intermediate algebra chapter 7 - gay radical expressions
TRANSCRIPT
Oprah Winfrey
• “Although there may be tragedy in your life, there’s always to possibility to triumph. It doesn’t matter who you are, where you come from. The ability to triumph begins with you. Always.”
Angela Davis – U.S. political activist-1987 – Spellman college
• “Radical simply means grasping things at the root.”
Definition of nth root
• For any real numbers a and b and any integer n>1, a is a nth root of b if and only if
na b
Principal nth root
• Even roots
• Principal nth root of b is the
nonnegative nth root of b.
• Represented by
n b
Objectives
• 1. Find the nth root of a number• 2. Approximate roots using
calculator.• 3. Graph radical functions• 4. Determine domain and range of
radical functions.• 5. Simplify radical expressions.
Rational Exponent – numerator of 1
• For any real number b for which the nth roof of b is defined and any integer n>1
1n nb b
Procedure: Reduce the Index
• 1. Write the radical in exponential form
• 2. Reduce exponent to lowest terms.
• 3. Write the exponential expression as a radical.
Objectives:
• 1. Evaluate rational exponents.
• 2. Write radicals as expressions raised to rational exponents.
• 3. Simplify expressions with rational number exponents using the rules of exponents.
• 4. Simplify radical expressions
Thomas Edison
• “I am not discouraged, because every wrong attempt discarded is another step forward.”
Product Rule for Radicals
• For all real numbers a and b for which the operations are defined
• The product of the radicals is the radical of the product.
n n na b ab
Simplifying a RadicalCondition 1
• The radicand of a simplified n-th root radical must not contain a perfect n-th power factor.
Using product rule to simplify
• 1. Write the radicand as a product of the greatest possible perfect nth power and a number that has no perfect nth power factors.
• 2. Use product rule• 3. Find the nth root of perfect nth power
radicand.• 4. Do all necessary simplifications
Quotient Rule for Radicals• For all real numbers a and b for which the
operations are defined.
• The radical of a quotient is the quotient of the radical.
n n
n n
a a
b b
Simplifying a radical: condition 2
• The radicand of a simplified radical must not contain a fraction
33
7 9
9 x
Simplifying a radical – condition 3
• A simplified radical must not contain a radical in the denominator.
3 3
5 7
4 x
Rationalizing the denominator
• Square Roots• 1. Multiply both the numerator
and denominator by the same square root as appears in the denominator.
• 2. Simplify.
Rationalizing a denominator containing a higher-order radical.
• Multiply the numerator and denominator by the expression that will make the radicand of the denominator a perfect nth power.
Definition: Like Radicals
• Are radical expressions
• * with identical radicands
• and
• * Identical indexes.
Procedure – Adding like radicals
• Simplify all radicals first.
• To add or subtract like radicals, add or subtract the coefficients and keep the radicals the same.
Procedure- multiplication with radicals
• Simplify all radicals first
• Use Product Rule
• Use distributive property
• Use FOIL if needed
Rationalizing a binomial denominator with radicals
• Multiply the numerator and denominator by the conjugate of the denominator.
• Combine and Simplify
• Denominator cannot be radical
Rationalizing a binomial numerator with radicals
• Multiply the numerator and denominator by the conjugate of the numerator.
• Combine and Simplify
• Denominator cannot be radical
Lance Armstrong
• “I didn’t just jump back on the bike and win. There were a lot of ups and downs, good results and bad results, but this time I didn’t let the lows get to me.”
Definition: imaginary number i
• The symbol I represents an imaginary number with the following properties:
21 1i and i
Definition: Complex Number
• A number that can be expression the form
• a + bi where a and b are real numbers and i is the imaginary unit.
a+bi
• a is called the real part• b is called the imaginary part• a+bi is standard form• a+0i is a real number = a• 0 + bi =bi is pure imaginary
number
Set of Complex Numbers
• Set of Real numbers = R union with set of Imaginary numbers = I is the set of Complex numbers=C
R I C
Equality of Complex Numbers
• a + bi = c + di if and only if
• a = b and c = d
• Real parts are equal and imaginary parts are equal
Add and subtract Complex #s
• (a+bi)+(c+di) = (a + c) + (b + d)i
• (a+bi) - (c+di) = (a - c)+(b – d)I
• Add or subtract the real and imaginary parts.
Multiplication of complex numbers
• (a+bi)(c+di)=(ac-bd) + (bc+ad)I
• Translation:
• 1. Use FOIL
• 2. Substitute
• 3. Combine terms
• 4. Write in standard form
2 1i
Division of imaginary number by real number
• To divide a + bi by a nonzero real number c, divide real part and imaginary part by c.
2
2
6 5 6 5 7 2
7 2 7 2 7 2
42 12 35 10
49 432 47
53 53
i i i
i i i
i i i
i
i
a bi a bi
c c c
Division by Complex Numbers
• 1. Multiply numerator and denominator by complex conjugate of denominator.
• 2. Combine and simplify
• 3. *** Write in standard form.