Early Algebra

Early Algebra is an approach to early mathematics teaching and learning. It is about teaching traditional topics in more profound ways.[1] It is also an area of research in mathematics education.

Traditionally, algebra instruction has been postponed until adolescence. However, data of early algebra researchers shows ways to teach algebraic thinking much earlier. The National Council of Teachers of Mathematics (NCTM) integrates algebra into its Principles and Standards starting from Kindergarten.

One of the major goals of early algebra is generalizing number and set ideas. It moves from particular numbers to patterns in numbers. This includes generalizing arithmetic operations as functions, as well as engaging children in noticing and beginning to formalize properties of numbers and operations such as the commutative property, identities, and inverses.

Students historically have had a very difficult time adjusting to algebra for a number of reasons. Researchers[2] have found that by working with students on such ideas as developing rules for the use of letters to stand in for numbers and the true meaning of the equals symbol (it is a balance point, and does not mean "put the answer next"), children are much better prepared for formal algebra instruction.

Teacher professional development in this area consists of presenting common student misconceptions and then developing lessons to move students out of faulty ways of thinking and into correct generalizations. The use of true, false, and open number sentences can go a long way toward getting students thinking about the properties of number and operations and the meaning of the equals sign.

Research areas in early algebra include use of representations, such as symbols, graphs and tables; cognitive development of students; viewing arithmetic as a part of algebraic conceptual fields [3]

Notes

  1. https://as.tufts.edu/education/earlyAlgebra/default.asp TERC
  2. Carpenter, T.P., Franke, M.L., and Levi, L. Thinking Mathematically. (Heinemann, 2003).
  3. Vergnaud, G. Long terme et court terme dans l’apprentissage de l’algebre. In C. Laborde (Ed.), Actes du premier colloque franco-allemand de didactique des mathematiques et de l’informatique (pp. 189–199). (La Pensée Sauvage, 1988).
gollark: I mean, either works, but I was thinking an on-FPGA interpreter.
gollark: Yes, that.
gollark: Well, first, you sacrifice your soul to Ba'hawejodfp, god of hardware design languages and books over 700 pages (gods nowadays have to take on multiple jobs to remain relevant).
gollark: Low-end FPGAs aren't *that* expensive nowadays, are they?
gollark: Why not a Brain[REDACTED] FPGA?

References

  • Blanton, M. L. Algebra and the Elementary Classroom: Transforming Thinking, Transforming Practice. (Heinemann, 2008).
  • J. Kaput, D. Carraher, & M. Blanton (Eds.), Algebra in the Early Grades. (Lawrence Erlbaum and Associates, 2007).
  • Schliemann, A.D., Carraher, D.W., & Brizuela, B. Bringing Out the Algebraic Character of Arithmetic: From Children's Ideas to Classroom Practice. (Lawrence Erlbaum Associates, 2007).
  • Carraher, D., Schliemann, A.D., Brizuela, B., & Earnest, D. (2006). Arithmetic and Algebra in early Mathematics Education. Journal for Research in Mathematics Education, Vol 37.
  • National Council of Teachers of Mathematics. Principles and Standards for School Mathematics. (Author, 2000)
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.