APPENDIX C
Standards for Grades 6–8
Middle-grades students should see mathematics as an exciting, useful, and
creative field of study. As they enter adolescence, students experience
physical, emotional, and intellectual changes that mark the middle grades as a
significant transition point in their lives. During this time, many students
will solidify conceptions about themselves as learners of mathematics—about
their competence, their attitude, and their interest and motivation. These
conceptions will influence how they approach the study of mathematics in later
years, which will in turn influence their life opportunities. Middle-grades
students are drawn toward mathematics if they find both challenge and support in
the mathematics classroom. Students acquire an appreciation for, and develop an
understanding of, mathematical ideas if they have frequent encounters with
interesting, challenging problems.
Children may mature early or late
In the middle-grades mathematics classroom, young adolescents should regularly
engage in thoughtful activity tied to their emerging capabilities of finding and
imposing structure, conjecturing and verifying, thinking hypothetically,
comprehending cause and effect, and abstracting and generalizing. In these
grades, each student follows his or her own developmental timetable. Some mature
early, and others late. Some progress rapidly, others more slowly. Thus, every
middle-grades teacher faces the challenge of dealing with many aspects of
diversity. Yet students also display some commonalities. For example, young
adolescents are almost universally sensitive to the influence of their peers.
There will always be differences in intellectual
development The differences in intellectual development and emotional
maturity and the sensitivity of individuals to peer-group perceptions make it
especially important for teachers to create classroom environments in which
clearly established norms support the learning of mathematics by everyone.
What is p. 211
p. 211 An ambitious, focused mathematics program for all students in the middle
grades is proposed in these Standards. Ambitious expectations are identified in
algebra and geometry that would stretch the middle-grades program beyond a
preoccupation with number. In recent years, the possibility and necessity of
students' gaining facility in algebraic thinking have been widely » recognized.
Accordingly, these Standards propose a significant amount of algebra for the
middle grades. In addition, there is a need for increased attention to geometry
in these grades. Facility in geometric thinking is essential to success in the
later study of mathematics and also in many situations that arise outside the
mathematics classroom.
Why more geometry is recommended
Moreover,
geometry is typically the area in which U.S. students perform most poorly on
domestic and international assessments of mathematics proficiency. Therefore,
significantly more geometry is recommended in these Standards for the middle
grades than has been the norm. The recommendations are ambitious—they call for
students to learn many topics in algebra and geometry and also in other content
areas. To guard against fragmentation of the curriculum, therefore,
middle-grades mathematics curriculum and instruction must also be focused and
integrated.
Facility with rational numbers
Specific foci are identified in several content areas. For example, in number
and operations, these Standards propose that students develop a deep
understanding of rational-number concepts, become proficient in rational-number
computation and estimation, and learn to think flexibly about relationships
among fractions, decimals, and percents. This facility with rational numbers
should be developed through experience with many problems involving a range of
topics, such as area, volume, relative frequency, and probability. In algebra,
the focus is on proficiency in recognizing and working effectively with linear
relationships and their corresponding representations in tables, graphs, and
equations; such proficiency includes competence in solving linear equations.
Students can develop the desired algebraic facility through problems and
contexts that involve linear and nonlinear relationships. Appropriate problem
contexts can be found in many areas of the curriculum, such as using
scatter plots and approximate lines of fit to give meaning to the concept of
slope or noting that the relationship between the side lengths and the
perimeters of similar figures is linear, whereas the relationship between the
side lengths and the areas of similar figures is nonlinear.
Curricular focus and integration are also evident in the proposed emphasis on
proportionality as an integrative theme in the middle-grades mathematics
program. Facility with proportionality develops through work in many areas of
the curriculum, including ratio and proportion, percent, similarity, scaling,
linear equations, slope, relative-frequency histograms, and probability. The
understanding of proportionality should also emerge through problem solving and
reasoning, and it is important in connecting mathematical topics and in
connecting mathematics and other domains such as science and art.
Linear, non linear, and Pythagorean relationship
p. 212 In the recommendations for middle-grades mathematics outlined here,
students will learn significant amounts of algebra and geometry throughout
grades 6, 7, and 8. Moreover, they will see algebra and geometry as
interconnected with each other and with other content areas in the curriculum.
They will have experience with both the geometric representation of algebraic
ideas, such as visual models of algebraic identities, and the algebraic
representation of geometric ideas, such as equations for lines represented on
coordinate grids. They will see the value of interpreting both algebraically and
geometrically such important mathematical ideas as the slope of a line and the
Pythagorean relationship. They also will relate algebraic and geometric ideas to
other topics—for example, when they reason about percents using visual models or
equations or when they represent an approximate line of fit for a scatter plot
both geometrically and » algebraically. Students can gain a deeper understanding
of proportionality if it develops along with foundational algebraic ideas such
as linear relationships and geometric ideas such as similarity.
Extended experience over all three years in the middle
grades
Students' understanding of foundational algebraic and geometric ideas should be
developed through extended experience over all three years in the middle grades
and across a broad range of mathematics content, including statistics, number,
and measurement. How these ideas are packaged into courses and what names are
given to the resulting arrangement are far less important than ensuring that
students have opportunities to see and understand the connections among related
ideas. This approach is a challenging alternative to the practice of offering a
select group of middle-grades students a one-year course that focuses narrowly
on algebra or geometry. All middle-grades students will benefit from a rich and
integrated treatment of mathematics content. Instruction that segregates the
content of algebra or geometry from that of other areas is educationally unwise
and mathematically counterproductive.
Principles and Standards for School Mathematics proposes an ambitious and rich
experience for middle-grades students that both prepares them to use mathematics
effectively to deal with quantitative situations in their lives outside school
and lays a solid foundation for their study of mathematics in high school.
Students are expected to learn serious, substantive mathematics in classrooms in
which the emphasis is on thoughtful engagement and meaningful learning.
For those who make decisions about the design and organization of middle-grades
mathematics education, it would be insufficient simply to announce new and
more-ambitious goals like those suggested here. School system leaders need to
commit to and support steady, long-term improvement and capacity building to
accomplish such goals. The capacity of schools and middle-grades teachers to
provide the kind of mathematics education envisioned needs to be built. Special
attention must be given to the preparation and ongoing professional support of
teachers in the middle grades.
Teachers need to
Teachers need to develop a sound knowledge of mathematical ideas and
excellent pedagogical practices and become aware of current research on
students' mathematics learning. Professional development is especially important
in the middle grades because so little attention has been given in most states
and provinces to the special preparation that may be required for mathematics
teachers at these grade levels. Many such teachers hold elementary
school generalist certification, which typically involves little specific
preparation in mathematics. Yet teachers in the middle grades need to know much
more mathematics than is required in most elementary school
teacher-certification programs. Some middle-grades mathematics teachers hold
secondary school mathematics-specialist certification. But middle-grades
teachers need to know much more about adolescent development, pedagogical
alternatives, and interdisciplinary approaches to teaching than most secondary
school teacher-certification programs require. In order to accomplish the
ambitious goals for the middle grades that are presented here, special
teacher-preparation programs must be developed.
We have refined the ways we prepare children to understand and use mathematics.
Principles and Standards for School Mathematics urges us to start building the
foundations of mathematics success even before students enter kindergarten. Our
vision of a high-quality mathematics education for every child demands that we
find approaches for improving the mathematics content knowledge and pedagogy of
all teachers, especially elementary school teachers.
In US there is insufficient preparation to
the mathematics" elementary school teachers
In most states, teachers in grades K–6 are not mathematics specialists, nor have
states asked them to be. But as we reach for higher standards, we are faced with
a challenge. How do we better prepare elementary school teachers in mathematics
and mathematics pedagogy? According to the National Science Foundation, only 7
percent of elementary school teachers and 18 percent of middle grades
mathematics teachers majored or minored in mathematics or mathematics education.
Furthermore, 40 percent of elementary school and middle grades teachers of
mathematics report that they do not feel qualified to teach the content that
they teach. In some school districts, large percentages of middle grades and
high school mathematics teachers lack the certification to teach mathematics.
For example, in one major U.S. city, 57 percent of the middle grades mathematics
teachers lack mathematics certification, and 20 percent have not satisfied their
board of education college mathematics requirements.
the low level of preparation in
mathematics and mathematics teaching
The level of preparation in mathematics and mathematics teaching needed to
implement Standards-based mathematics programs may be largely inconsistent with
the preservice preparation of the majority of elementary school teachers in the
United States and Canada. We must address these crucial questions: Do teachers
lack the deep understandings of mathematics that would allow them to teach
concepts flexibly? Can teachers make appropriate connections (a) between
arithmetic and real-life situations, and (b) among arithmetic concepts? Are
teachers being prepared to implement Standards-based mathematics programs?
In every state and province, students must demonstrate a greater knowledge and
understanding of mathematics--and mathematics teachers are expected to better
facilitate their learning. This is especially true for elementary school
teachers. That is why high-quality professional development is a necessary
component of mathematics education reform. Does it work? Consider recent reforms
in Puerto Rico (see Christian Science Monitor, 30 May 2000). Professional
development was a fundamental component of mathematics reform efforts there. Six
years after instituting instruction consistent with Principles and Standards for
School Mathematics, important differences were observed. Public school children
who had attended reform classes in middle grades and high school every year
out-scored private school students who did not attend reform classes by 58
points in mathematics reasoning and by 79 points in mathematics achievement on
College Entrance Examination Board tests.
Yet, amazingly, there is currently no comprehensive system in place in the
United States or Canada to help mathematics teachers grow and develop
professionally. We must change this, especially for elementary school teachers.
Elementary school teachers cannot be expected to master and maintain new
knowledge and skills and change their current teaching practices without support
from their schools and districts. In addition to structured, ongoing
professional development beyond school hours, school systems must find ways to
give teachers more time during the school week. Teachers need time to
collaborate with colleagues, time to examine reform curricula based on
Principles and Standards, and time to incorporate new mathematics content and
teaching strategies into existing or new curricula. All teachers deserve
opportunities to develop, analyze, master, and reflect on mathematics content
and new teaching approaches that increase the likelihood that every child will
succeed.
We must give even more attention to our preservice teacher preparation programs
and requirements. And we need knowledgeable, experienced, and dedicated
mathematicians and mathematics educators to form partnerships to provide course
and professional development offerings that meet the content and pedagogical
needs and challenges facing elementary school teachers in their classrooms each
and every day.
NCTM can also play a role. This fall, the Council launched its Academy for
Professional Development, which is offering two-day--and later will offer
five-day--institutes focused on helping teachers put Principles and Standards
into practice. This is a start. Ways to expand the professional development of
mathematics teachers in the United States and Canada both in and out of the
school setting will continue to be a focus of the Council for years to come.
It's time to make changes. Excellence in mathematics teaching and learning
cannot wait. If we are to develop flexible and resourceful problem solvers for
the future, we must eliminate the mathematics of exclusion in which only a few
students gain access to the best we can offer. We must staff our classrooms at
every grade level with well-prepared, knowledgeable mathematics teachers right
now. And we must teach in ways that develop successful learners of mathematics.
Our children deserve it.