International Comparisons of Mathematics Achievement

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International Comparisons of Mathematics Achievement

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Title: International Comparisons of Mathematics Achievement

1
International Comparisons of Mathematics
Achievement

Kaye Stacey

2
A growing concern

Dates approximate different years for data
collection around the world, publications etc
FIMSS 1967 IEA
SIMS 1980 (but maths from an ACER study) IEA
TIMSS 1994 (third) IEA (Years 4, 8 12)
TIMSS-R 1999 (repeat)
TIMSS video study ( 100 lessons in each of 8
countries)
PISA 2000 (R m s) OECD (15 year olds)
TIMSS 2002 (trends) (Years 4 8)
PISA 2003 (r M s) also problem solving
TIMSS 2006 (4 yearly cycle being established)
PISA 2006 (r-m-S) (3 yearly cycle being
established)

3
Why two series of studies?

IEA
all countries on an equal footing, with positive
and negative consequences (e.g. translation)
Curriculum based study
Population defined by school level and class,
which makes teaching surveys better
PISA
Directed to needs of OECD countries ( others)
Population defined as 15 year olds
Looking at outcome of schooling - math literacy

4
PISA assesses Mathematical Literacy

Mathematics literacy is the capacity to identify,
understand and engage in mathematics, and to make
well-founded judgments about the role that
mathematics plays in an individual's current and
future private life, occupational life, social
life with peers and relatives, and life as a
constructive, concerned and reflective citizen.
(OECD PISA)
A key feature is being able to bring mathematical
skills to bear in situations which are not
presented in mathematical terms.
OECD-PISA divides into 3 classes, from
reproduction to generalisation, formulation and
analysis.

5
BOOKSHELVES (FROM PISA 2003, ASSESSMENT FOR 15
YEAR OLDS)

To complete one set of bookshelves a carpenter
needs the following components
4 long wooden panels,
6 short wooden panels,
12 small clips,
2 large clips and
14 screws.
The carpenter has in stock 26 long wooden panels,
33 short wooden panels, 200 small clips, 20 large
clips and 510 screws.
How many sets of bookshelves can the carpenter
make?

6
PISA Framework for 2003 Mathematics

Situations and context
Everyday and personal
Workplace and scientific
Mathematical content - the four overarching ideas
Space and shape
Change and relationships
Quantity
Uncertainty
Mathematical processes
Mathematisation
The competencies
Competency clusters
Reproduction cluster
Connections cluster
Reflection cluster
Assessing mathematical literacy
Task characteristics
Assessment structure
Reporting mathematical proficiency

7
(No Transcript)
8
Australias performance

Good !
Plenty of room for improvement !

9
Finnish National Board of Education Adapted from
http//www.oph.fi/english/page.asp?path447,488,42
774

The strengths of Finnish schools include good
teachers, efficient teaching and uniform quality.
The status of the school does not seem to affect
the level of the students performance.
Weakest students raise Finland to the top in
PISA. The mathematics skills of Finnish students
are among the best in the world, although
attitudes to mathematics leave room for
improvement.
The skills of Finnish students were among the
best in all domains assessed in the PISA 2003
survey, that is, mathematics, reading literacy,
sciences and problem solving. This outstanding
achievement is based, in particular, on the good
performance even by the weakest and average
students. The average score achieved by the
weakest quarter of Finnish students was by far
better than that of the corresponding quarter in
any other country. The difference to the OECD
average score in the weakest quarter was 56 in
mathematics, 61 in science and problem solving
and as much as 64 in reading literacy. On the
other hand, Finlands best quarter was the best
in the OECD only in reading literacy. The best
Finnish students were surpassed by the best in 4
countries in mathematics, 1 country in science
and 3 countries in problem solving. The good
level of Finlands weakest students is also
reflected in the smallness of groups at risk.
With regard to the information society, only 7
of Finnish students had poor mathematics skills
(OECD average 21) and 6 poor reading literacy
(OECD average 19).The Finnish school system has
succeeded in supporting weaker students. In
future, more attention should also be paid to
developing the skills of the better achieving
children. As a means to this end, PISA
researchers mention differentiated teaching in
the teaching group and encouraging talented
students to develop and use their skills both in
school and outside it.

10
Finnish National Board of Education Adapted from
http//www.oph.fi/english/page.asp?path447,488,42
774

The strengths of Finnish schools include good
teachers, efficient teaching and uniform quality.
The status of the school does not seem to affect
the level of the students performance.
PRINCIPALS AND STUDENTS APPRECIATE TEACHERS
Finnish principals see their teachers commitment
and high work ethic as the key strengths of their
schools. They judge the teachers influence on
the schools atmosphere to be more positive than
in the OECD countries on average. In particular,
principals see their teachers as a positive
resource in creating a good school environment.
According to PISA researchers, this is made
possible because Finnish teachers are quite
independent and have wide powers of decision
compared to their colleagues in other countries.
Finnish students have positive attitudes towards
their mathematics teachers.
Mathematics teachers were mainly seen as a strong
support and guide to the students own learning.
Mathematics lessons, on the other hand, were
criticised for being restless. The feeling of
fellowship in the school community was slightly
weaker among young Finns than among young people
in other countries on average.
FINNISH TEACHING EFFECTIVE
According to the PISA researchers, Finnish basic
teaching can be characterised as efficient. The
time the students spend studying was one of the
lowest in the countries surveyed. At the same
time, resources allocated to education are only
OECD average, so work by students and teachers
has been very efficient.

11
TIMSS
12
Research questions for TIMSS

What are mathematics and science students around
the world expected to learn?
What opportunities are provided for students to
learn mathematics and science?
What mathematics and science concepts,processes
and attitudes have studentslearned?

13
International Association for theEvaluation of
Educational Achievement

IEA http//www.iea.nl/
The International Association for the Evaluation
of Educational Achievement (IEA) is an
independent, international cooperative of
national research institutions and governmental
research agencies.
Through its comparative research and assessment
projects, IEA aims to
Provide international benchmarks that may assist
policy-makers in identifying the comparative
strength and weaknesses of their educational
systems
Provide high-quality data that will increase
policy-makers understanding of key school- and
non-school-based factors that influence teaching
and learning
Provide high-quality data which will serve as a
resource for identifying areas of concern and
action, and for preparing and evaluating
educational reforms
Develop and improve educational systems capacity
to engage in national strategies for educational
monitoring and improvement
Contribute to development of the world-wide
community of researchers in educational
evaluation
Since its inception in 1958, the IEA has
conducted more than 23 research studies of
cross-national achievement. The regular cycle of
studies encompasses learning in basic school
subjects. Examples are the Trends in Mathematics
and Science Study (TIMSS 1995, TIMSS 1999, TIMSS
2003, TIMSS 2007) and the Progress in
International Reading Literacy Studies (PIRLS
2001, PIRLS 2006). IEA projects also include
studies of particular interest to IEA members,
such as the TIMSS-R Video Study of Classroom
Practices, Civic Education, Information
Technology in Education (SITES-M1, SITES-M2,
SITES 2006), and Preprimary Education.
IEA studies are an important data source for
those working to enhance students learning at
the international, national and local levels. By
reporting on a wide range of topics and subject
matters, the studies contribute to a deep
understanding of educational processes within
individual countries, and across a broad
international context. In addition, the cycle of
studies provides countries with an opportunity to
measure progress in educational achievement in
mathematics, science and reading comprehension.
The cycle of studies also enables monitoring of
changes in the implementation of educational
policy and identification of new issues relevant
to reform efforts.

14
IEA current studies

TIMSS Advanced 2008
Replication of TIMSS 1995 Advanced Mathematics
and Physics
First administered in 16 countries in 1995, TIMSS
Advanced assesses school-leaving students with
special preparation in advanced mathematics and
physics. Countries that...
TIMSS 2007
Trends in International Mathematics and Science
Study 2007
TIMSS 2007 is the fourth assessment in the
framework of the Trends in International
Mathematics and Science Study. The previous
assessments, conducted in 1995, 1999, and...

15
The largest educational study . . . (1994 data)

500 000 students
15 000 schools
45 countries
5 grades in 3 populations
1500 items
31 languages
millions of hours and dollars

16
The largest educational study..

Strengths of the data
sheer breadth of study
range of participants
curriculum, teaching, people, attitudes
several aspects of achievement
sampling and quality control measures
Cautions
doesnt measure everything
little depth of information on any one aspect
needs sophisticated analysis

17
TIMSS 2002 Content Cognitive Dimensions

Mathematics
Content Domains
Number
Algebra (Patterns and relationships at Grade 4)
Measurement
Geometry
Data
Cognitive Domains
Knowing Facts and Procedures
Using Concepts
Solving Routine Problems
Reasoning
Science
Content Domains
Life Science
Chemistry (combined into physical science at
grade 4)
Physics (combined into physical science at grade
4)
Earth Science

18
TIMSS 2003 Grade 4 Content Domain Number Main
Topic Fractions and decimals Cognitive Domain
Using Concepts
Click here for TIMSS Grade 4 Mathematics Released
Items
19
TIMSS 2003 Grade 4 Content Domain
Measurement Main Topic Attributes and
units Cognitive Domain Knowing Facts and
Procedures
Click here for TIMSS Grade 4 Mathematics Released
Items
20
Item types

STUDENTS
test booklets - rotating and matching
questionnaires
multiple choice short answer
performance tasks
TEACHERS, PRINCIPALS
questionnaires

21
SIMS The Second International Mathematics Study
1977- 1981

The study examined mathematics education at three
levels curricular intentions, implemented
curriculum, and student achievement. Student
performance was measured and reported separately
for five areas arithmetic, algebra, geometry,
measurement, and statistics. The study included
some features that involved a replication of the
First International Mathematics Study (FIMS). It
also incorporated a detailed longitudinal
component designed to investigate causal
relationships between the output and input
measures of mathematics education.
Target Population
This was 13-year-old students and students in the
final grade of secondary education.
Participating Countries
Belgium (Flemish), Belgium (French), Canada
(British Columbia and Ontario), England and
Wales, Finland, France, Hong Kong, Hungary,
Israel, Japan, Luxembourg, Netherlands, New
Zealand, Nigeria, Scotland, Swaziland, Sweden,
Thailand, United States.
Key Findings
At the middle school level, there was no one
subtest on which students performed in the same
general way across the systems. For example,
students in five systems performed best on the
arithmetic subtest while those from six other
systems had their poorest performance on that
same set of items. One apparent trend was that
students from any system were more likely to have
their best or worse performance occurring on
either arithmetic or geometry than on other
areas.
Japan and Hong Kong were the highest achieving
countries at the final grade of the secondary
school. Geometry curricula, more than any other
branch of school mathematics, differed across the
educational systems.
At the middle school level, girls tended to
outperform boys in computational skills and
algebra. Boys performed better in geometry and
measurement. By the end of secondary school, boys
were outperforming girls in every subtest and in
every country.
There were many similarities among teachers at
both grade levels and across systems regarding
the teaching of mathematics. Teachers were using
whole-class instructional techniques, relying
heavily on prescribed textbooks, and rarely
giving differentiated instruction or assignments.
Wide differences between systems were observed in
the degree of opportunity provided to students to
complete secondary school to the Grade 12 level
or equivalent. However, during the period between
the first and the second IEA mathematics studies,
growth occurred, and in some countries (Belgium,
Finland) was very substantial (from 13 to 65
percent and from 14 to 59 percent respectively).
In the period between the two mathematics
studies, substantial changes took place in the
mathematics curricula of many systems. At the
middle school level, emphasis on arithmetic
declined while emphasis on algebra and geometry
increased. At the end of the secondary school
level, diversity between the nature and extent of
the mathematics being taught increased,
particularly with respect to calculus, geometry,
probability, and statistics.
This information is taken from the IEA website
http//www.iea.nl/sims.html

22
Trends in Mathematics and Science Study
2003(2001 2004) Extract from IEA website. Key
Findings

The Asian countries outperformed the other
participants. Singapore was the top performing
country at both the fourth and eighth grades in
mathematics and science. Also Chinese Taipei,
Hong Kong SAR and Republic of Korea did very
well.
At the eight grade countries that showed
significant improvement in mathematics form 1995
to 2003 included the Republic of Korea, Hong Kong
SAR, Latvia (Latvian speaking schools), United
States and Lithuania. At the forth grade, they
were Hong Kong SAR, Latvia (Latvian speaking
schools), England, Cyprus, New Zealand and
Slovenia. For science, improvement was registered
in Republic of Korea, Hong Kong SAR, the United
States, Australia, Slovenia, Lithuania and Latvia
(Latvian speaking schools) for grade eight,
Singapore, Hong Kong SAR, England, Hungary,
Latvia (Latvian speaking schools), New Zealand,
Slovenia, Cyprus, and Iran.
Decreases in achievement were found in Japan,
Belgium (Flemish), the Russian Federation, the
Slovak Republic, Sweden, Bulgaria, Norway, Cyprus
(mathematics eighth grade), the Netherlands and
Norway (mathematics fourth grade), Sweden, the
Slovak Republic, Belgium (Flemish), Norway,
Bulgaria, Iran and Cyprus (science eighth grade),
Japan, Scotland and Norway (science fourth
grade).
Gender differences were negligible in many
countries for mathematics, but in science at the
eighth grade boys had significantly higher
achievement than girls in the majority of
countries. Nevertheless girls had greater
improvement on average than boys, especially
since 1999.
The home context (highly educated parents,
speaking the language of the test at home, more
books at home, and frequently using the computer)
was important to foster higher achievement.
Providing students the opportunity to learn the
content assessed was fundamental. The content
needed to be delivered in the classroom and in an
effective way.
Positive school environment was related to higher
achievement (positive climates for learning,
fewer students from disadvantaged homes, and
schools where teachers and students felt safe).

23
Trends in Mathematics and Science Study
2003(2001 2004) Extract from IEA website

TIMSS was designed to measure trends in students
mathematics and science achievement. TIMSS 2003
was the third in a four-year-cycle of
assessments. TIMSS tests contained questions
requiring students to select appropriate
responses or to solve problems and answer
questions in an open-ended format. From 2003 on,
TIMSS has gradually placed more emphasis on
questions and tasks that offer better insight
into the analytical, problem-solving, and inquiry
skills and capabilities of students. In addition,
students, teachers, and school principals in each
participating country were asked to complete
questionnaires concerning the context for
learning mathematics and science, so as to
provide a resource for interpreting the
achievement results and to track changes in
instructional practices.
The data collection for TIMSS 2003 was conducted
in OctoberDecember 2002 (Southern Hemisphere)
and MarchJune 2003 (Northern Hemisphere).
Target Population
TIMSS 2003 was assessing the mathematics and
science achievement of children in two target
populations. These populations correspond to the
upper grades of the TIMSS 1995 Population 1 and
Population 2 target definitions. Generally, these
are the fourth and eighth grades.
Participating Countries
Argentina, Armenia, Australia, Bahrain, Belgium
(Flemish), Botswana, Bulgaria, Canada (Ontario
and Québec), Chile, Chinese Taipei, Cyprus,
Egypt, England, Estonia, Ghana, Hong Kong (SAR),
Hungary, Indonesia, Iran, Israel, Italy, Japan,
Jordan, Korea, Latvia, Lebanon, Lithuania,
Macedonia, Malaysia, Moldova, Morocco,
Netherlands, New Zealand, Norway, Palestinian
Autonomy, Philippines, Romania, Russian
Federation, Saudi Arabia, Scotland, Serbia,
Singapore, Slovak Republic, Slovenia, South
Africa, Sweden, Syria, Tunisia, United States,
Yemen. The Basque Country (Spain) and Indiana
State (United States) also participated in the
TIMSS 2003 data collection.

24
Australian Teachers - an area of concern

Teachers of 13 yr olds
only 5 under 30
only 26 think society appreciates their work
50 would change to another career if they had
the opportunity (only NZ higher)
Teachers of 9 yr olds
only 35 think society appreciates their work
44 would change to another career if they had
the opportunity (only NZ higher)

25
Results from TIMMS 1994 study

Mainly from Australian reports on TIMSS published
by ACER (Lokan, Greenwood Ford, 1995)
Typical of results from many of the studies, but
frequently differing in detail.

26
Australian Attitudes to maths
27
Australian Achievement in maths

9 year olds above average
tied for 7th (out of 26) with 6 countries
a top western, English-speaking country
13 year olds above average
tied for 9th (out of 41) with 14 countries
a top western, English-speaking country
Year 12 students did well (in small group of
countries!)

28
Interesting countries on international ranking

Singapore, Japan, Hong Kong, Korea
Netherlands
25 years highly professional development of
Realistic Mathematics Education

29
Features of Australian curriculum

Seeking wide participation
Broad curriculum - all main content areas
Emphasising everyday usefulness including
embracing calculators
very informal maths with little proof and rigour
Aiming to develop strong understanding first,
then skills
Advocating active teaching methods

30
Encouraging wide participation

Language background
identifying areas of success and of need
Gender
no achievement differences for 9 or 13 yr olds
Home background
most highly correlated with achievement (0.4)
Australias results have very high spread

31
Results by content area

Achievement by content area is generally in line
with overall performance
no evidence that a narrow curriculum gives better
results
Geometry / Space performance
extremely high for 9 yr olds
relatively our worst area for 13 yr olds
curriculum explanation?
State differences reflect curriculum emphasis

32
Everyday usefulness in the modern world

Less emphasis on computation,
because of advent of calculators
AND
Emphasis on strong understanding.

33
Computational skill

9 year olds (upper)
6000 - 2369 Aust 47 Intl 71
23 x 3 Aust at intl average
6971 5291 Aust 76 Intl 84
13 year olds (upper)
(8/35) divided by (4/15) Aust 25 lowest
6000 - 2369 Aust 85 Intl ?

34
Conceptual understanding of number - 13 yr olds
(upper grade)

choose largest of 4 fractions
Aust 43 Intl 39 Sing 76
order three decimals and a fraction
Aust 47 Intl 44 Sing
84

35
Conceptual understanding of number 9 yr olds
(upper grade)

0.4 as four tenths
Aust 48 Intl 39
25x18 is how much more than 24x 18
Aust 40 Intl 45
smallest whole number made from 4,3,9,1 Aust
65 Intl 43
1/4 pie less than 1/3 pie
Aust 24 Intl 26

36
0.4 is the same as
37
Which number is the largest?
38
Which number is the smallest?(similar to TIMSS
item, real TIMSS data)
39
Understanding before skills

Have lower skills, but understanding is not yet
showing great improvement
Work on
activities from which children really learn
(note Japanese lessons)
tackle the hard ideas more thoroughly, maybe
starting earlier

40
Which number represents the shaded part of the
figure? (9 yr olds - upper grade)
41
Differences between the states - Australias most
important data source?

Significant differences in overall achievement
Variations in performance by content area (but
tending to follow overall pattern)

42
Significant differences between states - 13 year
olds (states ordered by achievement)
43
Significant differences between states - 9 year
olds (states ordered by achievement)
44
Why state differences?

Age and/or amount of schooling ?
Home background and social factors ?
Place of maths in total curriculum ?
Differences in content taught ?
Teaching practices ?

45
Achievement, age and years at school
46
Teaching practices

Data difficult to interpret
Many advocated methods have no straightforward
relationship to achievement - teacher
professional development may need to be more
sophisticated

47
Teaching practices a common pattern