Improving learning in mathematics PD2: Learning from mistakes and misconceptions.

Improving learning in mathematicsImproving learning in mathematics

PD2: Learning from mistakes and misconceptions

Aims of the session

This session is intended to help us to: reflect on the nature and causes of

learners’ mistakes and misconceptions; consider ways in which we might use

these mistakes and misconceptions constructively to promote learning.

Assessing learners’ responses

Look at the (genuine) examples of learners' work.

Use the grid sheet to write a few lines summarising: the nature of the errors that have been

made by each learner; the thinking that may have led to these

errors. Discuss your ideas with the whole group.

Saira: Fractions and decimals

Saira: Fractions and decimals

Saira: Fractions and decimals

Confuses decimal and fraction notation.(0.25 = )

Believes that numbers with more decimal places are smaller in value.(0.625 < 0.5).

Sees as involving the cutting of a cake into 8 parts but ignores the value of the numerator when comparing fractions.

25

1

8

3

Saira: Fractions and decimals

Damien: Multiplication and division

Damien: Multiplication and division

Damien: Multiplication and division

Believes that one must always divide the larger number by the smaller (4 ÷ 20 = 5).

Appears to think that: division 'makes numbers smaller’; division of a number by a small quantity

reduces that number by a small quantity.

Damien: Multiplication and division

Julia: Perimeter and area

Julia: Perimeter and area

Julia: Perimeter and area

Julia: Perimeter and area

Has difficulty explaining the concept of volume, which she describes as the 'whole shape.'

Believes that perimeter is conserved when a shape is cut up and reassembled.

Believes that there is a relationship between the area and perimeter of a shape.

Jasbinder: Algebraic notation

Jasbinder: Algebraic notation

Jasbinder: Algebraic notation

Does not recognise that letters represent variables. Particular values are always substituted.

Shows reluctance to leave operations in answers.

Does not recognise precedence of operations: multiplication precedes addition; squaring precedes multiplication.

Interprets '=' as 'makes’ ie a signal to evaluate what has gone before.

Jasbinder: Algebraic notation

Why do learners make mistakes?

Lapses in concentration.

Hasty reasoning.

Memory overload.

Not noticing important features of a problem.

or…through misconceptions based on:

alternative ways of reasoning;

local generalisations from early experience.

Generalisations made by learners 0.567 > 0.85

The more digits, the larger the value.

3÷6 = 2 Always divide the larger number by the smaller.

0.4 > 0.62The fewer the number of digits after the decimal point, the larger the value. It's like fractions.

5.62 x 0.65 > 5.62Multiplication always makes numbers bigger.

Generalisations made by learners 1 litre costs £2.60;

4.2 litres cost £2.60 x 4.2;0.22 litres cost £2.60 ÷ 0.22.If you change the numbers, you change the operation.

Area of rectangle ≠ area of triangleIf you dissect a shape and rearrange the pieces, you change the area.

AB C

AB

C

If x + 4 < 10, then x = 5.Letters represent particular numbers.

3 + 4 = 7 + 2 = 9 + 5 = 14.‘Equals' means 'makes'.

In three rolls of a die, it is harder to get 6, 6, 6 than 2, 4, 6. Special outcomes are less likely than more representative outcomes.

Generalisations made by learners

Some more limited generalisations What other generalisations are only true in

limited contexts? In what contexts do the following

generalisations work? If I subtract something from 12, the answer will be

smaller than 12. The square root of a number is smaller than the

number. All numbers can be written as proper or improper

fractions. The order in which you multiply does not matter. You can differentiate any function. You can integrate any function.

What do we do with mistakes and misconceptions? Avoid them whenever possible? "If I warn learners about the misconceptions as I

teach, they are less likely to happen. Prevention is better than cure.”

Use them as learning opportunities?"I actively encourage learners to make mistakes and to learn from them.”

Some principles to consider Encourage learners to explore misconceptions

through discussion. Focus discussion on known difficulties and

challenging questions. Encourage a variety of viewpoints and

interpretations to emerge. Ask questions that create a tension or ‘cognitive

conflict' that needs to be resolved. Provide meaningful feedback. Provide opportunities for developing new ideas

and concepts, and for consolidation.

Look at a session from the pack What major mathematical concepts are involved

in the activity? What common mistakes and misconceptions will

be revealed by the activity? How does the activity:

encourage a variety of viewpoints and interpretations to emerge?

create tensions or 'conflicts' that need to be resolved?

provide meaningful feedback? provide opportunities for developing new

ideas?