march 4, 2014
DESCRIPTION
Educating for Careers 2014 Math Project-Based Learning and the Common Core: Intersection , Union, or Empty Set?. March 4, 2014. Kentaro Iwasaki. Who’s Here?. Raise your hand for all groups that apply to you. Teachers Career Technical Mathematics Other. Pathway Leads - PowerPoint PPT PresentationTRANSCRIPT
Educating for Careers 2014
Math Project-Based Learning and the Common Core: Intersection, Union, or Empty Set? March 4, 2014
Kentaro Iwasaki
Who’s Here?
Raise your hand for all groups that apply to you
2
• Teachers– Career Technical– Mathematics– Other
• Pathway Leads• School
Administrators• District
Administrators• Counselors• Other
Who Here Is In a Linked Learning Pathway?
Please raise your hand if you are in a Linked Learning Pathway.
3
4
Components of Linked Learning
A comprehensive four-year program of study integrating:
• Rigorous academics
• Real-world technical skills
• Work-based learning
• Personalized supports
Session Objectives
• Explore the Venn of Common Core Math and Project-Based Learning in a Linked Learning context
• Explore how Project-Based Learning in a Linked Learning Context enhances students’ understanding of mathematical content and practices from the CCSS-M
6
Agenda
1. What’s Your Venn?
2. ConnectEd’s PBL-based Math Curriculum
3. Focus on One Unit and Project
4. Discuss Links to CCSS-M Standards and Practices
5. Share out
6. What’s Your Venn?
7. Feedback
7
What’s Your Venn?
Please draw what your Venn between Math PBL and CCSS-M is and explain why.
8
ConnectEd’s PBL Math Curriculum
ConnectEd developed 10 pre-algebra and algebra project-based and
problem-based units in order to support engineering pathway students
in mathematics.
9
ConnectEd’s PBL Math Curriculum
Currently our math curriculum is part of a rigorous randomized controlled trial through a federal i3 (Investing in Innovation) project in 17
districts across California that will impact approximately 6000 students with achievement
on 8th grade CST Algebra scores as the measurement.
10
ConnectEd’s PBL Math Curriculum
Measurement, fraction, and percent skills are applied to build the most efficient wind turbine possible
Graphs, algebraic expressions, and ratios are used to build and analyze a transportation system
Scale, slope, and proportional reasoning are taught through the design of an access ramp and a remodeling plan for a building
Unit 2: Blueprints and Models
Unit 1: Wind Power
Unit 4: Safe Combinations
Unit 3: People Movers
Exponent rules to calculate the number ofpossible combinations on a constructed combination lock. Writing and solving equations are used to “code” and “decode” solutions
ConnectEd’s PBL Math Curriculum
Solve single-variable linear equations as students build the pieces of a puzzle cube
Solve quadratic equations to design and play a game with projectile machines
Graph linear equations to chart the progress of multiple planes and direct them to land safely
Unit 2: Air Traffic Control
Unit 1: Puzzle Cube
Solve rational expressions to calculate the total resistance in circuits
Unit 6: Electrical Resistance
Unit 3: Catapult Game
Experiential Project from “The Catapult Game”
Your group’s task is to use mathematics to determine how far away to place your catapult in order to hit the targets on a castle poster.
What mathematical content and practices are involved?
Materials: Catapult, Tape Measure, Grid Poster Paper (1”X1” squares), Markers, Laptops or graphing calculators
13
Experiential Project from “The Catapult Game”
14
Experiential Project from “The Catapult Game”
15
x, Distance from Launch Point
y, Height Off Ground
Where’s the Math?
Please discuss in your groups what mathematical content and practices were involved in this
project. Be ready to share out.
16
Catapult Game Unit Overview
17
• The main mathematical concept of the Catapult Game unit focuses on connecting various aspects of quadratic functions (factoring, roots, x-intercepts, graphs, quadratic formula, applications).
• We work to emphasize the meaning of these math concepts in CONTEXT!
Lesson 1 Overview: Multiplying Binomials and Finding Area
18
Students multiply binomials through an area model and find patterns in perfect square trinomials and difference of squares.
Target Dimensions Area in Expanded Form
A x x (10 )(10 ) 100 – 20x + x2
B x x ( 15)( 15) x2 + 30x + 225
C x x ( 2)( 2) x2 + 4x + 4
D x x ( 5)( 5) x2 – 10x +25
E x x (2 1)(2 1) 4x2 + 4x + 1
F x x ( 4)( 4) x2 + 8x + 16
Total Area: 9x2 + 16x + 371
2x
–x –2
x
–4
2 x
4x 8
Lesson 2 Overview:Graphs of Equations in Factored Form
19
-20-18-16-14-12-10
-8-6-4-202468
1012141618202224262830323436
-10 -9 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7 8 9 10x
y
(x+2)(x+4)
(x-3)(x+5)
x(x-2)
2) Graph the three sets of data from Problem 1. Label each graph.
Graphs of Equations in Factored Form
20
x
Root Root
Area of Target The regions of
the graphs that represent all of the possibilities for real targets.
x
Area of Target
Root Root
The x-intercepts or zeroes tell us about the graphs of quadratics in this contextThe set of x-values that lead to positive areas is bound by the points where the function is equal to zero. We already know that these points are the roots or x intercepts‑ of the function. They are also called the zeroes of the function.
Lesson 3 Overview:Factoring
21
Factoring using the area model
Designer: Bianca
Summary: Target Areas
Target Area
A 2 3 4x x (x + 4)(x – 1)
B 2 1 6x x (x – 3)(x + 2)
C 2 3 10x x (x + 5)(x – 2)
D 2 36x (x + 6)(x – 6)
Lesson 4.2 Factoring Doesn’t Always Work
22
Consider the trajectory of ammunition launched by Catapult Q: 2( 10 6).y x x Where should you place the catapult in order to shoot ammunition through Target C, which is 25 inches high?
2
2
2
25 ( 10 6)
25 10 6
0 10 19not factorable
x xx xx x
x xx xx xx
x
x
2
2
2
2
0 10 19
0 6 10 (19 6)
6 10 25
6 ( 5)
6 5
5 6
(?, 25)
Lesson 4.2 Factoring Doesn’t Always Work
23
This process of completing the square was done to the generic quadratic equation in standard form (2 0ax bx c ) to create a formula for the solutions:
The Quadratic Formula
If 2 0ax bx c , then b b acxa
2 42
Completing the Square
Solve the following equations by adding a number to both sides of the equal sign that makes the right side a perfect square. The first one is done for you.
Lessons 4.4 Analyze the Catapult Part 2
24
Determine where to place each catapult in order to hit all of the targets on the castle.
Trajectory Equations x = horizontal distance; y = height of ball
Catapult Ammunition Balls Supply Balls
Q y x x2( 9 6) y x x 2( 13 6)
R y x x 2( 17 3) y x x 2( 11 3)
S y x x2( 10 4) y x x 2( 7 4)
B
A
D
G
F
E
C
6
10
13
20
25
28
33
Inches from the Ground
The Castle
Must Place Catapult This Distance Away from Castle to Hit the Target (ft.)
(Round all answers to the nearest hundredth place)Target Catapult Q Catapult R Catapult S
Ammunition Supplies Ammunition Supplies Ammunition Supplies
A Impossible; no real solutions 2, 11 1.63, 15.73 3.21, 7.79 4, 6
Impossible; no real solutions
Lesson 5Playing the Catapult Game Virtually
25
Go to http://www.8kindsoffun.com/Catapult/CatapultGUI.html and record your calculations for playing the virtual catapult game below.
An example of a quadratic regression applet can be found at
http://www.xuru.org/rt/PR.asp Data Points for Ammunition Trajectory
Point 1Point 2Point 3
Quadratic Standard Form Calculator Data Points for Ammunition Trajectory
Vertex 𝑥= 𝑦=
x-intercept 𝑥=
Standards of Mathematical Practice
What standards of mathematical practice from the CCSS-M did you find in the project?
1. Make sense of problems and persevere in solving them.
2. Reason abstractly and quantitatively.
3. Construct viable arguments and critique the reasoning of others.
4. Model with mathematics.
5. Use appropriate tools strategically.
6. Attend to precision.
7. Look for and make use of structure.
8. Look for and express regularity in repeated reasoning.
26
Has Your Venn Changed?
Take a look at your Venn from the beginning of the session.
Has your Venn changed at all?How so?
27