Transcript Document

The Challenges of Scale: Designing
Learning Organizations for Instructional
Improvement in Mathematics
Paul Cobb
Vanderbilt University
Purpose
• Illustrate a way of conducting research
studies that aim to inform the ongoing
improvement of mathematics teaching and
learning at scale
History of Failure
• The closer that an instructional innovation
gets to what takes place between teachers and
students in classrooms, the less likely it is that
it will implemented and sustained on a large
scale
Limited Impact of Research on
Classroom Practice
• Supporting students’ learning of central
mathematical ideas
• Instructional materials
• Teachers’ instructional practices
• Supporting mathematics teachers’
development of high-quality instructional
practices
Large-Scale Implementation
Projects
• Focus is primarily on teacher professional
development
• Unanticipated “obstacles”
• Conflicts with other district initiatives
• Lack of understanding and/or support by school
and district administrators
Large-Scale Implementation
• Flying blind: Little knowledge of the schools
and districts in which they are working
• Reactive: Plans changed in response to
unanticipated obstacles
• Proactive: Anticipate school and district
structures that might support mathematics
teachers’ ongoing improvement of their
instructional practices
Map Backwards From the Classroom
• Research on high-quality mathematics
instruction
• Demands on the teacher
• Challenges of supporting the development of
high-quality instructional practices
• School and district support structures
High-Quality Mathematics Instruction
• Keep one eye on the mathematical
horizon and the other on students’
current understandings, concerns, and
interests. (Ball, 1993)
Measuring With a Ten Bar
Measuring With a Ten Bar
• Edward: I think it’s 33 [points to where they have
marked 23 with the three cubes] because 10
[iterates the smurf bar once], 20 [iterates the smurf
bar a second time], 21, 22, 23 [counts the first,
second and third cubes within the second iteration]
Measuring With a Ten Bar
• Edward: Ten [iterates the smurf bar once], 20
[iterates the smurf bar again]. I change my mind.
She's right.
• T: What do you mean?
• Edward: This would be 20 [points to the end of
the second iteration].
Measuring With a Ten Bar
• T: What would be 20?
• Edward: This is 20 right here [places one hand at
the beginning of the “plank” and the other at the
end of the second iteration]. This is the 20. Then,
if I move it up just 3 more. There [breaks the
bar to show 3 cubes and places the 3 cubes beyond
20]. That’s 23.
Measuring With a Ten Bar
• Measuring as a sequence of separate
units
• Measuring as the accumulation of
distance
Classroom Discourse
• Not sufficient to show how measured
• Also had to explain why measured in
a particular way
• Measuring organizes distance into
units
Demands on the Teacher
• Deep understanding of mathematics
• Mathematical knowledge for teaching
• Knowledge of how students’ reasoning
develops in particular mathematical domains
• Know-in-practice how to pursuing a
mathematical agenda by building on students’
(diverse) contributions
Improvement in Instructional Practices
• Students have to adjust to the teacher
• Teaching a routine activity
• Covering instructional objectives + classroom
management
• Teacher adjusts instruction to the students
• Ongoing assessment of student reasoning
• Non-routine -- a complex and demanding activity
Framing Instructional Improvement at
Scale as a Research Issue
• Series of conjectures about school and
district structures that might support
teachers’ ongoing learning
• Instruments to document the institutional
setting of mathematics teaching
• Extent to which the conjectured support
structures have been established
Research Plan
• Four urban districts
• High proportion of students from traditionally
underserved groups of students
• Limited financial resources
• Most districts clueless about how to respond
productively to high-stakes accountability
• A small minority have reasonably worked out
strategies
Research Plan
• Document district plans for improving middleschool mathematics
• 6-10 middle schools - 30 teachers
• Four rounds of yearly data collection
• First year: Baseline data
• Document change over a three-year period in
each district
Data Collection
• Institutional setting of mathematics teaching
• Audio-recorded interviews and surveys
• Quality of teacher professional development
• Video-recordings
• Quality of instructional materials and resources
• Artifact collection
• Quality of teachers’ instructional practices
• Video-recordings of two consecutive classroom lessons
• Teachers’ mathematical knowledge for teaching
• Student mathematics achievement data
Add Value to Districts’ Improvement
Efforts
• Feed back results of analyses to districts
• Gap analysis -- how district’s plan is actually
playing out in schools
• Recommend actionable adjustments that might
make each district’s improvement design
more effective
• Design experiment at the level of the district
Research Team
Paul Cobb
Tom Smith
Erin Henrick
Kara Jackson
Chuck Munter
Sarah Green
John Murphy
Karin Katterfeld
Lynsey Gibbons
Glenn Colby
Annie Garrison
One District as an Illustrative Case
• Conjectured support structures
• The district’s improvement plan
• Findings and feedback to the district
Conjecture: Teacher Networks
• US teachers typically work in isolation
• Social support from colleagues in developing
demanding instructional practices
• Focus of teacher interactions
• Classroom instructional practice
• Depth of teacher interactions
• Mathematical intent of instructional tasks
• Student reasoning strategies
Conjecture: Key Resources for
Teacher Networks
• Time built into the school schedule for
collaboration among mathematics teachers
• Access to colleagues who have already
developed relatively sophisticated
instructional practices
• Concrete exemplars of high-quality instructional
practice
District Plan: Teacher Networks
• 1-2 mathematics teachers in each school
receive additional intensive mathematics
professional development
• Lead mathematics teachers
• Facilitate biweekly or monthly teacher study
group meetings
Findings and Recommendations:
Teacher Networks
• Quality of professional development for lead
teachers high
• Does not focus specifically on teaching
underserved groups -- English language learners
(ELLs)
• Additional professional development for lead
teachers on:
• Teaching language in the context of mathematics
-- ELLs
Findings and Recommendations:
Teacher Networks
• Collaboration between isolated pairs of mathematics
teachers in some schools
• Typically low depth
• No opportunities for lead teachers to share what
they are learning in most schools
• Common planning time for mathematics teachers
• Additional professional development for lead
teachers on:
• Process of supporting colleagues’ learning
• Organizing the content of a study group’s work
Findings and Recommendations:
Teacher Networks
• At least one mathematics teacher in each
school with a sophisticated view of highquality mathematics instruction
• Principals selected teachers for additional
professional development
• District policy: criteria for selecting lead
mathematics teachers
Conjecture: Shared Vision of High
Quality Mathematics Instruction
• Instructional goals -- what students should
know and be able to do mathematically
• How students' development of these forms
of mathematical knowing can be supported
Conjecture: Shared Vision of High
Quality Mathematics Instruction
• Coordination between district administrative
units
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Curriculum and Instruction
Leadership
Research and Evaluation
English Language Learners
Special Education
Conjecture: Shared Vision of High
Quality Mathematics Instruction
• Occupational groups: Mathematics teachers,
principals, district mathematics specialists,
district leadership specialists, …
• Differences in:
• Responsibilities
• Practices
• Professional affiliations (and professional
identities)
Conjecture: Brokers
• Participate at least peripherally in the
activities of two or more groups
• Can bridge between differing agendas for
mathematics instruction
District Plan: Shared Instructional
Vision
• Curriculum Cabinet -- heads of all district
units + area superintendents
• Professional development in instructional
leadership for all principals
• Not content specific
• Intellectually-demanding tasks
• Maintain the challenge of the tasks as they are enacted
in the classroom
• Compatible with district goals for mathematics
instruction
Findings and Recommendations: Shared
Instructional Vision
• District leaders: Inconsistent visions + not specific to
mathematics
• Form rather than function views
• Area superintendents participate in mathematics
professional development with lead teachers
• Expertise in Curriculum Cabinet
• Support alignment between Curriculum and Instruction,
and Leadership
• Brokers between district leaders and principals
Findings and Recommendations: Shared
Instructional Vision
• Principals: Not specific to mathematics
• Form rather than function views
• Teachers: At least one mathematics teacher in
each school with a sophisticated view of
high-quality mathematics instruction
• Few formal opportunities for principals to draw
on or learn from expert teachers
Findings and Recommendations: Shared
Instructional Vision
• Principals share leadership of mathematics
study groups with lead teachers
• Principals gain access to mathematics expertise in
their schools
• Brokers between mathematics teachers and
school/district leaders
• Legitimize work of lead teachers
• Lead teachers can focus on content-specific aspects
of study group activities
Conjecture: Mutual Accountability
• School leaders hold mathematics teachers
accountable for developing high-quality
instructional practices
• School leaders are accountable to
mathematics teachers (and district leaders) for
supporting teachers’ learning
Conjecture: Leadership Content
Knowledge (in Mathematics)
• Enables school and district leaders to:
• Recognize high-quality mathematics instruction
• Support teachers’ learning directly
• Organize the conditions for ongoing learning of
school and district staff
(Stein & Nelson)
Conjecture: Leadership Content
Knowledge
• Principals require a relatively deep
understanding of:
• Mathematical knowledge for teaching
• How students learn mathematics
• What is known about how to teach mathematics
effectively
• Teachers-as-learners and effective ways of
teaching teachers
Conjecture: Leadership Content
Knowledge
• Distributed across formal and informal
leaders
• Lead mathematics teachers
• Accomplished teachers as informal instructional
leaders
• Principal instructional leadership expertise involves
recognizing and capitalizing on mathematics teachers’
expertise
District Plan: Mutual Accountability
• Professional development in instructional
leadership for all principals
• In classrooms observing instruction for two
hours each day
• Use developing understanding of (content-free)
high-quality instruction to:
• Assess quality of instruction and give feedback to
teachers
• Organize school-level teacher professional
development
• Develop school improvement plans
Findings and Recommendations: Mutual
Accountability
• Most principals do not view themselves as
instructional leaders
• Most principals are spending only limited time in
classrooms
• Inconsistent messages from district leaders -- not aware
that district leaders expect them to be in classrooms
• District leaders need to communicate expectations
for what it means to be an instructional leader
clearly and consistently
• Hold principals accountable for supporting mathematics
teachers in improving their instructional practices
Findings and Recommendations: Mutual
Accountability
• Most Principals have developed form rather than
function views of high-quality mathematics
instruction
• Feedback to teachers focuses on surface level features of
instruction (e.g., arranging students in groups)
• Most principals are not organizing school-based
professional development for mathematics teachers
• No supports for principals as instructional leaders
beyond professional development
Findings and Recommendations: Mutual
Accountability
• Principals participate in at least a portion of
mathematics professional development with
lead teachers
• Principals share the leadership of
mathematics study groups
• Area superintendents provide guidance on:
• Providing constructive feedback to teachers
• Organizing school-based professional
development
Findings and Recommendations: Mutual
Accountability
• Generic classroom observation form
specifies “promotion of innovative teaching
methods”
• Redesign observation form to reflect district
vision of high-quality mathematics
instruction
Summary: Conjectured Support
Structures
• Teacher networks
• Time for collaboration
• Access to expertise
• Shared instructional vision
• Brokers
• Mutual accountability
• Leadership content knowledge
Current and Next Steps
• Fall 2009:
• Document whether districts actually act on the
basis of our feedback
• January-March 2009:
• Document the consequences of any adjustments
• May 2009:
• Second round of feedback to districts
Research Agenda
• Test, revise, and modify conjectures about
relationships between:
• Changes in school and district support structures
• Improvement in mathematics teachers’
instructional practices
• Student achievement
Research Agenda
• Refine conjectures:
• Identifying additional support structures
• Clarifying relationships between support
structures
• Specifying the conditions under which particular
support structures are important
Teachers’ Access to Expertise:
Local and External Views of Expertise
• Local views: Who teachers identify as experts
• Criteria for what counts as instructional expertise
• External views: Teachers we identified as
experts:
• District views of high-quality mathematics
instruction
• Research literature on mathematics learning and
teaching
Teachers’ Access to Expertise:
The Role of the Principal
• Teachers’ access to expertise
• Teacher networks, mathematics coaches, district
math specialists, external expertise
• Principals’ practices
• The how of instructional leadership
• Principals’ knowledge-of-practice
• Vision of high-quality mathematics instruction
• (Suppositions about process of teacher learning)
Policy and Learning
• Policy
• Local, state, and national policies intentionally
designed to influence teachers’ classroom
practices
• Mathematics education
• Professional development and instructional
materials intentionally designed to influence
teachers’ classroom practices
Policy Research
• The outcomes of specific policies
• The process by which particular policies are
implemented
• No position on what high-quality instruction
looks like
Mathematics Education
• Students’ and teachers’ learning
• Classroom in an institutional vacuum
Learning Policy
• Formulate and refine policies by building on
research on learning and teaching
• Frame instructional improvement as a
problem of organizational learning for
schools and districts