Unit 3: Exponents, Radicals, and Exponential Equations

Foundations of Math 2 Final Exam Review Name: ______

UNIT 3: EXPONENTS, RADICALS, AND EXPONENTIAL EQUATIONS

Part 1: Exponent Rules

Mathematical Expressions can be simplified used exponent rules

Here are all of the rules:

______

______

______

______

______

______

ADDING AND SUBTRACTING EXPRESSIONS

When you are adding and subtracting exponents, you must:

______only!

Make sure to ______the ______ when subtracting

Example:

(4x2 + 9x – 6) + (7x2 – 2x – 1) = ______

(3x2 + 5x – 8) – (5x2 – 4x + 6) = ______

MULTIPLYING EXPRESSIONS

When you are multiplying expressions:

______ the whole numbers

______ the exponents

Example:

(4x3)(2x2) = ______

(-4x5)(3x2) = ______

RAISING A POWER TO A POWER

When you are raising a power to a power:

______ the whole numbers to the power

______ the exponents

Example: (5x2)4 = ______

(-3x6)3 = ______

DIVIDING EXPRESSIONS

When you are dividing expressions:

______the whole numbers

______ the exponents

Example:

= ______

______

NEGATIVE EXPONENTS

When you have a negative exponent:

______the negative exponent “______”, meaning move it to the other side of the ______

When you move it, change the exponent to a ______because now it’s ______

Example:

= ______

= ______

ZERO EXPONENTS

When you have a zero exponent:

The answer is always ______

Example: = ______

= ______

Practice All Exponent Rules:

1. (5x2 – 5x + 2) + (6x2 + 2x – 10) =

2. (3x2 + 6x – 4) – (6x2 – 2x + 9) =

3. (6x4)(5x2) =

4. (4x2)3 =

5. =

6. =

7. (3x2y)0 =

Part 2: Converting a Radical into a Fractional Exponent

Parts of a radical

When converting a radical to a fractional exponents

The power inside the radical becomes the ______

The number in the ______becomes the ______

Example: = ______

Now try these:

1. = ______3. = ______

2. = ______4. = ______

______

Part 3: Converting a Fractional Exponent into a Radical

When converting a fractional exponent to a radical:

The numerator becomes the power ______the radical

The denominator becomes the number in the ______

Example: = ______

Now try these:

1. = ______3. = ______

2. = ______4. = ______

______

Part 4: Solving Rational Equations

When solving rational equations with ______terms, you must ______

Example:

5(2x+1) = 20x

10x + 5 = 20x

5 = 10x

x =

You try:

Example: Answer: ______

Part 5: Exponential Growth and Decay

Exponential Functions can either represent ______or ______

Every function follows this formula:

y = a bx

a is the ______ value

b is the ______or ______ rate

If the problem is growth, use (______) for b

If the problem is decay, use (______) for b

x is the ______

Example: Write the equation for this situation: The amount of movies made in 2015 was 1,255. The number is expected to increase by 2.1% every year. ______

Now try these: Write an equation for these situations:

1. The population of an ant colony with 5,056 members increases by 5.6% every year.

______

1. The number of people who live in North Dakota (who currently has 739,482 people) decreases every year by 1.3%.

______

______

Part 5: Word Problems

There are many real life situations that use exponential growth and decay. You can use these equations in order to predict outcomes in the future.

In order to do this, use your calculator to put in the equation and use the table to find values.

Try this one:

The model y = 604000(1 + 0.045)x represent the population of Washington DC after 1990.

1. Find the initial population: ______

2. Is this a growth or decay problem? ______

3. Predict the population in 1995. ______

4. In what year will the population reach 1,000,000? ______

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