INTRODUCTION - stupidchicken comic
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GENERAL PROPERTIES OF WAVES
GCE ‘O’ LEVEL PHYSICS 5052
LESSON PLAN A:
INTRODUCTION TO WAVES
Done by: Chew Yiming Clement (LG02)
Supervisor: Mr Charles Chew
Module Code: QCP521
INTRODUCTION
The topic on General Wave Properties for 5052 Physics O Level is an important topic that sets the foundation for further study in topics on EM waves, Light and Sound. The topic will be taught in two lessons.
Lesson A: Introduction to Waves
Lesson B: The Wave Equation and its Applications
The lesson plan that follows is for Lesson A.
LESSON PLANNING (LESSON A)
Topic: General Wave properties
Class: Secondary 3 Express (Average ability)
Content:
a) Describing wave motion
b) Wave terms
c) Longitudinal and transverse waves
Time: 2 periods (70 min)
Prerequisites and Prior Knowledge:
a) Students should have learnt light and sound in Lower Secondary Science
b) Students should have learnt the concept of speed and its definition.
c) Students should have experience with water waves and have witnessed ocean waves.
Lesson objectives:
At the end of the lesson, students should be able to:
a) Describe and explain what is meant by wave motion as illustrated by vibrations in ropes, springs and by waves in a ripple tank. (Waves in a ripple tank to be dealt in next lesson)
b) Show understanding that waves transfer energy without transferring matter
c) Define speed, frequency, wavelength, period and amplitude
d) Compare transverse and longitudinal waves, and give suitable examples of each
(In lesson B)
e) State what is meant by the term wavefront
f) Recall the relationship velocity = frequency [pic] wavelength
g) Apply the relationship between velocity, frequency and wavelength to new situations or to solve related problems.
Learning Environment:
Classroom with whiteboard, OHT, a computer and a projector
Learning Aids & Resources:
a) 1 × clear plastic basin (with wide base)
b) 1 × rope
c) 5 × slinky coil
d) 1 × skipping rope
e) Flash animations.
f) 1 × newspaper article from Straits Times 15 Oct 2005 – ‘S’pore not safe from tsunami’
g) 2 × movie clips
• 1 × movie clip showing 26 Dec 2004 tsunami
• 1 × movie clip showing Tacoma Bridge collapse
h) 11 × construction sheets (10 red, 1 yellow) for the wave game
i) 1 × music clip
j) PowerPoint Slides
k) 1 × worksheets
(l) 1 × notes
m) 1 × dipper
Lesson Presentation:
Trigger Activity:
1) Take the clear basin and fill it with water. Place the basin onto the OHT. This is to simulate a pond or a puddle of water. Now drop a coin gently into the basin and observe how the circular ripples move outwards to the surface of the water. This is similar to the effect caused by casting a pebble into a pond.
2) Show applet of 26 Dec 2004 tsunami. This is to illustrate the destructive power of waves. Follow-up with newspaper cutting from the Straits Times 15 Oct 2005 – “‘S’pore not safe from tsunami’”.
Emphasise to the students that we encounter waves daily in our lives. There are also many application for waves in communications and medical science (radio sets, satellite technology, GPS, handphones, X-ray, photography). Tell the students that if they want to pursue these interests later in life, they must pay attention to the lesson, and learn more about waves! (
Set Induction:
The Wave Game
Ask ten students to come to the front of the class. Make them stand in a straight line facing the class. Give them each a red construction paper. Tell them to do a continuous human wave. Synchronise the wave with some music. Using this activity, provide sufficient scaffolding to induce them to the properties of a transverse wave. For more details, refer to Procedure for Lesson Plan
Strategies for Lesson Development:
a) Simple to complex. Concrete to abstract.
One should not start off by introducing complex concepts before simpler concepts. The students will be confused. The lesson plan takes an inductive approach leading from specific to general examples, concrete to abstract concepts. Example: we begin by talking about waves in daily life before proceeding to classifying the waves into two different categories.
b) Everyday Applications
The continuous emphasis of the use of waves in everyday applications will make students more interested as they can relate them to their lives. Physics is useful and not just some theoretical exercise!
c) Perceptual Learning Styles
According to Dunn & Dunn (1978), students may have different perceptual learning styles. Learners may be auditory, visual or tactual/kinesthetic. Activities such as the wave game appeals to both kinesthetic and visual learners. Students will also get to play with the slinky coils. Those who learn better by writing down what they see and think have notes with blanks provided for them. They can fill in the blanks during the course of the lesson.
d) Focusing on the Essentials
No one can learn everything that is present in any textbook or lesson. Hence, it is important for the teacher to communicate what is most essential to the students. Notes with blanks are given out to fulfil the purposes. They contain the important definitions and concepts a student has to master from the lesson. The lesson closure also offers a recap using a concept map.
e) Collaborative Learning
To integrate collaborative learning, students will be asked to take part in a Think-Share-Pair activity where they are required to brainstorm and list the application of waves in daily life.
Lesson Closure:
The teacher will recap what the students have learnt using a concept map. The teacher will proceed to ask them some thinking questions that will prepare them for Lesson B on The Wave Equation and its Applications. Worksheets will also be given for students to do at home to facilitate their consolidation of concepts, as well as serve as student assessment.
Possible Learning Difficulties and Misconceptions:
Most students find the topic of waves very abstract. Hence, there is a need for demonstrations so that students can visualise the concepts involved. Some misconceptions of waves include:
• Waves transport matter.
• There must be a medium for a wave to travel through.
• Waves do not have energy.
• All waves travel the same way.
• Big waves travel faster than small waves in the same medium.
Concept Map:
[pic]
Reflection of lesson:
• The pace of the lesson was good. However, I can improve in the management of my time during activities
• The music clip hanged during the wave game. There is a need to prepare a contingency plan for teaching if technology fails.
Procedure of Lesson Plan
|Time Frame |Activities |Resources |Rationale |
|7 min |Trigger Activities | |To provoke students and prepare |
| |Activity 1: Throwing a pebble into a pond (5min) |Clear basin filled |their mindset to explore more into |
| |Ask students if they had ever throne a stone into a pond or a |with water. |the topic of waves. |
| |puddle of water. What happens when the stone hits the water? | | |
| |Take a clear basin and fill it with water. |Dipper |To show that waves occur in |
| |Place the basin onto the OHT. This is to simulate a pond | |everyday life. |
| |Using a dipper, create some circular ripples in the basin of | | |
| |water. | | |
| |The teacher says, “This is what will happen when I throw a | | |
| |pebble into a pond. Do you see those circular ripples? Those | | |
| |are waves” | | |
| | | | |
| |Remark: Distribute the notes before the trigger activity | | |
| |Activity 2: Movie Clips |Movie Clips | |
| |(5min) | | |
| |Tell students that waves are not always so harmless. They can |Newspaper Article | |
| |be very destructive. | | |
| |Show students movie clip of 26 Dec 2004 tsunami. | | |
| |Follow this up by showing newspaper clip from Straits Times 15 | | |
| |Oct 2005 – ‘S’pore not safe from tsunami’ | | |
| |Show movie clip of Tacoma Bridge collapse. | | |
| | | | |
| |Tell the students that waves occur in everyday life. Hence, it | | |
| |is important for us to study waves. There are also many | | |
| |applications for waves in the fields of medical science and | | |
| |communications. If they want to pursue their interests in these| | |
| |areas, they must know more about waves. Hence, they must pay | | |
| |attention in class. | | |
|7 min |Think-Pair-Share |Handout A |To get students to think critically|
| |Distribute handout A. | |and construct their own |
| |Ask them to work in pairs to fill in the 1st column the |PowerPoint slides |understanding regarding the |
| |applications of waves in everyday life. | |definition of a wave. |
| |After they have finished, write some of the students’ answers | | |
| |on the whiteboard. | | |
| |Ask them the reason for choosing some of the answers | | |
| | | | |
| |Note: Some of the students’ answers might be wrong. It is fine | | |
| |at this time because the motive is to get them to think | | |
| |critically about what is a wave. They can learn from their | | |
| |mistakes | | |
|5 min |Definition of a wave |Clear basin filled |Introduce definition of wave using |
| |Take the clear basin of water and placed it over the OHP. |with water |previous demonstrations and |
| |Create some ripples using the dipper again. | |activities as scaffolding |
| |Bring to students’ attention the disturbance resulting from the|Dipper | |
| |vibrations caused by the ball falling into the water. | | |
| |Show PowerPoint Slide explaining definition of waves. |PowerPoint Slides | |
| |Now that the students know the definition of waves, ask the | | |
| |students to evaluate their previous answers. Which are waves | | |
| |and which are not? | | |
| |Emphasise that not all waves need a medium to propagate. | | |
| |Example: EM waves | | |
|8 min |The Wave Game |10 red construction |The intention of the wave game is |
| |Ask ten students to come to the front of the class and make |paper |to help students visualise the |
| |them stand in a straight line facing the class. | |mechanics involved in a transverse |
| |Give each student a red construction paper |2 cardboard arrows |wave. |
| |Ask the students to do a continuous human wave. If resources | | |
| |are sufficient, the human wave can be synchronised by a music |Optional: |Student-centered learning |
| |clip. |Music clip | |
| |Using a cardboard arrow, prompt the students to indicate the | | |
| |direction of propagation of the wave. | | |
| |Using the other cardboard arrow, prompt the students to | | |
| |indicate the direction each student is moving. | | |
| |Teacher to ask student what they observe about the direction of| | |
| |the two arrows. (They are perpendicular to each other) | | |
| | | | |
| | | | |
|5 min |Defining Transverse Waves |Skipping Rope |Using activities to help student |
| |Ask a student to hold one end of the skipping rope while the | |construct their understanding of |
| |teacher holds the other end. |Flash Animation |what is a transverse wave. |
| |The teacher moves his hand up and down to generate transverse | | |
| |waves. |PowerPoint Slides | |
| |Show the flash animation from | | |
| |. | | |
| |The flash animation shows an electronic representation of the | | |
| |rope wave. | | |
| |Ask the students what are the similarities between the rope | | |
| |wave and the human wave in the wave game. | | |
| |Show PowerPoint slide explaining what a transverse wave is. | | |
| |Help students to remember for transverse waves, waves travel in| | |
| |a direction perpendicular to the direction of vibration using | | |
| |the symbol of a cross for the letter “t”. | | |
| |Give some examples of transverse waves. Example: EM waves | | |
| |Ask review question to test understanding of waves. | | |
| | | | |
| | | | |
| | | | |
| | | |Help students consolidate their |
| | | |understanding of transverse waves. |
|8 min |Slinky Coil Demonstration |Slinky Coil |Using activities to help student |
| |Take a slinky coil and create longitudinal waves. | |construct their understanding of |
| |Pass the slinky coils for the student to play along |Flash animation |what is a longitudinal wave. |
| |Show flash animation on longitudinal waves. | | |
| | |2 Cardboard arrows | |
| |Again using the two cardboard arrows, ask students to show the | | |
| |direction of propagation of the waves, and the direction of the|PowerPoint Slides | |
| |vibration. Ask them how this is different from a transverse | | |
| |wave. |Optional | |
| |Show PowerPoint slides explaining the definition of a |Movie Clip | |
| |longitudinal wave. | | |
| |For longitudinal waves, the direction of vibration is along the| | |
| |direction of the propagation of the waves. | | |
| |Ask the students to observe that there are areas where the | | |
| |spring appears more compressed than other areas. Introduce | | |
| |concept of compressions and rarefactions. | | |
| |Give examples of longitudinal waves in everyday life. Example: | | |
| |sound (if there is time, show video clip of candle flame | | |
| |flickering vigorously due to sound blasting from a loud | | |
| |speaker) | | |
|5 min |Review Questions |PowerPoint Slides |Reinforce and assess students’ |
| |Ask students some simple question to test whether they can | |understanding of the concepts |
| |compare and distinguish transverse and longitudinal waves. | |involved. |
|15 min |Introducing crest, trough, amplitude and wavelength, frequency,|Construction Paper |Introducing wave terms to the |
| |period | |students. |
| |Get another 10 students to play the wave game. This time give |Music Clip | |
| |one of the students a yellow construction paper instead of a | |Visual representation allows |
| |red construction paper. Synchronise the wave using some music. |PowerPoint Slides |students to understand abstract |
| |Ask the students to freeze in their positions when you stop | |concepts better. |
| |playing the music. |Handout B | |
| |Stop the music when the student with the yellow construction | | |
| |paper is at his highest point. Introduce the idea of crests to |Optional: | |
| |the students. |Flash Animation | |
| |Stop the music when the student with the yellow construction | | |
| |paper is at his lowest point. Introduce the idea of troughs to | | |
| |the students. | | |
| |Using PowerPoint slides to introduce definitions of crest, | | |
| |trough, amplitude, wavelength, frequency and period to the | | |
| |students. | | |
| |For relationship between frequency and period, ask the students| | |
| |to do handout 2 and observe the trend that frequency increases | | |
| |as period decrease. Ask why this occurs. | | |
| | | | |
| |(If there is time, show flash animation on wave terms. Students| | |
| |can vary wave length, amplitude and frequency, and see the | | |
| |effect on the wave) | | |
| | | |Get students discover implications |
| | | |of T=1/f via induction. |
| | | | |
| | | | |
|5 min |Review Questions on wave terms |PowerPoint Slides |Reinforce students’ understanding |
| |Using PowerPoint, ask questions regarding the wave terms to | |of wave terms |
| |reinforce the students’ understanding of the wave terms. | | |
| | | | |
| |(If there is time, introduce the concept of wave speed and a | | |
| |derivation of the wave equation. But it is not critical as it | | |
| |will be covered in the next lesson) | | |
|5 min |Lesson Closure |Notes |Refresh the students’ memory |
| |Summarise the concepts taught using the concept map. They are | |concerning the concepts taught in |
| |to fill up the blank spaces in their notes. | |the lesson. |
| |Pose the following questions to the students to think through | | |
| |before the next lesson | |Help the students focus on the |
| |Why don't incoming ocean waves bring more water on to the shore| |essentials. |
| |until the beach is completely submerged? | | |
| |In space films, we often hear the sound of the engine of the | |Thinking questions to set the |
| |spaceship as the zoom past each other in outer space. We even | |students to inquire more into the |
| |hear the spaceship firing lasers at one another. What are your | |subject |
| |thoughts concerning this? | | |
| |How will the motion of water waves change as they move from | | |
| |deep to shallow water? How about from shallow to deep water? | | |
References
1) Charles Chew, Leong See Cheng, Chow Siew Foong (2000). Physics A Course for ‘O’ Levels (2nd Edition), Federal, Singapore.
2) Rita Dunn, Kenneth Dunn (1978). Teaching Students Through Their Learning Styles – a practical approach, Prentice-Hall, Virginia, USA.
3) Loo Wan Yong, Loo Kwok Wai, See Toh Weng Fong (2000). Physics Insights, Pearson Education, Singapore.
4) Panagiotis Pantidos, Stamatis Patapis (2005). Kinesthetic Transverse Wave Demostration, The Physics Teacher, Vol. 43, p.344-345
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APPENDIX A
HANDOUT 1 FOR INTRODUCTION TO WAVES
|Name: | |Class: | |
|Examples and Applications of Waves in Everyday Life |Type of Waves (Transverse/Longitudinal) |Any medium involved? |
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APPENDIX C
HANDOUT B FOR INTRODUCTION TO WAVES
|Name: | |Class: | |
Exploring the relationship between period, T and frequency, f
We have just learnt that[pic].
Let’s explore the implications of this relationship.
|Frequency, f/Hz |Period, T/s |
|1 | |
|2 | |
|3 | |
|4 | |
|5 | |
|6 | |
|7 | |
|8 | |
|9 | |
|10 | |
What do you observe?
APPENDIX C
HANDOUT B FOR INTRODUCTION TO WAVES (ANSWERS)
|Name: | |Class: | |
Exploring the relationship between period, T and frequency, f
We have just learnt that[pic].
Let’s explore the implications of this relationship.
|Frequency, f/Hz |Period, T/s |
|1 |1 |
|2 |0.5 |
|3 |0.333 |
|4 |0.25 |
|5 |0.2 |
|6 |0.167 |
|7 |0.143 |
|8 |0.125 |
|9 |0.111 |
|10 |0.1 |
What do you observe?
APPENDIX E – NOTES WITH ANSWERS
|UNIT 13 - GENERAL PROPERTIES OF WAVES |
1. What is a wave?
➢ It is a spreading of disturbance from one place to another.
➢ The source of the wave is a vibration or an oscillation.
➢ Energy is transferred from one point to another without physical transfer of any material between two points.
2. Do waves need a medium to propagate? No
3. Transverse waves travel in a direction perpendicular to the direction of the vibrations.
Some examples of transverse waves: water waves, rope waves, EM waves
4. Longitudinal waves travel in a direction parallel to the direction of the vibrations.
5. Crests: Points of maximum displacement on a wave.
Troughs: Points of minimum displacement on a wave.
[pic]
6. Amplitude (A): Maximum displacement from the rest or central position.
SI unit: metre (m)
[pic]
7. Wavelength (λ): Distance between two successive points of the same phase.
Example: distance between two crests.
SI unit: metre (m)
[pic]
8. Frequency (f): Number of waves generated per second.
SI unit: hertz (Hz)
9. Period (T): Time taken to generate one complete wave (or to complete one cycle).
SI unit: seconds (s)
10. Relationship between period, T and frequency, f:
[pic]
As f increases, T decreases.
CONCEPT MAP:
[pic]
APPENDIX F – NEWSPAPER CLIP AND POWERPOINT SLIDES
[pic]
-----------------------
TROUGH
CREST
CREST
displacement
distance
along rope
amplitude
amplitude
trough
crest
crest
distance along rope
displacement
amplitude
amplitude
λ
trough
crest
crest
distance
displacement
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