Free Sample of Upcoming Core Subjects EC-6 Math Study Material and Sample Questions

Competency 002 (Number Concepts and Operations):

The educator knows concepts related to numbers, operations and algorithms and the properties of numbers.

The teacher:

A. Knows how to create, describe, analyze, compare, and model relationships between operations, algorithms, and number properties for the four basic operations involving rational numbers, real numbers, and integers, including real-world situations.

Four basic operations: addition, subtraction, multiplication, division

Algorithm: a solution with specific steps you follow (if you follow those steps, you end up with the correct solution).  The solution for a long division problem (with specific steps you take to reach it) are an example of an algorithm.

Number properties (commutative properties, associative properties, distributive property, density property, and identity property)

Commutative Properties:

Commutative Property of Addition - numbers can be added in any order without changing the result

Example:  5+3+2 = 3+2+5

Commutative Property of Multiplication - numbers can be multiplied in any order, and the result will remain the same

Example: 5n × 2 = 2 × 5n

Memorization tip:  When you commute, you are moving- going from home to work.  The commutative property involves moving numbers around.

Associative Property of Addition - numbers can be grouped in a sum in any way (using parenthesis) and still get the same result

Examples:

(3 + 1) + 2 = 3 + (1 + 2)

(2n + 4n) + 6 = 2n + (4n + 6)

Associative Property of Multiplication - numbers can be grouped in a product in any way (using parenthesis) and still get the same result

Examples:

(3 × 5) × 2 = 3 × (5 × 2)

5x³(20y) = 20y (5x³)

Distributive Property - this will only happen when an expression includes both addition and multiplication.  When you have a term multiplied by terms in parenthesis, you have to distribute the multiplication over the terms inside the parenthesis.

Examples:

3n (n +5) = 3n²+15n    (you have to multiply 3n×n and 3n×5)

2(2+1) = (2 × 2) + (2 × 1)

Rational numbers - any number that can be expressed as the fraction or quotient x/z of two integers, and the denominator z cannot be equal to zero.  Since z can be equal to 1, all integers are rational numbers.  When represented as a decimal, a rational number will either terminate (end) after a finite number of digits or will begin to repeat the same finite sequence of numbers.

Irrational numbers - any real number that cannot be represented as a simple fraction or a ratio of two integers.  They will not have repeating decimals or terminal decimals.

Real numbers - any value that can be represented on a number line, including both rational and irrational numbers.

Integers - whole numbers; numbers that are not fractions and do not include decimals; can be positive or negative

B. Shows an understanding of equivalency between mathematical expressions and among different representations of rational numbers.

Understanding Equivalency Between Mathematical Expressions

Some examples of equivalent mathematical expressions:

3/4 = .75

6(3n²) = 18n²

(4*2) + 8n + 9n² + 5n = 8 + 13n + 9n²

Understanding Equivalency of Different Representations of Rational Numbers

Examples:

3 ÷ 4 = .75

100.75 = 100 ¾

1. Mr. Jackson posts these numbers on the board.  He then asks different students what type of numbers these are: integers, rational numbers, irrational numbers, or negative numbers.  He asks students to raise their hand to indicate which type of number it is.  Out of 24 students, 22 raise their hands to indicate these numbers are irrational numbers.   Based on this information, Mr. Jackson should:

3.33333

1.34343434

100.75

A. Develop a formal assessment that students take individually so they are not influenced by seeing other students raise their hands.

B. Explain to the students why their answer is incorrect and give them additional homework about integers, rational numbers, irrational numbers, and negative numbers.

C. Since almost all students answered correctly, commend them and move on to the next lesson.

D. Find a new method to re-teach rational and irrational numbers, give students additional opportunities to learn and practice, and then ask individual students to come to the board to explain why certain numbers written on the board are integers, rational numbers, irrational numbers, and negative numbers.

Explanation: All of those numbers are rational numbers, so the majority of the class answered the question incorrectly.  D is correct because he needs to re-teach this concept and give students more practice, and having students come to the board to explain their thought process will help him know what students understand, and will also help students learn from each other.  A is incorrect because Mr. Jackson does not need to do a formal assessment- he already knows students do not understand.  B is incorrect because simply telling students why their answer was incorrect and giving them homework is not likely to help students understand integers, rational, irrational, and real numbers.  C is incorrect because most of the students answered incorrectly.

2. Which of the following math problems demonstrates the commutative property of addition?

A. 3+1 = 2 + 2

B. 3+1= 1+3

C. (3+1) +2=3+ (1+2)

D. 3x + x = 3x + x + 0

Explanation: B is correct because the commutative property of addition states that numbers can be added in any order and the result will be the same.  None of the other options demonstrate that.