Categories: All - division - decimals - multiplication - place

by Tegan Derscheid 1 year ago

163

K-8 Mathematics

Understanding how to multiply and divide decimals is crucial in foundational mathematics. When multiplying decimals, align the numbers and multiply as if they were whole numbers, then place the decimal in the product.

K-8 Mathematics

K-8 Mathematics

Week Fifteen

EXAM 3

Week Thirteen

Practice Problems 2

a) 11% of 45 is what number?


0.11 * 45 = 4.95


Multiply the decimal and the whole number together and then add.



b) 9% of what number is 17


0.09 * n = 17

–––– ––––

0.09 0.09


n = 188.8 <–– Repeating decimal / 189


Divide both sides by the decimal.



c) 17% is what % of 25


17/25 = 0.68

|

V

68%

Divide the percentage by the whole number.

Week Eleven

EXAM 2

Week Nine

Multiplying and Dividing Fractions

Multiplication (Part of a Part):


1/2 of 1/2


1/2 x 1/2 = 1/4


1/2 x 1/4 = 1/8


1/3 x 1/8 = 1/24


Division:


2/3 ÷ 4/5 =


(Keep –> Change –> Flip)


2/3 x 5/4 = 10/12 = 5/6



2/3 ÷ 4/5 =


2/3 / 4/5 = 2/3 x 5/4 / 4/5 x 5/4

V V

10/12 20/20 = 1


10/12 / 1 = 10/12 = 5/6

Adding and Subtracting Fractions

Addition:


1/4 + 2/4 = 3/4


3/12 + 2/12 = 5/12


Subtraction:


5/8 - 4/8 = 1/8


8/9 - 2/9 = 6/9 = 2/3


Improper Fractions:


5/6 + 2/3 =

V V

5/6 + 4/6 = 9/6 = 1 3/6 –> 1 1/2 (Mixed Number)



6/10 - 2/5 =

V V

6/10 - 4/10 = 2/10 = 1/5

Week Seven

Prime Factor Trees

Prime Factor Trees


24

/ \

6 4

/ \ / \

3 2 2 2


2 * 2 * 2 * 3 = 24


48

/ \

12 4

/ \ / \

6 2 2 2

/ \

2 3


2 * 2 * 2 * 2 * 3 = 48


GCF and LCM

GCF: Greatest Common Factor


GCF (24, 36):


1. List Method:


24: 1, 2, 3, 4, 6, 8, 12, 24

36: 1, 2, 3, 4, 6, 9, 12, 18, 36


GCF (24, 36) = 12


2. Prime Factorization Method:


*USE TREE*


24: 2 * 2 * 2 * 3

36: 2 * 2 * 3 * 3


GCF (24, 36) = 2 * 2 * 3 = 12


24

/ \

6 4

/ \ / \

3 2 2 2


2 * 2 * 2 * 3 = 24


36

/ \

6 6

/ \ / \

3 2 3 2


2 * 2 * 3 * 3 = 36



LCM: Least Common Multiple


LCM (24, 36):


1.List Method


24: 24, 48, 72, 96

36: 36, 72, 108


LCM (24, 36) = 72


2. Prime Factorization Method


LCM (24, 36) =

GCF * 2 * 3 =

^

Unused Factors from the GCF


12 * 2 * 3 = 72

Divisibility Rules

a is divisible by b if there is a number c that meets the requirement: b * c = a


Ex. 10 is divisible by 5 because 2 * 5 = 10


2 * 5 = 10 5 and 2 are factors of 10

5 * 2 = 10 5 and 2 are divisors of 10

10 ÷ 2 = 5 10 is divisible by 2 and 5

10 ÷ 5 = 2 10 is a multiple of 2 and 5


Divisibility Rules:


Ending:


Sum of Digits:


Last Digits:


Extras:


Examples:

*770: 2, 5, 7, 10, 11

*136: 2, 4, 8


Factors:

28: 1, 2, 4, 7, 14, 28

60: 1, 2, 3, 4, 5, 6, 10, 12, 15, 20, 30, 60

7: 1, 7

91: 1, 7, 13, 91


1 –> Identity Multiplication Element

0 –> Identity Addition Element


Prime Numbers (0-60)


2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59

Week Five

Subtraction Algorithms

Subtraction Algorithms


American Standard:


4 13

V V

4 5 3

-2 3 6

––––––

217


European/ Mexican:


1V

4 5 3

4V

-2 3 6

––––––

217


Reverse Indian:


1V

4 5 3

-2 3 6

––––––

2

2

1 7

217


Left - to - right:

13

V

4 5 3

-2 3 6

––––––

2 0 0

2 0

10

7

–––––

217


Expanded Notation:

40 13

453 = 400 + 50 + 3

236 = 200 + 30 + 6

––––––––––––

200 + 10 + 7

217


Integer Subtraction:


4 5 3

-2 3 6

–––––

-3

20

200

––––

217

Addition Algorithms

Addition Algorithms


American Standard:


1

V

384

+235

––––––

619


Partial Sums:


3| 8| 4

+2| 3| 5

––|––|–––

| |9

1 | 1 |

5 | |

––––––––––

619


Partial Sums With Place Value:


3| 8| 4

+2| 3| 5

––|––|–––

| |9

1 | 1 |0

5 | 0 |0

––––––––––

619


Left - to - Right:


384

+235

––––––

500

110

+ 9

––––––

619


Expanded Notation:


100

V

384 = 300 + 80 + 4

+235 = 200 + 30 +5

–––––––––––––––––––

600 + 10 + 9 = 619

Week Three

Multiplication Properties

`Multiplication ––> Repeated addition


3 x 4 = 12 ––> Product

^ ^

Factors


3 x 2 = 3 groups of 2


  1. Identity property of multiplication
  2. Any number multiplied by 1, equals one).
  3. a x 1= a
  4. 7 x 1 = 7
  5. -3 x 1 = -3
  6. 3/5 x 1 = 3/5
  7. 7 x 0 = 0 (any number multiplied by 0, equals 0).
  8. Commutative property of multiplication
  9. The order of numbers being multiplied does not matter.
  10. a x b = b x a
  11. 7 x 3 = 3 x 7
  12. Associative property of multiplication
  13. When multiplying numbers together in an equation, the grouping does not matter.
  14. (a x b) x c = a x (b x c)
  15. (3 x 7) x 2 = 3 x (7 x 2)
  16. Distributive property of multiplication
  17. When a number is multiplied by a sum, it is the same as multiplying that number by adding the sum and partial products together.
  18. a x (b + c) = (a x b) + (a x c)
  19. 3 x 7 = 3 x (5 + 2) = (3 x 5) + (3 x 2)


Addition and Subtraction Properties

Meaning:

Addition (Put together/ Join)


  1. Identity Property
  2. When adding the number 0 to any value, the identity remains the same.
  3. a + 0 = a
  4. 4 + 0 = 4
  5. Commutative Property
  6. The order of numbers in an equation will equal the same value.
  7. a + b = b + a
  8. 3 + 4 = 4 + 3
  9. Associative Property
  10. Grouping of numbers does not matter when adding values.
  11. (a + b) + c = a + (b +c)


Addends

3 + 4 = 7 <–––– Sum

^ ^

Addends



Meanings:

Subtraction:

  1. Take away (5 - 2 = 3)
  2. Comparison**
  3. Missing addend** (3 + __ = 7)


7 - 3 = 4 <–––– Difference

^. ^--- Subtrahend

Minuend


Week One

Problem Solving

I have three 5-cent stamps and two 9-cent stamps. Using one of more of these stamps, how many different amounts of postage can I make?


There are three 5-cent stamps - ©©© 


There are also two 9-cent stamps - ©©


© 

©© 

©©© 

© 

©©

©©

©©©

©©©

©©©©

©©©©

©©©©©


11 different postage combinations


Explanation: First I started off with laying out the different combinations of the 5-cent and 9-cent stamps, there are three 5-cent (blue) stamps and two 9-cent (red) stamps. Each combination containing both types of stamps are all unique as they have different numbers of both the 5-cent and 9-cent stamps. I first started with different combinations of 5-cent stamps with the 9-cent stamps by adding one, two, or three 5-cent stamps to each combination of 9-cent stamps. For example, when I had one 5-cent stamp I needed to add one 9-cent stamp and then another 9-cent stamp to a different 5-cent stamp so it went up +1 each time until I ran out of 9-cent stamps. I did this with other combinations of 5-cent stamps such as having two or three 5-cent stamps with one or two 9-cent stamps. Adding up all the different combinations of stamps it is a total of 11 different postage combinations.

Polya's Four Steps
  1. Understand the question/ problem:
  2. What are you asked to find/ show?
  3. Can you restate the problem?
  4. Can you draw a picture or diagram to help you solve the problem?
  5. Plan how to solve the problem:
  6. Draw a picture/ diagram
  7. Look for a pattern
  8. Work backwards
  9. Make the problem simpler
  10. Implement the plan to solve the problem:
  11. Try different strategies
  12. Do not get discouraged
  13. Carrying out the plan is usually easier than devising the plan
  14. Look back (reflect):
  15. Is it a reasonable answer?
  16. Did all questions get answered?
  17. Is there an easier way?
  18. What did you learn?

Week Fourteen

Positive and Negative Numbers

-17 + (10) = -7


-10 - (8) = -18


3 * (-4) = -7


16 / -4 = -4

Week Twelve

Decimals and Place Value

Decimals:


a) 0.128 < 0.234 < 0.45 <0.9


b) 0.23 < 0.3 < 0.378 < 0.98


c) 0.003 < 0.03 < 0.033 < 0.303 < 0.33 < 3.003



Place Value:


Hundred Hundred

Thousands Thousands Tens Tenths Thousandths Thousandths

V V V V v V

100,000 10,000 1,000 100 10 1 . 1/10 1/100 1/1,000 1/10,000 1/100,000

^ ^ ^ ^ ^

Ten Hundreds Ones Hundredths Ten

Thousands Thousandths



**If decimals are repeating, only use the line to represent what is being repeated**

__

0.21212121 = 0.21

_

0.555555 = 0.5

__

0.2345454545 = 0.2345

Multiplying and Dividing Decimals

Multiplication:


0.34 x 2 = ?


0.34

x 2

-----------

0.68


Answer:


0.34 x 2 = 0.68

Division:


1 ÷ 8 = ?


0.1 2 5

8 ⟌ 1.0 0 0

-8 | |

---- V |

2 0 |

-1 6 |

----- V

4 0

-4 0

----------

0


Answer:


1 ÷ 8 = 0.125


0.125 = 12.5%


0.125 = 1/8

Adding and Subtracting Decimals

Adding:


1.24 + 1.35 = ?


1.24

+ 1.35

-------------

2.59


21.34 + 90.319 = ?


21.34

+ 90.319

---------------

111.659



Subtracting:


34.45 - 32.23 = ?


34.45

- 32.23

---------------

2.22


12.338 - 8.23 = ?


12.338

- 08.230

---------------

4.108



Week Ten

Practice Problems

There was ¾ of a pie in the refrigerator. John ate 2/3 of the left over pie. How much pie did he eat?


  1. First start by drawing out 3/4 on paper.
  2. Then shade 2/3 of whats left of the pizza.
  3. It would be 3/6 still shaded.



Jim, Ken, Len, and Max have a bag of miniature candy bars from trick-or-treating together. Jim took ¼ of all the bars, and Ken and Len each took 1/3 of all the bars. Max got the remaining 4 bars. How many bars were in the bag originally? How many bars did Jim, Ken, and Len each get?


Jim: 1/4 = 3/12 = 12 bars

Ken: 1/3 = 4/12 = 16 bars

Len: 1/3 = 4/12 = 16 bars

Max: 4 bars = 1/12


Draw a 3 x 4 grid containing 12 squares inside of it.


Week Eight

Fractions

Fractions:


Meanings:

  1. Part-Whole
  2. Quotient
  3. Ratio


Models:

  1. Surface Area
  2. Length
  3. Sets (groups of things)



20 Students

13 girls

7 boys


Fractions:


Girls 13 Boys 7

------- = ----- --------- = ----

Whole 20 Whole 20


Not Fractions:


Boys 7 Girls 13

-------- = ---- ------- = ----

Girls 13 Boys 7



3/7 > 1/7

4/5 > 4/9

3/7 < 5/8

9/10 > 3/4


4/ 4 = 1

1.4./ 1.4 = 1

x/ x = 1

xy/ xy =1

Week Six

EXAM 1

Week Four

Multiplication and Division

Division


8 ÷ 4 -> ÷ Division Sign


8/2 -> / Division/ Fraction Bar


2 ⟌8 -> The rinculum



Quotient

V

4

2⟌8 <- Dividend

^

Divisor


Standard Algorithm Place Value Explicit

1 4 6 1 4 6

4 ⟌5 8 5 4 ⟌5 8 5

- 4 | | - 4 0 0

------V | --------

1 8 | 1 8 5

- 16 | - 1 6 0

---------V --------

2 5 2 5

- 2 4 - 2 4

--------- ---------

1 <-- Remainder 1 <-- Remainder



Alternative Algorithm


167 Pokemon Cards

12 in each booster pack

How many Packs? 13 Packs

12 ⟌ 1 6 7

- 1 2 0 --> 10 packs

-----------

47

- 36 --> 3 packs

-------------

11




  1. Standard Algorithm 2. Place Value 3. Expanded Notation

2

^ 19 19

19 x 13 x 13

x 13 ---------- ---------

---------- 3 x 9 = 27 -->20 10 + 9

5 7 3 x 10 = 30 10 + 3

+ 1 9 0 10 x 9 = 90 ----------

---------- + 10 x 10 = 100 110 + 7

2 4 7 --------------------- -----------

2 4 7 100 + 90 + 0

200 + 40 + 7

------------------

2 4 7

Week Two

Expanded Notation

Expanded Notation:


285 = 2 hundreds + 8 tens + 5 ones.

= 200 + 80 + 5

= (2 x 100) + (8 x 10) + (5 x 1)

= (2 x 10^2) + (8x10^1) + (5 x 10^0)


Note: When moving from left to right, the exponent must decrease by -1.


(Numbers to the power of 0 always equal 1)


For expanded notation, we are going to use the number 1342 with a base of 5.

13425


13425 = (1 x 5^3) + (3 x 5^2) + (4 x 5^1) + (2 x 5^0)

= (1 x 125) + (3 x 25) + (4 x 5) + (2 x 1)

= 125 + 75 + 20 + 2

= 222


2123 = (2 x 3^2) + (1 x 3^1) + (2 x 3^0)

= (2 x 9) + (1 x 3) + (2 x 1)

= 18 + 3 + 2

= 23

Numeration Systems

Base-10 (Decimal)


Using the number, 357.35, lets break down what each value represents.


Decimal

10's Point 1/100

V V V

3 5 7 . 3 5

^ ^ ^

100's 1's 1/10


<–––––––– –––––––––>

x10 ÷10


Base-10:

Ones - 10^0

Tens - 10^1

Hundreds - 10^2

Thousands - 10^3


When in base form, no value can exceed the number of the base. For example,

In base-10 there are 10 numeric digits:

0, 1, 2, 3, 4, 5, 6, 7, 8, and 9.

Therefore, any value in base-form cannot be larger than 9.


So in base-5, the digits are 0, 1, 2, 3, and 4.

And again but in base-3, 0, 1, and 2.