Key Features
The first edition of ''Core-Plus Mathematics'' was designed to meet the curriculum, teaching, and assessment standards from theFirst Edition (1994-2003)
The program originally comprised three courses, intended to be taught in grades 9 through 11. Later, authors added a fourth course intended for college-bound students.Second Edition (2008-2011)
The course was re-organized around interwoven strands of algebra and functions, geometry and trigonometry, statistics and probability, and discrete mathematics. Lesson structure was updated, and technology tools, including ''CPMP-Tools'' software was introduced.CCSS Edition (2015)
The course was aligned with theEvaluations, Research, and Reviews
Project and independent evaluations and many research studies have been conducted on ''Core-Plus Mathematics'', including content analyses, case studies, surveys, small- and large-scale comparison studies, research reviews, and a longitudinal study.Positive reviews
There are multiple research studies and evaluations in which students using ''Core-Plus Mathematics'' performed significantly better than comparison students on assessments of conceptual understanding, problem solving, and applications, and results were mixed for performance on assessments of by-hand calculation skills.Schoen, H. L., & Hirsch, C. R. (2003). The Core-Plus Mathematics Project: Perspectives and student achievement. In S. Senk & D. Thompson (Eds.), Standards-based school mathematics curricula: What are they? What do students learn? (pp. 311–344). Hillsdale, NJ: Lawrence Erlbaum Associates.Schoen, H. L., Hirsch, C. R., & Ziebarth, S. W. (1998). An emerging profile of the mathematical achievement of students in the Core-Plus Mathematics Project. Paper presented at the 1998 Annual Meeting of the American Educational Research Association. San Diego, CA. Some of these studies were funded by the National Science Foundation, the same organization that funded the development of ''Core-Plus Mathematics'' program.Large-scale comparison studies
A three-part study of ''Core-Plus Mathematics'' and more conventional curricula were reported by researchers at theOther comparison studies
A study conducted by Schoen and Hirsch, two authors of ''Core-Plus Mathematics'', reported that students using early versions of ''Core-Plus Mathematics'' did as well as or better than those in traditional single-subject curricula on all measures except paper-and-pencil algebra skills. A study on field-test versions of ''Core-Plus Mathematics'', supported by a grant from the National Science Foundation (Award MDR 9255257) and published in 2000 in the ''Reviews of instructional materials and programs
EdReports, an independent nonprofit, recently completed evidenced-based reviews of K-12 instructional materials. In their analysis of Core-Plus Mathematics Courses 1–3, the three-year core program was found to meet expectations for alignment to the high school Common Core State Standards for Mathematics in terms of content, focus, and coherence, and in terms of rigor and mathematical practices. The Core-Plus Mathematics instructional materials also met EdReports criteria that the materials are well designed and reflect effective lesson structure and pacing. In an in-depth analysis by The Center for Research on Reform in Education at Johns Hopkins University, Core-Plus Mathematics was given a "moderate" evidence rating, and is the only comprehensive three-year high school mathematics program to be rated at any level (strong, moderate, or promising) for meeting federal ESSA Standards for Evidence in terms of promoting student achievement.Other research studies
In terms of core content development, a study comparing the development of quadratic equations in the Korean national curriculum and ''Core-Plus Mathematics'' found that some quadratic equation topics are developed earlier in Korean textbooks, while ''Core-Plus Mathematics'' includes more problems requiring explanations, various representations, and higher cognitive demand. Several studies have analyzed the teacher's role in ''Core-Plus Mathematics''.Negative reviews
In November 1999, David Klein, professor of mathematics at California State University, Northridge, sent an open letter to the U.S. Department of Education, in response to the U.S. Department of Education Expert Panel in Mathematics and Science designation of ''Core-Plus Mathematics'' as "exemplary." Klein's open letter urged the Department of Education to withdraw its recommendations of the severalAndover High School Survey
One of the first schools to pilot Core-Plus was Andover High School inA study of Core-Plus students attending Michigan State University
In 2006, Richard O. Hill and Thomas H. Parker from Michigan State University (MSU) evaluated the effectiveness of the Core-Plus Mathematics Project in preparing the students for subsequent university mathematics. R. Hill and T. Parker analyzed the college mathematics records of students arriving at MSU from four high schools that implemented the Core-Plus Mathematics program between 1996 and 1999. They found a "disconnect" between the mathematics expectations that students encounter in K-12 education and those that they encounter in college. The effectiveness of Core-Plus and the other NSF-funded high school curricula programs became a significant issue for college mathematics faculty. Core-Plus students placed into, and enrolled in, increasingly lower-level courses. The percentages of students who eventually passed a technical calculus course showed a statistically significant decline averaging 27 percent a year; this trend was accompanied by an obvious and statistically significant increase in percentages of students who placed into low-level and remedial algebra courses. Except for some top students, graduates of Core-Plus mathematics were struggling in college mathematics, earning below average grades. They were less well prepared than either graduates in the Control group (who came from a broad mix of curricula) or graduates of their own high schools before the implementation of Core-Plus mathematics.Review by Prof. Harel
In 2009 professor of mathematics at the University of California in San Diego, Guershon Harel reviewed four high-school mathematics programs. The examined programs included Core-Plus Courses 1, 2, and 3. The examination focused on two topics in algebra and one topic in geometry, deemed by Prof. Harel central to the high school curriculum. The examination was intended "to ensure these topics are coherently developed, completely covered, mathematically correct, and provide students a solid foundation for further study in mathematics". From the outset, Prof. Harel noted that the content presentation in Core-Plus program is unusual in that its instructional units, from the start to the end, are made of word problems involving "real-life" situations. This structure is reflected in the subtitle of the Core-Plus series: ''Contemporary Mathematics in Context''. To review the program, it was necessary to go through all the problems in the core units and their corresponding materials in the Teacher's Edition. Despite the unconventional textbook structure, the language used by the Core-Plus program was found mathematically sound. In the algebra section, fundamental theorems on linear functions and quadratic functions were found not justified, except for the quadratic formula. Theorems are often presented without proof. Like in the algebra texts, the geometry text does not lead to a clear logical structure of the material taught. Because theoretical material is concealed within the text of the problems, "a teacher must identify all the critical problems and know in advance the intended structure to establish the essential mathematical progression. This task is further complicated by the fact that many critical problems appear in the homework sections. Important theorems in geometry are not justified. Moreover, with the way the material is sequenced, some of these theorems cannot be justified". According to Prof. Harel, the Core-Plus program "excels in providing ample experience in solving application problems and in ensuring that students understand the meanings of the different parts of the modeling functions. The program also excels in its mission to contextualize the mathematics taught". However, it fails "to convey critical mathematical concepts and ideas that should and can be within reach for high school students".Review by Prof. Wilson
Professor W. Stephen Wilson from Johns Hopkins University evaluated the mathematical development and coherence of the Core-Plus program in 2009. In particular, he examined "the algebraic concepts and skills associated with linear functions because they are a critical foundation for the further study of algebra", and evaluated how the program presents the theorem that the sum of the angles of a triangle is 180 degrees, "which is a fundamental theorem of Euclidean geometry and it connects many of the basics in geometry to each other". Prof. Wilson noted that the major theme of the algebra portion of the program seems to involve creating a table from data, graphing the points from the table; given the table students are asked to find a corresponding function. In case of linear function, "at no point is there an attempt to show that the equation's graph really is a line. Likewise, there is never an attempt to show that a line graph comes from the usual form of a linear equation". Prof. Wilson considered this approach to be "a significant flaw in the mathematical foundation". Quoting the textbook, "Linear functions relating two variables x and y can be represented using tables, graphs, symbolic rules, or verbal descriptions", Prof. Wilson laments that although this statement is true, "the essence of algebra involves abstraction using symbols". Prof. Wilson says that the Core-Plus program "has a multitude of good problems, but never develops the core of the mathematics of linear functions. The problems are set in contexts and mathematics itself is rarely considered as a legitimate enterprise to investigate". The program lacks attention to algebraic manipulation" to the point that "symbolic algebra is minimized". In regards to geometry portion, Prof. Wilson concludes that the program fails to build geometry up from foundations in a mathematically sound and coherent way". He stresses out that "one significant goal of a geometry course is to teach logic, and this program fails on that account". Overall, the "unacceptable nature of geometry" and the fashion in which the program downplays "algebraic structure and skills" make the Core-Plus program unacceptable.Historical Controversy
Mathematics programs initially developed in the 1990s that were based on the NCTM's Curriculum and Evaluation Standards for School Mathematics, like ''Core-Plus Mathematics'', have been the subject of controversy due to their differences from more conventional mathematics programs. In the case of ''Core-Plus Mathematics'', there has been debate about (a) the international-like integrated nature of the curriculum, whereby each year students learn algebra, geometry, statistics, probability, and discrete mathematical modeling, as opposed to conventional U.S. curricula in which just a single subject is studied each year, (b) a concern that students may not adequately develop conventional algebraic skills, (c) a concern that students may not be adequately prepared for college, and (d) a mode of instruction that relies less on teacher lecture and demonstration and more on inquiry, problem solving in contextualized settings, and collaborative work by students. For example, this debate led to some schools in Minnesota abandoning ''Core-Plus Mathematics'' in the early 2000s and returning to traditional mathematics curricula. In a master's degree research paper at the time, interviews with teachers at four schools that had dropped ''Core-Plus Mathematics'' suggested that many teachers "did not feel that Core-Plus emphasized mastering skills enough", while parents "felt that it did not prepare students for college" and some parents commented that the text was difficult to read. The author of the paper made suggestions for successful adoption of any new materials, including "don't rush the adoption process," have "continued professional development for all," and "school districts need to be proactive regarding parent questions."References
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