Date: Dec. 17, 2013

FOR IMMEDIATE RELEASE:

New System of Assessments Needed When Next Generation Science Standards Are Implemented, Report Says

WASHINGTON – New types of assessments will be needed to measure student learning once the Next Generation Science Standards (NGSS) are implemented, says a new report from the National Research Council. The tests that states currently use emphasize factual knowledge and were not designed to assess the type of understanding envisioned by the standards, which emphasize depth of knowledge based on the ability to integrate core content with science and engineering practices.

The report describes a new system of assessments that should be developed, and it offers examples of the types of tasks and questions that could assess student knowledge as detailed in the standards. To monitor progress in meeting the standards, states should use information both from state-administered tests and from classroom-based assessments, as well as information about students’ opportunity to learn in the ways laid out in the science standards, said the committee that wrote the report.

“The Next Generation Science Standards present challenges for assessment, but they are also an opportunity to address longstanding limitations with current approaches,” said committee co-chair James Pellegrino, Liberal Arts and Sciences Distinguished Professor and Distinguished Professor of Education at the University of Illinois at Chicago. “Current assessments tend to ask students to define the scientific method absent specific content; assessments under NGSS should ask students to demonstrate that they understand aspects of scientific reasoning by applying particular science practices, such as designing a study or interpreting the meaning of a data set, to questions about genetic inheritance, for example.”

The Next Generation Science Standards, which have been adopted by eight states so far, describe “performance expectations” that articulate what students should know and be able to do at each grade level. The standards support science learning structured around three dimensions: scientific and engineering practices; core ideas of the science and engineering disciplines; and crosscutting concepts, such as “cause and effect” and “energy and matter.” In classroom teaching and learning, these three dimensions should be integrated: for example, the students should always learn by engaging in one or more scientific practices in the context of core ideas, and their advancement should be mapped out in terms of a learning progression.

To assess students’ mastery and integration of these three dimensions, a variety of question formats will be needed, the report says. Questions may require students to supply an answer, produce a product, or perform an activity. “Formative” assessments would help teachers see how students are progressing and make instructional decisions; and “monitoring assessments” would measure science learning on a broader scale.

For the monitoring tests, the full breadth and depth of NGSS expectations for a given grade level cannot be covered with a single large-scale test, the report says. The committee recommended that the information from external “on-demand” assessments (that is, assessments that are administered at a time mandated by the state) should be supplemented with information gathered from classroom-embedded assessments (that is, assessments that are administered at a time determined by the district or school that fits the instructional sequence in the classroom) to fully assess whether performance expectations have been met.

These classroom-embedded assessments could take various forms. For example, they might be self-contained curricular units that include both instructional materials and assessments, provided by the state or district to be administered in classrooms. Or the state or district could develop banks of tasks that schools and teachers would use at the appropriate time in classrooms.

Assessments should be developed using a “bottom up” rather than a “top down” approach, the report says. The learning progression should begin with designing instruction and assessments for the classroom, perhaps integrated into instructional units, and then move toward assessment that meets the needs for monitoring purposes, including accountability.

In addition to using assessments to monitor students’ progress, states should monitor indicators of "opportunity to learn" – the extent to which students have the opportunity to learn science in the way called for in the standards and the extent to which schools have the resources they need to support learning (e.g., teacher subject-area knowledge, adequate time, and appropriate materials to devote to science instruction).

“It will take time to implement the new system of assessments, just as it will take time to implement the teaching approaches needed for students to learn science in the way NGSS envisions,” said committee co-chair Mark Wilson, professor of policy, organization, measurement, and evaluation and of cognition and development in the Graduate School of Education at the University of California, Berkeley. “States should develop and implement the new assessments gradually, starting with what is necessary and possible in the short term while establishing long-term goals for reaching a fully integrated system of curriculum, instruction, and assessment.”

In 2011 the National Research Council released A Framework for K-12 Science Education: Practices, Crosscutting Concepts, and Core Ideas, which served as the foundation for the Next Generation Science Standards.

The study was sponsored by the Bechtel Corp., Carnegie Corporation of New York, and the William and Flora Hewlett Foundation. The National Academy of Sciences, National Academy of Engineering, Institute of Medicine, and National Research Council make up the National Academies. They are private, independent nonprofit institutions that provide science, technology, and health policy advice under a congressional charter granted to NAS in 1863. The Research Council is the principal operating agency of the National Academy of Sciences and the National Academy of Engineering. For more information, visit http://national-academies.org. A committee roster follows.

Contacts:

Molly Galvin, Senior Media Relations Officer

Rachel Brody, Media Relations Associate

Office of News and Public Information

202-334-2138; e-mail news@nas.edu

http://national-academies.com/newsroom

Twitter: @NAS_news and @NASciences

RSS feed: http://www.nationalacademies.org/rss/index.html

Flickr: http://www.flickr.com/photos/nationalacademyofsciences/sets

Additional resources:

Full Report

Report in brief

Copies of Developing Assessments for the Next Generation Science Standards are available from the National Academies Press on the Internet at http://www.nap.edu or by calling tel. 202-334-3313 or 1-800-624-6242. Reporters may obtain a copy from the Office of News and Public Information (contacts listed above).

# # #

NATIONAL RESEARCH COUNCIL

Division of Behavioral and Social Sciences and Education

Board on Testing and Assessment

Board on Science Education

Committee on Developing Assessments of Science Proficiency in K-12

James W. Pellegrino (co-chair)

Distinguished Professor

Learning Science Research Institute

University of Illinois

Chicago

Mark R. Wilson (co-chair)

Professor

Graduate School of Education

University of California

Berkeley

Richard M. Amasino*

Howard Hughes Medical Institute Professor

Department of Biochemistry

University of Wisconsin

Madison

Edward Haertel

Jacks Family Professor of Education, Emeritus

Graduate School of Education

Stanford University

Stanford, Calif.

Joan Herman

Director, Emeritus

National Center for Research on Evaluation, Standards, and Student Testing

University of California

Los Angeles

Richard Lehrer

Professor

Department of Teaching and Learning

Peabody College

Vanderbilt University

Nashville, Tenn.

Scott F. Marion

Vice President

National Center for the Improvement of Educational Assessment

Dover, N.H.

Peter McLaren

Science and Technology Specialist

Elementary and Secondary Education

Rhode Island Department of Education

Providence

Knut Neumann

Professor for Physics Education

Leibniz Institute for Science and Mathematics Education

University of Kiel

Germany

William Penuel

Professor of Education

School of Education

University of Colorado

Boulder

Helen R. Quinn*

Professor Emerita

Particle Physics and Astrophysics

SLAC National Accelerator Laboratory

Stanford University

Stanford, Calif.

Brian Reiser

Professor of Learning Sciences

School of Education and Social Policy

Northwestern University

Evanston, Ill.

Kathleen Scalise

Associate Professor

Educational Methodology, Policy, and Leadership

University of Oregon

Eugene

Jerome M. Shaw

Associate Professor

Education Department

University of California

Santa Cruz

Nancy Butler Songer

Professor

School of Education

University of Michigan

Ann Arbor

Roberta Tanner

Retired Physics Teacher

Thompson School District

Loveland, Colo.

Catherine J. Welch

Professor

Department of Psychological and Quantitative Foundations,

Educational Measurements and Statistics

University of Iowa

Iowa City

STAFF

Judith A. Koenig

Study Director

___________________________________­­______

* Member, National Academy of Sciences