Solutions as numbers (EduCue)

Slides:

Advertisements

Similar presentations

Copyright © 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley. Chapter 1. Concepts of Motion The universe we live in is one of change.

Advertisements

Kinematics The branch of mechanics that studies the motion of a body without caring about what caused the motion.

3-instvelacc Review Three cars are starting on a 30-mile trip. They start at the same time, and arrive ½ hour later. Slow start, then becoming faster Fast.

Copyright © 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley. Chapter 1. Concepts of Motion The universe we live in is one of change.

Motion Introduction.

Chapter 1 Lecture Kinematics: Motion in One Dimension Week 2 Day 1 © 2014 Pearson Education, Inc.

Picturing Motion Describing Motion with Diagrams …

Describing Motion with Diagrams The two most common types of diagrams used to describe the motion of objects are: a. Ticker Tape Diagrams b. Vector Diagrams.

Motion diagrams Position and time Velocity Scientific notation and units Vectors and motion Unit 2 Concepts of Motion and Mathematical Background Topics:

Wednesday, August 27 Motion Position and Time Velocity Scientific Notation Vectors.

Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley. Motion diagrams Position and time Velocity Scientific notation and units.

© 2010 Pearson Education, Inc. General Motion and Constant Velocity Motion General Motion Model - Definitions Position Distance Displacement Average Speed.

Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley. Motion diagrams Position and time Velocity Scientific notation and units.

Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley. Motion diagrams Position and time Velocity Scientific notation and units.

© 2010 Pearson Education, Inc. Reading Quiz 2.The quantity 2.67 x 10 3 m/s has how many significant figures? A. 1 B. 2 C. 3 D. 4 E. 5 Slide 1-7.

Physics 151 Week 3 Day 3 Topics Strategic Problem Solving

1 AP Physics Chapter 2 Motion Along a Straight Line.

PHY131H1F – Introduction to Physics I Class 2

Chapter Acceleration  How do you know when velocity is changing? What do you experience?  Particle-models can represent velocity Evenly spaced.

Today: Chapter 1. Motion Diagrams Particle Model Vector Addition, Subtraction Position, velocity, and acceleration Position vs. time graphs PHY131H1F –

P201 Discussions Jan 15 Questions on Mastering Physics use? Using and interpreting motion diagrams 1.

Chapter 2 Preview Objectives One Dimensional Motion Displacement

Chapter 2 Table of Contents Section 1 Displacement and Velocity

Motion in One Dimension Average Versus Instantaneous.

Physics Ch. 4 Physics Ch. 4.  Acceleration is the rate of change of velocity in a specific direction.  It is a VECTOR quantity – has magnitude & direction.

Chapter 2 Motion in One Dimension

Week 3 Day 2: Topics Particle Model General Motion Model

Copyright © 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley. (Later in the course, we will consider “systems” of particles, and extended.

Kinematics in One Dimension We will focus today on problem- solving. Note: some problems are hard, some are not so hard. Part of the learning is recognizing.

Week 3 Day 1: Topics Particle Model General Motion Model

Ch. 2: Describing Motion: Kinematics in One Dimension.

Chapter 3 Acceleration Lecture 1

Chapter 1 Stop to Think / Quick Check Problems

Ch. 2: Describing Motion: Kinematics in One Dimension.

Acceleration Physics 11.

1 Chapter 2 Motion in One Dimension Kinematics Describes motion while ignoring the agents that caused the motion For now, will consider motion.

Picturing Motion: Dot Diagrams If you related the position of the runner to the background in each frame taken in 1 second intervals, you would conclude.

Kinematics in Two Dimensions AP Physics 1. Cartesian Coordinates When we describe motion, we commonly use the Cartesian plane in order to identify an.

Chapter 3 Describing Motion.

FOR SCIENTISTS AND ENGINEERS physics a strategic approach THIRD EDITION randall d. knight © 2013 Pearson Education, Inc. Chapter 1 Lecture.

Physics MOTION Motion Diagrams n A series of images of a moving object that records its position after equal time intervals n *see the pictures in your.

Chapter 2: Motion, Forces, & Newton’s Laws. Brief Overview of the Course “Point” Particles & Large Masses Translational Motion = Straight line motion.

Describing Motion Physics 11. Cartesian Coordinates When we describe motion, we commonly use the Cartesian plane in order to identify an object’s position.

© 2010 Pearson Education, Inc. 1.What is the difference between speed and velocity? A. Speed is an average quantity while velocity is not. B. Velocity.

Chapter 1. Concepts of Motion

Kinematics The branch of mechanics that studies the motion of a body without caring about what caused the motion.

Physics Chapter 3 Describing Motion. 3.1 Picturing Motion Motion diagram Operational definition Particle model 3.2 Where and When Coordinate systems Scalar/Vector.

Chapter 1 Lecture Kinematics: Motion in One Dimension Prepared by Dedra Demaree, Georgetown University © 2014 Pearson Education, Inc.

CN – Kinematic Graphs What is kinematics? 3 types of Kinematic Graphs.

Ying Yi PhD Chapter 2 Motion in One Dimension 1 PHYS HCC.

Today: finishing Chapter 1. Position, velocity, and acceleration Problem solving Scaling Significant Figures PHY131H1S – Introduction to Physics I Class.

Motion ONE DIMENSION POSITION: FRAME of REFERENCE X

Uniform Motion t (s) x (cm) v (cm/s)

It’s All About Acceleration

Picturing Motion: Dot Diagrams

Chap. 2: Kinematics in one Dimension

Acceleration Changing velocity (non-uniform) means an acceleration is present Acceleration is the rate of change of the velocity Units are m/s² (SI)

Describing Motion Chapter 3.

Physical Science Chapter 11: Motion.

Picturing Motion Section 3.1

Find the velocity of a particle with the given position function

Chapter 1 – Concepts of Motion

Motion in One Dimension

Day 4 10/21/10 Topic: Accelerated Motion Diagrams

Describing Motion with Diagrams

ONE DIMENSIONAL MOTION

Chapter Accelerated Motion 3.

Uniform Motion t (s) x (cm) v (cm/s)

FOR SCIENTISTS AND ENGINEERS physics a strategic approach THIRD EDITION randall d. knight © 2013 Pearson Education, Inc. Chapter 1 Lecture.

Presentation transcript:

Solutions as numbers (EduCue) Classroom Response System “Clicker” Questions for Physics for Scientists and Engineers by Randall D. Knight Solutions as numbers (EduCue) PowerPoints prepared by Benjamin Grinstein, University of California San Diego

Chapter 1

Which car is going faster, 1 or 2 Which car is going faster, 1 or 2? Assume there are equal intervals of time between the frames of both movies. Car 1 Car 2 STT1.1

Which car is going faster, 1 or 2 Which car is going faster, 1 or 2? Assume there are equal intervals of time between the frames of both movies. Car 1 Car 2 2 is going faster STT1.1

2. (a) is ball, (b) is dust, (c) is rocket Three motion diagrams are shown. Which is a dust particle settling to the floor at constant speed, which is a ball dropped from the roof of a building, and which is a descending rocket slowing to make a soft landing on Mars? 1. (a) is dust, (b) is ball, (c) is rocket 2. (a) is ball, (b) is dust, (c) is rocket 3. (a) is rocket, (b) is dust, (c) is ball 4. (a) is rocket, (b) is ball, (c) is dust 5. (a) is ball, (b) is rocket, (c) is dust STT1.2

2. (a) is ball, (b) is dust, (c) is rocket Three motion diagrams are shown. Which is a dust particle settling to the floor at constant speed, which is a ball dropped from the roof of a building, and which is a descending rocket slowing to make a soft landing on Mars? 1. (a) is dust, (b) is ball, (c) is rocket 2. (a) is ball, (b) is dust, (c) is rocket 3. (a) is rocket, (b) is dust, (c) is ball 4. (a) is rocket, (b) is ball, (c) is dust 5. (a) is ball, (b) is rocket, (c) is dust STT1.2

A particle moves from position 1 to position 2 during the interval ∆t A particle moves from position 1 to position 2 during the interval ∆t. Which vector shows the particle’s average velocity? STT1.3 (1) (2) (3) (4) (5)

A particle moves from position 1 to position 2 during the interval ∆t A particle moves from position 1 to position 2 during the interval ∆t. Which vector shows the particle’s average velocity? STT1.3 (1) (2) (3) (4) (5)

A particle undergoes acceleration while moving from point 1 to point 2 A particle undergoes acceleration while moving from point 1 to point 2. Which of the choices shows the velocity vector as the object moves away from point 2? (1) (2) (3) (4) STT1.4

A particle undergoes acceleration while moving from point 1 to point 2 A particle undergoes acceleration while moving from point 1 to point 2. Which of the choices shows the velocity vector as the object moves away from point 2? (1) (2) (3) (4) STT1.4

Rank in order, from the most to the least, the number of significant figures in the following numbers. For example, if b has more than c, c has the same number as a, and a has more than d, you could give your answer as b > c = a > d. a. 8200 b. 0.0052 c. 0.430 d. 4.321 10-10 1. d > c > b = a 2. a = b = d > c 3. b = d > c > a 4. d > c > a > b 5. b > a = c = d STT1.5

Rank in order, from the most to the least, the number of significant figures in the following numbers. For example, if b has more than c, c has the same number as a, and a has more than d, you could give your answer as b > c = a > d. a. 8200 b. 0.0052 c. 0.430 d. 4.321 10-10 1. d > c > b = a 2. a = b = d > c 3. b = d > c > a 4. d > c > a > b 5. b > a = c = d STT1.5

Chapter 1 Reading Quiz

4. An object that can be represented as a single point in time What is a “particle”? 1. Any part of an atom 2. An object that can be represented as a mass at a single point in space 3. A part of a whole 4. An object that can be represented as a single point in time 5. An object that has no top or bottom, no front or back IG1.1

4. An object that can be represented as a single point in time What is a “particle”? 1. Any part of an atom 2. An object that can be represented as a mass at a single point in space 3. A part of a whole 4. An object that can be represented as a single point in time 5. An object that has no top or bottom, no front or back IG1.1

What quantities are shown on a complete motion diagram? 1. The position of the object in each frame of the film, shown as a dot 2. The average velocity vectors (found by connecting each dot in the motion diagram to the next with a vector arrow) 3. The average acceleration vectors (there is one acceleration vector linking each two velocity vectors) 4. All of the above IG1.2

What quantities are shown on a complete motion diagram? 1. The position of the object in each frame of the film, shown as a dot 2. The average velocity vectors (found by connecting each dot in the motion diagram to the next with a vector arrow) 3. The average acceleration vectors (there is one acceleration vector linking each two velocity vectors) 4. All of the above IG1.2

An acceleration vector 1. tells you how fast an object is going. 2. is constructed from two velocity vectors. 3. is the second derivative of the position. 4. is parallel or opposite to the direction of motion. 5. Acceleration vectors weren’t discussed in this chapter. IG1.3

An acceleration vector 1. tells you how fast an object is going. 2. is constructed from two velocity vectors. 3. is the second derivative of the position. 4. is parallel or opposite to the direction of motion. 5. Acceleration vectors weren’t discussed in this chapter. IG1.3

The pictorial representation of a physics problem consists of 1. a sketch. 2. a coordinate system. 3. symbols. 4. a table of values. 5. all of the above. IG1.4

The pictorial representation of a physics problem consists of 1. a sketch. 2. a coordinate system. 3. symbols. 4. a table of values. 5. all of the above. IG1.4