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Measurement: Developmental Research and Theory

Generating operational questions. Measurement comprises a set of understandings and skills that form a foundation for essential learning, especially in science and mathematics. These understandings and skills routinely come into play in everyday life and as preparation for further investigation of other topics—fractions, proportion, area and volume, and density to name a few. The importance of measurement is underscored by the array of math science standards for which it forms the basic underpinning. This is discussed at length as both narrative and cited examples in national and state mathematics and science education standards documents.

Measurement Understandings, Skills, and Conceptual Growth

Most of what we know regarding measurement—especially linear measurement, the most basic building block of conceptual understanding of measurement—is based either directly or indirectly on studies by Piaget and his colleagues. As of publication of NCTM's Principles and Standards for School Mathematics (NCTM, 2000), Piaget's definition of measurement as the synthesis of subdivision (i.e., understanding that space or an object's length can be "partitioned") and change of position (i.e., being able to partition a unit from an object and iterate that unit without gaps or overlaps) (Piaget & Inhelder, 1956; Piaget et al., 1960) remains intact. The term "synthesis" has special meaning, as it refers to the ability to coordinate understanding and application of the two and to furthermore do so with insight—not randomly, or by trial and error, or even as an act of accurate measurement when done only by formalized steps devoid of meaning and interpretation. The importance of this notion is further supported by the Principles and Standards for School Mathematics. The concepts of inclusion and conservation of length are implicit in this view of measurement—they form as well the most sound developmental continua of which we are aware, as both have been found to grow as a child learns to measure (Inhelder, Sinclair, & Bovet, 1974). The question of the influence of one on the other, and by default the order in which each is realized, is a matter of debate. Of significance, however, is that the close correlation of the concepts of inclusion and conservation of length with the act of measuring has resulted in our ability to categorize children's development of measurement concepts into several stages (Piaget et al., 1960; Carpenter, 1976; Copeland, 1974; and Sinclair, 1970). The following illustrates the distinctions between stages based on their progress in their understanding and ability to appropriately apply these concepts.

Early Stage (younger than 6 years old) - The child cannot conserve length, but rather relies only on visual perception. At this stage, the child does not understand length as a fixed attribute of an object. For example, when two objects of equal length are placed beside each other, with their endpoints aligned, the child may recognize that they are of the same length, but when one or both of the objects are moved so that the endpoints do not align, the child will no longer recognize their equality. Likewise, the child cannot reason transitively—he/she is not able to use a third object of a certain length (e.g., stick, ruler, yardstick, or even his/her own body) to compare the lengths of two other objects. In the child's mind, once the third object is moved, it changes length. As with the notion of length, understanding of "space" also eludes the child at the early stage—he/she does not perceive objects with well-defined spatial relations as fixed attributes. The child therefore cannot exhibit reversibility. For example, the child will not recognize that the distance (the empty space between two objects) from fixed point A to fixed point B is the same as the distance from point B to A.

Transitional Stage (ages 6-8) - The child can conserve length. The child typically begins at ages 6-7 to exhibit the ability to reason transitively by using his/her own body as the third object—the referent—to compare the lengths of two other objects. With increased understanding of length as a fixed attribute of an object, the child at ages 7-8 exhibits understanding that an object can be partitioned (subdivision), the whole is the sum of its parts, and that a fixed unit (other objects or a ruler, for example) of length can be iterated along the length of an object—or over a distance—without gaps or overlaps, in either direction (reversibility), and that the "change of position" does not change the length of the referent.

Operational Stage (ages 8-10) - The child understands the concept of inclusion—when iterating a unit across a distance or length, the distance covered by the first unit is nested in the distance covered by two units, and so on. The child synthesizes and coordinates understanding and application of both subdivision and change of location, and does so with insight. Children with this ability can typically compare relative distances and express one distance in terms of the other (e.g., length A is half as long as length B, and so forth), coordinate units of different lengths in unique spatial environments, and recognize accumulation of distance (e.g., quantitative measurements represent a series of nested distances).

 

Carpenter, T. (1976). Analysis and synthesis on existing research on measurement. In R. Lesh & D. Bradford (Eds.), Number and measurement. [Papers from a research workshop]. (ERIC Document Reproduction Service No. ED 120027)

Copeland, R. (1974). How children learn mathematics: Teaching implications of Piaget's research (2nd ed.). New York: Macmillan.

Inhelder, B., Sinclair, H., & Bovet, M. (1974). Learning and the development of cognition. Cambridge, MA: Harvard University Press.

Piaget, J., & Inhelder, B. (1956). The child's conception of space. London: Routledge & Kegan Paul.

Piaget, J., Inhelder, B., & Szeminska, A. (1960). The child's conception of geometry. New York: Basic Books.

National Council of Teachers of Mathematics (2000). Principles and standards for school mathematics. Reston, VA: National Council of Teachers of Mathematics.

Sinclair, H. (1970). Number and Measurement. In M. Rosskopf, L. Steffe, & S. Taback (Eds.), Piagetian cognitive-development research and mathematical education (pp. 135-149). Washington, DC: National Council of Teachers of Mathematics.

 

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If you teach or have colleagues who work with preschoolers, go to the PreKorner™ homepage to browse similar resources. You may be particularly interested in the early childhood numeracy resources.


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