Differentiated learning: differentiated instruction, differentiated assessment
Mathematics 4: Support Differentiated Instruction.
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Transcript of Mathematics 4: Support Differentiated Instruction.
Differentiating Instruction “…differentiating instruction means … that
students have multiple options for taking in information, making sense of ideas, and expressing what they learn. In other words, a differentiated classroom provides different avenues to acquiring content, to processing or making sense of ideas, and to developing products so that each student can learn effectively.”
Tomlinson 2001
Diversity in the Classroom
Using differentiated tasks is one way to attend to the diversity of learners in your classroom.
Differentiating Instruction Some ways to differentiate Instruction
in mathematics class
Common Task with Multiple Variations
Open-ended Questions
Differentiation Using Multiple Entry Points
Common Tasks with Multiple Variations
A common problem-solving task, and adjust it for different levels.
Students tend to select the numbers that are challenging enough for them while giving them the chance to be successful in finding a solution.
Plan Common Tasks with Multiple Variations
The approach is to plan an activity with multiple variations.
For many problems involving computations, you can insert multiple sets of numbers.
An Example of a Common Task with Multiple Variations
Marian has a new job. The distance she travels to work each day is {5, 94, or 114} kilometers. How many kilometers does she travel to work in {6, 7, or 9} days?
Common Tasks with Multiple Variations
When using tasks of this nature all students benefit and feel as though they worked on the same task.
Class discussion can involve all students.
Follow-up Activity 1
Outcome D2 – Recognize and demonstrate that objects of the same area can have different perimeters.
Materials: coloured tiles and centimetre grid paper Differentiation: the choice will be the number of tiles
they select. Choose 6, 12, or 20 tiles. Model as many rectangles as
you can using all of your tiles. Draw each rectangle on your centimetre grid paper. Record both the area and perimeter for each figure.
Do all rectangles with the same area have the same perimeter?
Materials: Coloured tiles and centimetre grid paper Differentiation: the choice will be the number of tiles
they select. Choose 6, 12, or 20 tiles. Make as many different shapes
as you can and record the perimeter of each shape. Note: At least one side of each tile must abut the side of
another tile. Additional extensions:
Determine the greatest possible perimeter. Determine the least possible perimeter.
Follow-up Activity 2
Now You Try:
Choose an outcome(s) from your grade level curriculum and create a differentiated activity for your students.
Open-ended Questions
Open-ended questions have more than one acceptable answer and can be approached by more than one way of thinking.
Open-ended Questions Well designed open-ended problems
provide most students with an obtainable yet challenging task.
Open-ended tasks allow for differentiation of product.
Products vary in quantity and complexity depending on the student’s understanding.
Open-ended Questions An Open-Ended Question:
should elicit a range of responses
requires the student not just to give an answer, but to explain why
the answer makes sense
may allow students to communicate their understanding of
connections across mathematical topics
should be accessible to most students and offer students an
opportunity to engage in the problem-solving process
should draw students to think deeply about a concept and to select
strategies or procedures that make sense to them
can create an open invitation for interest-based student work
Open-ended Questions Adjusting an Existing Question
1. Identify a topic.2. Think of a typical question.3. Adjust it to make an open
question.
Example: 1. Money2. How much change would you get
back if you used a toonie to buy Caesar salad and juice?
3. I bought lunch at the cafeteria and got 35¢ change back. How much did I start with and what did I buy?
Today’s Specials
Green Salad $1.15Caesar Salad $1.20Veggies and Dip
$1.10Fruit Plate $1.15Macaroni $1.35Muffin
65¢Milk
45¢Juice
45¢Water
55¢
Open-ended Questions Use your curriculum document or Math Makes
Sense to find examples of open-ended questions.
Find two closed-questions from Math Makes Sense or from your curriculum document.
Change them to Open-ended Questions.
Be prepared to share one of your questions.
Differentiation Using Multiple Entry Points
Van de Walle (2006) recommends using multiple entry points, so that all students are able to gain access to a given concept.
diverse activities that tap students’ particular inclinations and favoured way of representing knowledge.
Multiple Entry Points
Multiple Entry Points are diverse activities that tap into students’
particular inclinations and favoured way of representing knowledge.
Multiple Entry Points
Based on Five Representations:
Based on Multiple Intelligences:
- Concrete- Real world (context)- Pictures- Oral and written- Symbols
- Logical-mathematical- Bodily kinesthetic- Linguistic- Spatial
Sample – 3D Geometry
Examine the 3-D models and explain why the number of faces and the number of vertices of hexagonal pyramids is one more than the number associated with its name.
Listen to a poem about a cube. Choose another prism or pyramid and compose your own poem.(Sample poem and format Appendix B)
Write a story about 3-D shapes modeled on The Greedy Triangle.Burns, Marilyn. The Greedy Triangle. Brainy Day Books, 1995
Which 3-D shapes occur in nature? Find and record as many examples as you can using a table to organize your ideas.
Complete a Frayer Model about one or more 3-D shapes (page 116, Mathematics Grade 4: A Teaching Resource)
Compose and solve riddles about 3-D shapes.Example: E4.1 What shapes are we? We both have six vertices. We both have triangular faces.
A standard die is in the shape of a cube. What other shapes can be used to make a fair die?
Complete a Concept Definition Map about one or more 3-D shapes.
(Appendix C)
Use a Venn diagram to compare two 3-D shapes(page 120, Mathematics Grade 4: A Teaching Resource)
Creating Tasks With Multiple Entry PointsUsing the outcomes for decimals, create tasks with multiple entry points. Take into consideration the five representations: real world (context), concrete, pictures, oral/written, and symbolic and multiple intelligences: logical/mathematical, bodily kinesthetic, linguistic, spatial.
Possible Uses for the Grid1. Introduce some of the activities to students
being careful to select a range of entry points. Ask students to choose a small number of activities. Other activities can be used for reinforcement or assessment tasks.
2. Arrange 9 activities on a student grid: 3 rows of 3 squares. Ask the students to select any 3 activities to complete, as long as they create a Tic-Tac-Toe pattern.
3. Other ideas?