i 2 + 2a Δx Δx = (v f + v i )Δt 2

72 Solving Problems (p. 5) 5. A car traveling at 20 m/s applies its brakes and comes to a stop in four seconds. How far does the car travel before coming to a stop?

73 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

74 Solving Problems (p. 5) 5. A car traveling at 20 m/s applies its brakes and comes to a stop in four seconds. How far does the car travel before coming to a stop?

75 Solving Kinematics Problems Step 1: Read the Problem, underline key quantities Step 2: Assign key quantities a variable Step 3: Identify the missing variable Step 4: Choose the pertinent equation: Step 5: Solve for the missing variable. Step 6: Substitute and solve.

76 Solving Problems (p. 5) 6. The USS Enterprise accelerates from rest at 100,000 m/s 2 for a time of four seconds. How far did the ship travel in that time?

77 Exit Ticket (p. 14) 12, Calvin tosses a water balloon to Hobbes. As Hobbes is about to catch it the balloon has a speed of 1 m/s. Hobbes catches the balloon, and the balloon experiences an acceleration of -0.5 m/s 2 as it comes to rest. How far did Hobbes' hands move back while catching the balloon? Write the given variables, the missing variable, and the equation you will use.

Download ppt "Oct. 29, 2012 AGENDA: 1 – Bell Ringer 2 – Kinematics Equations 3 – Exit Ticket Today’s Goal: Students will be able to identify which kinematic equation."

Similar presentations

STARTER vf = vi + at Rearrange the equation for acceleration,

STARTER vf = vi + at Rearrange the equation for acceleration,
Oct. 30, 2012 Today’s Goal: Students will be able to identify which kinematic equation to apply in each situation Homework 1. Pages 4-6 AGENDA: 1 – Bell.

Oct. 30, 2012 Today’s Goal: Students will be able to identify which kinematic equation to apply in each situation Homework 1. Pages 4-6 AGENDA: 1 – Bell.
Sept. 25, 2012 AGENDA: 1 – Bell Ringer 2 – Lab Explanation 3 – Lab 4 – Graphing Data 5 – Velocity on Position vs. Time Graphs Today’s Goal: Students will.

Sept. 25, 2012 AGENDA: 1 – Bell Ringer 2 – Lab Explanation 3 – Lab 4 – Graphing Data 5 – Velocity on Position vs. Time Graphs Today’s Goal: Students will.
Oct. 10th AGENDA: 1 – Bell Ringer 2 – Density Lab 3 – Cornell Notes: Phase Changes 4 – Practice Problems Today’s Goal: Students will be able to contrast.

Oct. 10th AGENDA: 1 – Bell Ringer 2 – Density Lab 3 – Cornell Notes: Phase Changes 4 – Practice Problems Today’s Goal: Students will be able to contrast.
Nov. 7th AGENDA: 1 – Bell Ringer 2 – Free Fall Acceleration 3 – Exit Ticket Today’s Goal: Students will be able to explain how free fall acceleration occurs.

Nov. 7th AGENDA: 1 – Bell Ringer 2 – Free Fall Acceleration 3 – Exit Ticket Today’s Goal: Students will be able to explain how free fall acceleration occurs.
Tuesday, October 23rd AGENDA: 1 – Bell Ringer 2 – Phase Change Diagrams 3 – Exit Ticket Announcements 2.5 pts of extra credit for coming for tutoring after.

Tuesday, October 23rd AGENDA: 1 – Bell Ringer 2 – Phase Change Diagrams 3 – Exit Ticket Announcements 2.5 pts of extra credit for coming for tutoring after.
Tuesday, October 16th AGENDA: 1 – Bell Ringer 2 – Phase Changes 3 – Exit Ticket Announcements 2.5 pts of extra credit for coming for tutoring after school.

Tuesday, October 16th AGENDA: 1 – Bell Ringer 2 – Phase Changes 3 – Exit Ticket Announcements 2.5 pts of extra credit for coming for tutoring after school.
Oct. 19, 2012 AGENDA: 1 – Bell Ringer 2 – Acceleration Review 3 – Finish Acceleration Assignments Today’s Goal: Students will be able to understand how.

Oct. 19, 2012 AGENDA: 1 – Bell Ringer 2 – Acceleration Review 3 – Finish Acceleration Assignments Today’s Goal: Students will be able to understand how.
3-3 Velocity and Acceleration. Velocity Average Velocity  Vector measurement that is the change in distance per some change in time  V = Δd / Δt = (d.

3-3 Velocity and Acceleration. Velocity Average Velocity  Vector measurement that is the change in distance per some change in time  V = Δd / Δt = (d.
November 5th AGENDA: 1 – Bell Ringer 2 – Review Today’s Goal: Students will be able to review for their unit test. Homework Start Reviewing for the test!

November 5th AGENDA: 1 – Bell Ringer 2 – Review Today’s Goal: Students will be able to review for their unit test. Homework Start Reviewing for the test!
Oct. 1, 2012 AGENDA: 1 – Bell Ringer 2 – Cornell Notes: Chemical & Physical Properties; Density 3 – Demos 4 – Start Homework Today’s Goal: Students will.

Oct. 1, 2012 AGENDA: 1 – Bell Ringer 2 – Cornell Notes: Chemical & Physical Properties; Density 3 – Demos 4 – Start Homework Today’s Goal: Students will.
Sept. 26, 2012 AGENDA: 1 – Bell Ringer 2 – Stations on Classifying Matter 3 – Classifying Matter Class Competition 4 – Exit Ticket Today’s Goal: Students.

Sept. 26, 2012 AGENDA: 1 – Bell Ringer 2 – Stations on Classifying Matter 3 – Classifying Matter Class Competition 4 – Exit Ticket Today’s Goal: Students.
Coach Kelsoe Physics Pages 48–59

Coach Kelsoe Physics Pages 48–59
Oct. 23, 2012 AGENDA: 1 – Bell Ringer 2 – Velocity Time Graphs 3 – Review of Quiz 2 Today’s Goal: Students will be able to construct velocity vs. time.

Oct. 23, 2012 AGENDA: 1 – Bell Ringer 2 – Velocity Time Graphs 3 – Review of Quiz 2 Today’s Goal: Students will be able to construct velocity vs. time.
Monday, September 23, 2013 Physics Warm Up Find the v i if v f =20m/s, a=4 m/s 2 and t=5s Standards: 1a Students know how to solve problems that involve.

Monday, September 23, 2013 Physics Warm Up Find the v i if v f =20m/s, a=4 m/s 2 and t=5s Standards: 1a Students know how to solve problems that involve.
Friday, October 26th AGENDA: 1 – Bell Ringer 2 – Quiz 3 – Metric Lab 4 – Exit Ticket Today’s Goal: Students will be able to convert between metric units.

Friday, October 26th AGENDA: 1 – Bell Ringer 2 – Quiz 3 – Metric Lab 4 – Exit Ticket Today’s Goal: Students will be able to convert between metric units.
Wednesday, October 31st AGENDA: 1 – Bell Ringer 2 – Homework Review 3 – Precision and Accuracy 4 – Chemical and Physical Changes Packet due tomorrow Today’s.

Wednesday, October 31st AGENDA: 1 – Bell Ringer 2 – Homework Review 3 – Precision and Accuracy 4 – Chemical and Physical Changes Packet due tomorrow Today’s.
Tuesday, October 30th AGENDA:

Tuesday, October 30th AGENDA:
Homework Due Tomorrow: 1. Quiz Corrections 2. Velocity HW (page 9) 3. Classroom Materials: 1. Scientific Calculator 2. Pens / Pencils 3. Notebook 4. Progress.

Homework Due Tomorrow: 1. Quiz Corrections 2. Velocity HW (page 9) 3. Classroom Materials: 1. Scientific Calculator 2. Pens / Pencils 3. Notebook 4. Progress.
Oct 5, 2012 AGENDA: 1 – Bell Ringer 2 – Review 3 – Quiz 4 – Density Today’s Goal: Students will succeed on their quiz Homework: 1.Density Handout.

Oct 5, 2012 AGENDA: 1 – Bell Ringer 2 – Review 3 – Quiz 4 – Density Today’s Goal: Students will succeed on their quiz Homework: 1.Density Handout.

Similar presentations

Ads by Google