Grades 6 - 8: Connections

Connections Standard for Grades 6–8

Instructional programs from prekindergarten through grade 12 should enable all students to—

recognize and use connections among mathematical ideas;
understand how mathematical ideas interconnect and build on one another to produce a coherent whole;
recognize and apply mathematics in contexts outside of mathematics.

Thinking mathematically involves looking for connections, and making connections builds mathematical understanding. Without connections, students must learn and remember too many isolated concepts and skills. With connections, they can build new understandings on previous knowledge. The important mathematical foci in the middle grades—rational numbers, proportionality, and linear relationships—are all intimately connected, so as middle-grades students encounter diverse new mathematical content, they have many opportunities to use and make connections.

This chapter on grades 6–8 mathematics contains numerous illustrations of mathematical connections. Many of the formulas students develop and use in the "Measurement" section draw on their knowledge of algebra, geometry, and measurement. The kite example in the "Geometry" section engages students in examining the perimeter and area of similar figures to investigate proportional relationships. Several examples in the "Data Analysis" section illustrate how gathering, representing, and analyzing data can help students develop insights into other mathematical ideas, including variation and change, probability, and ratio and proportion. The "cellular telephone" problem in the "Algebra" section demonstrates how connections among various forms of representation provide insights into patterns and regularities in problem situations. Clearly, rich problem contexts involve connections to other disciplines (e.g., science, social studies, art) as well as to the real world and to the daily life experiences of middle-grades students.

What should connections look like in grades 6 through 8?

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Mathematics classes in the middle grades should continually provide opportunities for students to experience mathematics as a coherent whole through the curriculum used and the questions teachers and classmates ask. Students reveal the ways they are connecting ideas when they answer questions such as, What made you think of that? Why does that make sense? Where have we seen a problem like this before? How are these ideas related? Did anyone think about this in a different way? How does today's work relate to what we have done in earlier units of study? From these discussions, students can develop new connections and enhance their own understanding of mathematics by listening to » their classmates' thinking.

If curriculum and instruction focus on mathematics as a discipline of connected ideas, students learn to expect mathematical ideas to be related. Rich mathematical tasks prompt students to use and develop mathematical understandings and connections. Challenging problems encourage students to think about how familiar concepts and procedures can be applied in new situations. In classrooms where students are expected to reason mathematically and to communicate clearly about significant mathematical tasks, new ideas surface quite naturally as extensions of previously learned mathematics. With prompting from their teacher, students routinely ask themselves, "How is this problem like what I have done before? How is it different?"

Consider an expanded version of a summary (adapted from NCTM, Algebra Working Group [1998, p. 155]) of a lesson on ratio and proportion. The intent of this lesson was to begin developing students' understanding of methods for comparing ratios. The students had not previously been taught such methods, so the teacher wanted to uncover whether and how students could apply what they had already learned about number and ratio. The lesson was centered on the following task, which was adapted from Lappan et al. (1998, p. 27):

Southwestern Middle School Band is hosting a concert. The seventh-grade class is in charge of refreshments. One of the items to be served is punch. The school cook has given the students four different recipes calling for sparkling water and cranberry juice.

Which recipe will make punch that has the strongest cranberry flavor? Explain your answer.
Which recipe will make punch that has the weakest cranberry flavor? Explain your answer.
The band director says that 120 cups of punch are needed. For each recipe, how many cups of cranberry juice and how many cups of sparkling water are needed? Explain your answer.

The students worked on the first two questions in groups of two or three. When the groups had finished, they came together as a whole class to share and explain their answers.

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The groups had attempted to figure out which recipe has the strongest cranberry flavor in different ways. Some examined the part-whole relationships of the number of cups of juice to the total number of cups in the recipe (these ratios are 2/5, 4/12, 3/8, 1/5 for recipes A–D, respectively). Others looked at the part-part ratios of juice to water (2/3, 4/8, 3/5, 1/4). Still others, failing to consider that the recipes, as given, make different amounts of punch, incorrectly » considered only the number of cups of juice in each recipe (2, 4, 3, 1). After questioning and challenging one another's solutions and comparing methods, the class decided to move on to the last question to see if they could resolve the differences in their answers. Each group was assigned to determine the amounts of juice and water needed for just one of the recipes. Below are four of the strategies the groups used to work through this part of the problem.

Group with recipe A

We figured out that each recipe would make 5 cups: 2 of juice and 3 of water. So to make 120 cups, it would take 120 divided by 5, and that is 24, the number of recipes needed. Since we need 2 cups of juice and 3 cups of water for one recipe, we need 224 = 48 cups of juice and 324 = 72 cups of water for the 24 recipes. And since 48 cups of juice + 72 cups of water makes 120 cups of punch that must be right.

Group with recipe B

We thought that 4 cups of juice and 8 cups of water is the same ratio as 1 cup of juice and 2 cups of water. We then thought about the 120 cups of punch as divided into three groups of 40 cups each: 40 + 40 + 40 = 120. We need 1 part juice, so that is 40 cups, and 2 parts water, so that is 80 cups. This makes 120 cups of punch, and you still have a ratio of 1 part juice to 2 parts water.

Group with recipe C

We tried to double the recipe, but that was not enough. So we added another batch and that still was not enough. So we just kept adding recipes and seeing how many total cups of punch we had. We kept up this pattern until we got 120 cups. So we had [a table like that shown in fig. 6.38]. That means we had 45 cups of juice and 75 cups of water.

Fig. 6.38. Chart for punch recipes.

Later in the class discussion, this group noticed that they could have gone directly from 3/5 to 45/75 by multiplying the numerator and denominator by 15 because they needed 15 recipes.

Group with recipe D

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We tried various numbers. First we tried 20 cups of juice. This means we needed 4 times as much water or 80 cups of water. But this was too small because 20 + 80 is only 100. So we tried 30 cups of juice, so that meant 304 = 120 cups of water. This time we had too much punch, 30 + 120 = 150. Next we tried 25 cups of » juice. And 254 = 100, so we had 100 cups of water. But this made 125 cups of punch, which was close but too much. So we tried 24 cups of juice, which needed 244 = 96 cups of water. This worked because 24 + 96 = 120 cups of punch.

After the groups had shared their approaches to the third question, the teacher continued the conversation by encouraging the class to talk about the similarities and differences among the strategies.

The "making punch" problem had brought numerous mathematical ideas to the forefront: fractions, ratios, proportions, operations, magnitude, scaling, number sense, patterns, and so on. By bringing previously understood mathematical ideas or processes to bear on this problem, the students were developing understandings that laid a foundation for the later study of such topics as rates of change and linear relationships.

Since the task required the students to explain their strategies, all the students had an opportunity to enhance their understanding of ratios by listening to the others' different ideas. For example, the group with recipe D used a "guess and check" approach to solve the problem. The group with recipe C made a table and used the ideas of scaling ratios and adding iteratively in the same way that students find equivalent fractions. The groups with recipes A and B thought about comparing quantities and using ratios.

None of the students mentioned that the answers to the first two questions would have been more obvious if they had solved the third problem first. For each recipe, we can add the number of cups of cranberry juice to the number of cups of water to determine how much punch one recipe makes. We divide this number into 120 to determine the multiples—24, 10, 15, and 24, respectively—of the ingredients that are needed. Because recipes A–D use 2, 4, 3, and 1 cup of cranberry juice initially, they will use 48, 40, 45, and 24 cups of cranberry juice, respectively, when multiplied to serve 120 people. Clearly, recipe D has the weakest cranberry flavor and recipe A has the strongest. This finding confirms the students' previous answers and approaches.

What should be the teacher's role in developing connections in grades 6 through 8?

The teacher's role includes selecting problems that connect mathematical ideas within topics and across the curriculum; it also includes helping students build on their current mathematical ideas to develop new ideas. The teacher's orchestration of the "making punch" lesson allowed the students to make the connections explicit and to focus on the relationships and commonalities among their strategies. The teacher took advantage of an opportunity to foster the students' disposition to look for connections as well as to use connections. In situations like this, it is essential that the teacher recognize and understand the mathematical concepts being developed, not just to teach the abstract manipulation but also to orchestrate the conversation. The teacher needs to be able to make quick decisions about next steps. It is also important to encourage students to use words and notation appropriately to support their understanding of new concepts, such as proportionality and algebra.

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It is sometimes quite effective to revisit a problem to help students connect familiar ideas to new concepts or skills. Indeed, the "making punch" problem has potential for connections to proportionality and linearity. For instance, students could make a graph, plotting values » from the first and third rows of the table in figure 6.38. These points lie on a line. If y represents the total number of cups of punch and x the number of cups of juice, then the line has equation y = (8/3)x (see fig. 6.39). To answer question 3—which asks how much juice and how much water are needed for 120 cups of punch—students can substitute 120 for y in this equation and compute x to find the number of cups of juice. They would subtract this number from 120 to find the amount of sparkling water needed. This equation works equally well for finding how much juice is needed for any other quantity of punch, so they see the power of expressing a relationship in general terms. Here the slope of the line is the ratio of the amount of punch to the amount of juice. Of course, having used this method to answer question 3 for all recipes, students can easily answer the other two questions. A teacher might also revisit the "making punch" problem to assess students' understanding of tabular, graphical, and symbolic representations for linear relationships.

Fig. 6.39. A graph of the numbers of cups of juice and punch reveals a linear relationship.

Teachers can also enhance students' understanding of mathematics by using other disciplines as sources of problems. Science and social studies are rich in opportunities to learn about measurement, data, and algebra; art and computer graphics can be used to make sense of shape, symmetry, similarity, and transformations of geometric figures. Environmental studies offers a context for the study of large numbers (analyzing population growth), measurement (finding the percent of different types of trash in landfills by volume and considering recycling alternatives), or data and statistics (studying the effects of pollution on animal and plant populations).

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In many schools, teachers are interested in fostering interdisciplinary studies. The mathematics teacher may work with teachers of other subjects to develop integrated units of study. For example, middle-grades science classes might study populations of wildlife such as deer, fish, eagles, or sharks (see Curcio and Bezuk [1994]). If students will be expected to use sampling techniques in science class to determine the population of a species, it is important that the mathematics and science teachers discuss students' understanding of different sampling techniques and of the idea of randomness. It is also important that science teachers understand that students are likely to use scaling and equivalent ratios to estimate the total population » rather than cross multiplication and formal algebraic symbol manipulation to find their solutions.

In the same spirit, mathematics teachers can build on and connect to disciplines other than science and social studies. For example, language arts teachers can describe the strategies they teach for writing convincing arguments. The mathematics teachers may then be able to help students use the strategies when appropriate in formulating mathematical arguments. They may also be better able to help students recognize and analyze forms of argumentation and justification that are peculiar to mathematics. Again, students benefit from teachers' efforts to understand how other subjects are taught and to make connections between the subjects explicit.

Conversations about students' experiences, understandings, and familiarity with procedures give teachers of other subjects an opportunity to learn about elements of the mathematics curriculum, such as algorithms and the level of abstract symbol manipulation that students might use. Without such conversations, those who are not mathematics teachers may expect students to understand and use procedures that are not part of their repertoire or teachers may fail to build on ideas with which students are already conversant. Students may miss an opportunity to apply and extend their reasoning skills or to see that mathematical ideas can be used in other disciplines. This is not to imply that merely applying mathematics in science, social studies, or any other discipline constitutes a sufficient middle-grades mathematics curriculum. The point is that interdisciplinary experiences serve as ways to revisit mathematical ideas and they help students see the usefulness of mathematics both in school and at home. If all the middle-grades teachers in a school do their best to connect content areas, mathematics and other disciplines will be seen as permeating life and not as just existing in isolation.

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