Exponents - A complete course in algebra

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A L G E B R A

EXPONENTS

WHEN A NUMBER is repeatedly multiplied by itself, we get the powers of that number (Lesson 1).

Problem 1. What number is

a)	the third power of 2? 2· 2· 2 = 8	b)	the fourth power of 3? = 81

c)	the fifth power of 10? = 100,000	d)	the first power of 8? = 8

Now, rather than write the third power of 2 as 2· 2· 2, we write 2 just once -- and place an exponent: 2³. 2 is called the base. The exponent indicates the number of times to repeat the base as a factor.

Problem 2. What does each symbol mean?

a)	x⁵ = xxxxx	b)	5³ = 5· 5· 5

c)	(5a)³ = 5a· 5a· 5a	d)	5a³ = 5aaa

In part c), the parentheses indicate that 5a is the base. In part d), only a is the base. The exponent does not apply to 5.

Problem 3. 3⁴ = 81.

a) Which number is called the base? 3

b) Which number is the power? 81 is the power of 3.

c) Which number is the exponent? 4. It indicates the power.

Problem 4. Write out the meaning of these symbols.

a²a³ =

(ab)³ =

(a²)³ =

d) (−a)⁴ = (−a)(−a)(−a)(−a)

e) −a⁴ = −aaaa

In part d), the base is −a. In part e), only a is the base. That symbol means "the negative of a⁴."

Problem 5. Evaluate.

a) −2⁴ = −16. Just as −5 is the negative of 5, this is the negative of 2⁴. The base is 2. See Problem 4e) above.

b) (−2)⁴ = +16, according to the Rule of Signs (Lesson 4).
The parentheses indicate that −2 is the base. See Problem 4d).

Example 1. Negative base.

(−2)³ = (−2)(−2)(−2) = −8,

again according to the Rule of Signs. Whereas,

(−2)⁴ = +16.

When the base is negative, and the exponent is odd, then the product is negative. But when the base is negative, and the exponent is even, then the product is positive.

Problem 6. Evaluate.

a)	(−1)² = 1	b)	(−1)³ = −1	c)	(−1)⁴ = 1	d)	(−1)⁵ = −1

e)	(−1)¹⁰⁰ = 1	f)	(−1)²⁵³ = −1	g)	(−2)⁴ = 16	h)	(−2)⁵ = −32

Problem 7. Rewrite using exponents.

xxxxxx

xxyyyy

xyxxyx

xyxyxy

Problem 8. Rewrite using exponents.

a)	(x + 1)(x + 1) = (x + 1)²	b)	(x − 1)(x − 1)(x − 1) = (x − 1)³

c)	(x + 1)(x − 1)(x + 1)(x − 1) = (x + 1)²(x − 1)²

d)	(x + y)(x + y)² = (x + y)³

Three rules

Rule 1. Same Base

a^maⁿ = a^{m + n}

"To multiply powers of the same base, add the exponents."

For example, a²a³ = a⁵.

Why do we add the exponents? Because of what the symbols mean. Problem 4a.

Example 2. Multiply 3x²· 4x⁵· 2x

Solution. The problem means (Lesson 5): Multiply the numbers, then combine the powers of x :

3x²· 4x⁵· 2x = 24x⁸

Two factors of x -- x² -- times five factors of x -- x⁵ -- times one factor of x, produce a total of 2 + 5 + 1 = 8 factors of x : x⁸.

Problem 3. Multiply. Apply the rule Same Base.

a)	5x²· 6x⁴ = 30x⁶	b)	7x³· 8x⁶ = 56x⁹	c)	x· 5x⁴ = 5x⁵

d)	2x· 3x· 4x = 24x³	e)	x³· 3x²· 5x = 15x⁶	f)	x⁵· 6x⁸y² = 6x¹³y²

g)	4x· y· 5x²· y³ = 20x³y⁴	h)	2xy· 9x³y⁵ = 18x⁴y⁶

i)	a²b³a³b⁴ = a⁵b⁷	j)	a²bc³b²ac = a³b³c⁴

k)	x^myⁿx^py^q = x^{m + p}y^{n + q}	l)	a^pb^qab = a^{p + 1}b^{q + 1}

Example 3. Compare the following:

a) x· x⁵ b) 2· 2⁵

Solution.

a) x· x⁵ = x⁶

b) 2· 2⁵ = 2⁶

Part b) has the same form as part a). It is part a) with x = 2.

One factor of 2 multiplies five factors of 2 producing six factors of 2. 2· 2 = 4 is not an issue.

Problem 4. Apply the rule Same Base.

a)	xx⁷ = x⁸	b)	3· 3⁷ = 3⁸	c)	2· 2⁴· 2⁵ = 2¹⁰

d)	10· 10⁵ = 10⁶	e)	3x· 3⁶x⁶ = 3⁷x⁷

Problem 5. Apply the rule Same Base.

a)	xⁿx² = x^{n + 2}	b)	xⁿx = x^{n + 1}	c)	xⁿxⁿ = x²ⁿ	d)	xⁿx^{1 − n} = x

e)	x· x^{n + 2} = x^{n + 3}	f)	xⁿx^m = x^{n + m}	g)	x²ⁿx^{2 − n} = x^{n + 2}

Rule 2: Power of a Product of Factors

(ab)ⁿ = aⁿbⁿ

"Raise each factor to that same power."

For example, (ab)³ = a³b³.

Why may we do that? Again, according to what the symbols mean:

(ab)³ = ab· ab· ab = aaabbb = a³b³.

The order of the factors does not matter:

ab· ab· ab = aaabbb.

Problem 6. Apply the rules of exponents.

(xy)⁴ =

(pqr)⁵ =

(2abc)³ =

d) x³y²z⁴(xyz)⁵	=	x³y²z⁴· x⁵y⁵z⁵ Rule 2,

	=	x⁸y⁷z⁹ Rule 1.

Rule 3: Power of a Power

(a^m)ⁿ = a^mn

"To take a power of a power, multiply the exponents."

For example, (a²)³ = a^{2 · 3} = a⁶.

Why do we do that? Again, because of what the symbols mean:

(a²)³ = a²a²a² = a^{3 · 2} = a⁶

Problem 7. Apply the rules of exponents.

(x²)⁵

(a⁴)⁸

(10⁷)⁹

Example 4. Apply the rules of exponents: (2x³y⁴)⁵

Solution. Within the parentheses there are three factors: 2, x³, and y⁴. According to Rule 2, we must take the fifth power of each one. But to take a power of a power, we multiply the exponents. Therefore,

(2x³y⁴)⁵ = 2⁵x¹⁵y²⁰

Problem 8. Apply the rules of exponents.

a)	(10a³)⁴ = 10,000a¹²	b)	(3x⁶)² = 9x¹²	c)	(2a²b³)⁵ = 32a¹⁰b¹⁵

d)	(xy³z⁵)² = x²y⁶z¹⁰	e)	(5x²y⁴)³ = 125x⁶y¹²

f) (2a⁴bc⁸)⁶ = 64a²⁴b⁶c⁴⁸

Problem 9. Apply the rules of exponents.

a)	2x⁵y⁴(2x³y⁶)⁵ = 2x⁵y⁴· 2⁵x¹⁵y³⁰ = 2⁶x²⁰y³⁴

b) abc⁹(a²b³c⁴)⁸ = abc⁹· a¹⁶b²⁴c³² = a¹⁷b²⁵c⁴¹

Problem 10. Use the rules of exponents to calculate the following.

a)	(2· 10)⁴ = 2⁴· 10⁴ = 16· 10,000 = 160,000

b) (4· 10²)³ = 4³· 10⁶ = 64,000,000

c) (9· 10⁴)² = 81· 10⁸ = 8,100,000,000

Example 5. Square x⁴.

Solution. (x⁴)² = x⁸.

Thus to square a power, double the exponent.

Problem 11. Square the following.

x⁵

8a³b⁶

−6x⁷

xⁿ

Note: In part c): The square of a negative number is positive.

(−6)(−6) = +36.

Problem 12. Apply a rule of exponents -- if possible.

x²x⁵

(x²)⁵

c) x² + x⁵

In summary: Add the exponents when the same base appears twice: x²x⁴ = x⁶. Multiply the exponents when the base appears once -- and in parentheses: (x²)⁵ = x¹⁰.

Problem 13. Apply the rules of exponents.

(xⁿ)ⁿ

(xⁿ)²

Problem 14. Apply a rule of exponents, or add like terms -- if possible.

a) 2x² + 3x⁴ Not possible. These are not like terms (Lesson 1).

b) 2x²· 3x⁴ = 6x⁶. Rule 1.

c) 2x³ + 3x³ = 5x³. Like terms. The exponent does not change.

d) x² + y² Not possible. These are not like terms.

e) x² + x² = 2x². Like terms.

f) x²· x² = x⁴. Rule 1.

g) x²· y³ Not possible. Different bases.

h) 2· 2⁶ = 2⁷. Rule 1.

Next Lesson: Multiplying out. The distributive rule.

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