2.4: Propose an Idea or Model

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Page ID: 31559

W. Sean Chamberlin, Nicki Shaw, and Martha Rich
Fullerton College via Blue Planet Publishing

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Collecting observations and forming questions naturally lead to consideration of possible answers. Humans relish in coming up with ideas about why something happened. Because of the way our brains work, we try to fit observations into mental frameworks of what we already know. These frameworks become conceptual models (introduced in Chapter 1), idealized representations of the world around us.

Conceptual models often take the form of illustrations, diagrams, and even animations. Descriptions and drawings of imaginary things like dragons, mermaids, and extraterrestrials represent someone’s conceptual model of these creatures. Ideas also take the form of illustrations or graphics, primarily as a means of refining those ideas and explaining them to others. In fact, most illustrations that you see in textbooks represent conceptual models. An illustration of the major ocean currents and a diagram of the interactions of species in an oceanic food web serve as examples of conceptual models of how a part of the ocean works.

Scientists, like everyone else, employ other kinds of models to help them understand and test hypotheses about the natural world. As a child, you likely played with toys. Toys are a kind of physical model, a scaled-down, three-dimensional, semirealistic representation of an object or part of nature. A Matchbox car is a physical model of a real car. A Cabbage Patch doll is a physical model of a human baby. Lincoln Logs represent real logs; Legos represent construction materials. These physical models allow kids to experience through pretend play what it’s like to drive a real car, care for a real baby, or build a house. They provide a sense of the excitement and, hopefully, the responsibilities involved with an actual car, baby, or house.

A third kind of model uses mathematics to formulate and test ideas. Mathematical models represent simple or complex expressions used to describe or simulate how something works. We usually think of them as quantitative—giving numerical results—but they may also be qualitative, helping scientists describe properties or relationships between variables (e.g., Dambacher et al. 2015). Mathematical models underpin the stock market, retirement planning, business development, economics, and a whole host of other human activities.

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