## Strings for Addition.docx - Section 2: Investigation

*Strings for Addition.docx*

*Strings for Addition.docx*

# Adding and Subtracting in Scientific Notation

Lesson 2 of 22

## Objective: SWBAT add and subtract numbers in scientific notation

*55 minutes*

#### Start Up

*15 min*

The common approach to adding and subtracting numbers in scientific notation doesn't involve typical use of the laws of exponents, but it does tap into our place value system. I show students this possibility by sharing some quick examples in a string.

**Write each expression and its sum in decimal form and scientific notation:**

5000 + 500

5000 + 50

5000 + 5

3 x 10^3 + 3 x 10^2

3 x 10^3 + 3 x 10^1

3 x 10^3 + 3 x 10^0

1,500,000 + 20,000

2,250,000 + 4 x 10^5

2,250,000 + 4 x 10^6

2,250,000 + 8 x 10^5

The string start off with three reference examples. Its a reminder of the the beauty of our place value system and a chance to tap into the way we use that system to think about adding. The next three examples all start with 3000 and then add hundreds, tens, and ones (like the first three reference examples). Then, there is an expression adding two quantities in decimal form (1,500,000 + 20,000). This example is meant to give students another reference with larger numbers (something that many students continually struggle with). The last three examples combine decimal form and scientific notation. The goal is to constantly reflect on the process of adding these numbers in an easy way. That might mean that students *always* rewrite in decimal form and then convert to scientific notation, but it also might mean that they recognize how the place values connect to solve a problem.

For example, when I add 3 x 10^3 + 3 x 10^2, I recognize that 3 x 10^3 represents 3 thousands and that 3 x 10^2 represents 3 hundreds. Together they make 3 thousands and 3 hundreds, which is 3.3 x 10^3. Students can always keep the higher power of 10 (in this case 10^3) and then add the first terms in their appropriate place. With 3 x 10^3, we have 3 thousands and 0 hundreds. So when we add the 3 hundreds to this number, we get 3 thousands and 3 hundreds. Students also need to recognize that when you have a number like 3.3 x 10^3, that the first three represents thousands and then the 3 after the decimal represents hundreds. We play more with this idea in the investigation.

*expand content*

#### Investigation

*25 min*

Here I give students 4 strings to work with. Each string is not meant to be an endless series of repetitive exercises. Instead each expression is meant to help students make sense of a pattern in the process of adding and subtracting numbers in scientific notation.

As I circulate, I ask students to describe the patterns they see and remind them that even when patterns like this aren't listed, they could *create* simple expressions that help them solve tougher questions. That is the heart of the pedagogy behind strings. Its an opportunity to remind students that they can create simple problems to make sense of anything they have to solve.

Strings for Addition has all addition problems, but I ask them to turn some of them into subtraction for the summary.

#### Resources

*expand content*

#### Summary

*15 min*

I could talk about strings for *years* and not get tired. This is because every string seems to hold some fun element of number sense that I planted and also some fun element that students and I discover together.

The first string is critical for its exposure of **place value**, but hard to share in an effective way:

1.23 x 10^{6}

1.23 x 10^{5}

1.23 x 10^{4}

1.23 x 10^{3}

1.23 x 10^{2}

1.23 x 10^{1}

1.23 x 10^{0}

1.23 x 10^{-1}

The most ideal situation would be to share students work through the document camera. Some students will line up the numbers in a way that demonstrates the pattern in the string. If they set it up right, there is no need to write the names of place values over and over again. Instead, you can see the place value in the layout:

1.23 x 10^{6 = 1230000}

1.23 x 10^{5 = 123000}

1.23 x 10^{4 = 12300}

1.23 x 10^{3 = 1230}

1.23 x 10^{2 = 123.}

1.23 x 10^{1 = 12.3}

1.23 x 10^{0 = 1.23}

1.23 x 10^{-1 = .123}

The second string is meant to cover some **basic elements of the scientific notation** algorithm. Students understand that answers should be written in scientific notation, but I leave that instruction out (I want them to still break the numbers down to standard form if they want to).

32 + 4 x 10^{2}

32 + 4 x 10^{3}

32 + 4 x 10^{4}

32 + 4 x 10^{5}

32 + 4 x 10^{6}

3.2 x 10^{2} + 4 x 10^{2}

3.2 x 10^{3} + 4 x 10^{2}

3.2 x 10^{3} + 4 x 10^{3}

3.14 x 10^{4} + 6 x 10^{5}

This string starts by mixing standard and scientific notation, but keeps the number 32 constant throughout. This is meant to help students build confidence as they work. The final four problems add scientific notation only, but start by building off the same decimals in the number 32

The third string is meant to be a gentle introduction to **decimal addition**, something that is markedly more challenging for students.

4 x 10^{1} + 6 x 10^{1}

4 x 10^{1} + 6 x 10^{0}

4 x 10^{1} + 6 x 10^{-1}

4 x 10^{0} + 6 x 10^{-1}

4 x 10^{0} + 6 x 10^{-2}

4 x 10^{0} + 6 x 10^{-3}

4 x 10^{-1} + 6 x 10^{-3}

4 x 10^{-2} + 6 x 10^{-3}

4 x 10^{-3} + 6 x 10^{-3}

The goal is to start with two small whole numbers and then work slowly towards all decimal addition.

The fourth string is "advanced" only because it deals with larger numbers and larger gaps in place value.

4 x 10^{6} + 6 x 10^{9}

4 x 10^{7} + 6 x 10^{9}

4 x 10^{8} + 6 x 10^{9}

4 x 10^{9} + 6 x 10^{9}

4.1 x 10^{6} + 6.3 x 10^{9}

4 x 10^{60} + 6 x 10^{61}

4 x 10^{61} + 6 x 10^{61}

4 x 10^{64} + 6 x 10^{65}

In the process of sharing these strings, I want students to recognize how to "line up" numbers by place value and recognize when this is effective and when it could be confusing (when there are large gaps in place value, it might always make more sense to transfer everything into standard form).

As for an algorithm, I am careful not to simply share my approach in lining up place value.

I picture the numbers stacked on top of each other. So if I am adding 3 x 10^3 and 2 x 10^2, I think:

3,000

+ 200

3200 = 3.2 x 10^3

Students invariably think of similar strategies, but I will lose them with my strategy if I don't acknowledge their strategy first.

*expand content*

##### Similar Lessons

Environment: Urban

###### Irrational (and Other!) Numbers on the Number Line

*Favorites(40)*

*Resources(20)*

Environment: Urban

Environment: Suburban

- UNIT 1: Starting Right
- UNIT 2: Scale of the Universe: Making Sense of Numbers
- UNIT 3: Scale of the Universe: Fluency and Applications
- UNIT 4: Chrome in the Classroom
- UNIT 5: Lines, Angles, and Algebraic Reasoning
- UNIT 6: Math Exploratorium
- UNIT 7: A Year in Review
- UNIT 8: Linear Regression
- UNIT 9: Sets, Subsets and the Universe
- UNIT 10: Probability
- UNIT 11: Law and Order: Special Exponents Unit
- UNIT 12: Gimme the Base: More with Exponents
- UNIT 13: Statistical Spirals
- UNIT 14: Algebra Spirals

- LESSON 1: Units and Vast Systems of Measurement
- LESSON 2: Adding and Subtracting in Scientific Notation
- LESSON 3: Mad Libs and Math Libs
- LESSON 4: Yuck! Word Problems...
- LESSON 5: The World of Microns
- LESSON 6: 100 People: An Assessment
- LESSON 7: Khan Academy and Scientific Notation Intuition
- LESSON 8: Khan Academy and Scientific Notation Conversions
- LESSON 9: Khan Academy and Orders of Magnitude
- LESSON 10: Khan Academy and Multiplying and Dividing with Scientific Notation
- LESSON 11: Khan Academy and Computations in Scientific Notation
- LESSON 12: Khan Academy Patterns in Zeros
- LESSON 13: Delta Math and Scientific Notation
- LESSON 14: Video Quiz (Alternative Assessment)
- LESSON 15: How far is that?
- LESSON 16: Long Distance Relationships Project
- LESSON 17: Long Distance Relationship Follow Up
- LESSON 18: How big is that?
- LESSON 19: The Universcale (A Project)
- LESSON 20: Universcale Project Follow Up
- LESSON 21: The Digital Scientific Notation Worksheet
- LESSON 22: The Cost of the Death Star