Scribd
Upload
61 views28 pages

Teachers' Specialized Content Knowledge: Preparing Future Elementary School Teachers To Teach Mathematics

This document discusses improving pre-service elementary teachers' mathematical content knowledge through specialized instructional tasks. It outlines the types of mathematical knowledge teachers need, including profound understanding of fundamental mathematics and mathematical knowledge for teaching. The document then describes an elementary pre-service mathematics project that developed instructional tasks focusing on number theory, fractions, ratio, proportion, geometry, and measurement. Preliminary testing found that use of the tasks led to significant achievement gains compared to a control group.

Uploaded by

Atiqah Nizam
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
Available Formats
Download as PDF, TXT or read online on Scribd
61 views28 pages

Teachers' Specialized Content Knowledge: Preparing Future Elementary School Teachers To Teach Mathematics

This document discusses improving pre-service elementary teachers' mathematical content knowledge through specialized instructional tasks. It outlines the types of mathematical knowledge teachers need, including profound understanding of fundamental mathematics and mathematical knowledge for teaching. The document then describes an elementary pre-service mathematics project that developed instructional tasks focusing on number theory, fractions, ratio, proportion, geometry, and measurement. Preliminary testing found that use of the tasks led to significant achievement gains compared to a control group.

Uploaded by

Atiqah Nizam
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
Available Formats
Download as PDF, TXT or read online on Scribd
You are on page 1/ 28

Teachers Specialized Content

Knowledge: Preparing Future


Elementary School Teachers to
Teach Mathematics
Elementary Pre-Service Teachers
Mathematics Project

Suzanne Chapin
schapin@bu.edu
Boston University
2

Why Focus on Teachers Knowledge?


Pre-service and in-service elementary teachers do not
have a deep understanding of the mathematics they
teach (van Es & Conroy, 2009; Philipp et al., 2007; NRC,
2001; Ball, 1990)

There is widespread agreement that teachers


mathematical knowledge has a profound effect on
instruction and student achievement (NMAP, 2008;
NCTQ, 2008; Hill et al., 2005)
To be effective, mathematics teachers must know the content they
will teach in a deep and connected way (Ball, Thames, & Phelps,
2008; Ma, 1999)
3

What Knowledge Should Teachers


Have?
Profound Understanding of Fundamental
Mathematics (Ma, 1999):
Knowledge that is deep, broad, and thorough
Consists of knowledge packages

Mathematical Knowledge for Teaching (Ball, Thames, &


Phelps, 2008):
Knowledge of mathematics that is specific to the task
of teaching
Includes several types of content knowledge (common,
specialized, and pedagogical)
Mathematical Knowledge for Teaching
(MKT)

Domains of Mathematical Knowledge for Teaching (Ball, Thames, & Phelps, 2007, p. 42).
Teachers with mathematical knowledge
for teaching can
Explain terms and concepts to students
Interpret students statements and solutions
Judge and correct textbook treatments of
particular topics
Use representations accurately
Determine sequences of instruction
Ask questions that assist students in organizing
knowledge around important ideas
Provide examples of mathematical concepts,
algorithms, or proofs
What else do we know about
mathematical knowledge for teaching?

Linked to student achievement


Can be improved through
experiences and instruction
More than simply
General mathematical knowledge
General intelligence
General pedagogical knowledge
What are some of the challenges
mathematics teacher educators face?

Students prior experiences and


beliefs
Mathematical skills
Functional fixedness
Decompression (inability to
unpack steps in a procedure)
Additional Challenges

MKT can be hard for instructors (including


mathematicians) to get a handle on and to teach
Curriculum is not transparent
Enacting tasks to focus on MKT can be challenging
Staying focused on the mathematics and not on how to teach the
math
Unpacking the mathematics sufficiently and convincingly to help pre-
service teachers see what there is to learn and do
Making visible the connections to the kinds of mathematical thinking,
judgment, reasoning one has to do in teaching
Keeping the problems focused on MKT and not just M
Elementary Teachers Pre-Service
Mathematics Project

Dicky Ng
Suzanne Chapin
Jessica Shumway
Ziv Feldman
Johanna Bunn
Nancy Anderson
Matthew Chedister
Alejandra Salinas
Diana Cheng
Elementary Pre-Service Teachers
Mathematics Project (EMP)
Overarching Goals:
Improve prospective teachers knowledge of the mathematics
needed for teaching.

Develop course materials for prospective teachers and


instructors that especially focus on specialized content
knowledge (SCK) and the processes of generalization,
justification, and communication.
Elementary Pre-Service Teachers
Mathematics Project
Year 1 Year 2

Created instructional materials for Field testing at Boston University,


Number theory Middle Tennessee State
Fractions University, and Utah State
University
Ratio and proportion
Geometry Revising student materials
Geometric measurement
Refining support materials for
instructors
Piloted drafts of 28 tasks at 5
institutions in MA Researching the efficacy of the
tasks and the role of discourse in
explaining and justifying
Snapshot of EMP Materials

For use in mathematics content courses for elementary


pre-service teachers
Replacement units consisting of instructional tasks
60 to 80-minute sessions
Specified order for the sessions
Instructors Guide for each session
EMP Design Principles
Design Features of Tasks
Subsets of problems grouped around key ideas
Multiple representations used to support reasoning
Scaffolded questions posed to help PSTs identify key ideas
Whole class discussion questions focused on explaining and justifying claims
Use of classroom artifacts to simulate the demands of teaching

Implementation Features of Tasks


Recurring cycles PSTs work on subsets of problems, discuss these in small
groups, then discuss overarching questions as a class

Emphasis during whole class discussion is on making claims, providing evidence,


and justifying those claims
Implementation Cycles

Adapted from Simon, 1994


Divisibility Task
Overview
Exploration of why the divisibility rules for 2, 4, 5, and 10
work.
Cycle 1
Explain rules for divisibility by 2, 5 and 10.
Cycle 2
Explain rule for divisibility by 4.
Cycle 3
Generalize and extend to other numbers (e.g., 8, 25) and
number theory concepts.
Summarize and Connect
Divisibility by 5 (Cycle 1)
a) What is the rule for divisibility by 5?

b) Consider the number 3,267, which can be written as 3,000 + 200 + 60 + 7. Is


3,000 divisible by 5? Is 200 divisible by 5? Is 60 divisible by 5? Is 7 divisible by 5?

c) Fred has no idea if 3,000 is divisible by 5, but he knows that 3,000 = 3 x 1000. As
a teacher, how might you use this information to help him?

d) Maria says she has another way to see if a number is divisible by 5. Here are some
examples of her strategy:

75 7 and 5. Seven is not divisible by 5 even though 5 is. So, 75 is not divisible by
5.
120 12 and 0. 12 is not divisible by 5 even though 0 is. So, 120 is not divisible
by 5.
255 25 and 5. 25 is divisible by 5 and so is 5. So, 255 is divisible by 5.

What is wrong with Marias reasoning? How can her strategy be amended so that
it would work?
Cycle 1 Continued .
Carol stated: I can use what I know about
divisibility by 5 to explain why the rule for
divisibility by 10 works. I considered each of the
place values separately: thousands, hundreds,
tens, and ones. Johan said, I think about
remainders when dividing by 10. What does
each student mean? Explain in your own words
why you only have to examine the ones digit
when deciding if a number is divisible by 10.
Group Discussion Question (Cycle 1)

Explain why looking at the digits in the ones place works


to check for divisibility by 2, 5 and 10 but not for
divisibility by other numbers such as 3.
PSTs ideas
Ten is divisible by 2, 5 and 10.
Any whole number can be thought of as a multiple of ten
plus some amount of units.
Any multiple of 10 is divisible by factors of 10.
Ten is not divisible by 3 and powers of 10 are not divisible
by 3, so we cant simply examine the ones digit to see if it is
divisible by 3.
Divisibility by 4 (Cycle 2)
Group Discussion Questions (Cycle 2)

Why might a teacher want students to construct numbers using


base-10 blocks when learning about divisibility by 4?

How is the explanation for the divisibility rule for 4 similar to and
different from the explanations for the divisibility rules for 2, 5, and
10?
Generalizing and Extending (Cycle 3)
So far you've looked at divisibility rules in which the
divisors are factors of 10 (e.g., 2, 5, and 10) or factors of
100 (e.g., 2, 5, 10 and 4).
a) Use what you have learned so far to explain why you examine
the last three digits of a number to see if it is divisible by 8 to
see if the original number is divisible by 8 (e.g., 23,816 is
divisible by 8).
b) Make up a divisibility rule for 25. Explain why your rule
works.
Generalizing and Extending (Cycle 3)
An important idea in mathematics is as follows: If n is a
factor of a number, a, and n is a factor of a number, b,
then n is a factor of their sum, (a + b). Explain the
connections you see between this idea and the divisibility
rules for 2, 4, 5, and 10.
Preliminary Testing of Efficacy of the Materials

Does the use of the EMP instructional tasks result in


student achievement gains?

Is there a difference in mathematics achievement


between the intervention group using the EMP tasks and
a comparison group of students?
Pre- and Post-Test Results Geometric
Measurement

Sample: 54 PSTs at BU.

Mean number of points gained was 10.1.


Independent Samples t-Test conducted; df=53, p<0.001
Intervention vs Control at BU
Boston University Subjects
N=56

Table 1
Adjusted Means from Analyses of Covariance: The Elementary and Middle School
Number and Operations Content Knowledge Instrument Forms A and B
Adj. Posttest Mean Obtained Post Test Mean
Comparison Treatment F Comparison Treatment
(n=19) (n=37) (n=19) (n=37)
____________________________________________________________

Total Scores 12.44 15.40 14.08*** 12.47 15.38

***p<.001
How EMP Tasks Support the Development of
PSTs Mathematical Knowledge
Questions are scaffolded in each implementation cycle
Implementation cycles build on prior cycles
Cycles work together to help PSTs identify key mathematical ideas
that comprise robust justifications for the focus of the task (e.g.,
Why do these divisibility rules work?)
How EMP Tasks Connect to the
Mathematical Demands of Teaching

PSTs are asked to:


Give or evaluate mathematical explanations and justifications
Analyze students thinking and errors

Choose and use representations

Analyze textbook examples in terms of the mathematical demands

Ball, Thames, Phelps (2008)


Questions?

You might also like