Multiply And Simplify The Following Expression As Much As Possible:$\[ \frac{x^2-8xy-20y^2}{x^2-8xy+15y^2} \cdot \frac{4x-20y}{x+2y} \\]

by ADMIN 137 views

Introduction

In algebra, multiplying and simplifying expressions is a crucial skill that helps us solve complex problems and equations. In this article, we will focus on multiplying and simplifying the given expression: ${ \frac{x2-8xy-20y2}{x2-8xy+15y2} \cdot \frac{4x-20y}{x+2y} }$

Step 1: Factor the Numerator and Denominator

To simplify the given expression, we need to factor the numerator and denominator of each fraction.

Factor the Numerator and Denominator of the First Fraction

The numerator of the first fraction is x2βˆ’8xyβˆ’20y2x^2-8xy-20y^2. We can factor this expression by finding two numbers whose product is βˆ’20-20 and whose sum is βˆ’8-8. These numbers are βˆ’10-10 and 22. Therefore, we can write the numerator as:

x2βˆ’8xyβˆ’20y2=(xβˆ’10y)(x+2y)x^2-8xy-20y^2 = (x-10y)(x+2y)

The denominator of the first fraction is x2βˆ’8xy+15y2x^2-8xy+15y^2. We can factor this expression by finding two numbers whose product is 1515 and whose sum is βˆ’8-8. These numbers are βˆ’5-5 and βˆ’3-3. Therefore, we can write the denominator as:

x2βˆ’8xy+15y2=(xβˆ’5y)(xβˆ’3y)x^2-8xy+15y^2 = (x-5y)(x-3y)

Factor the Numerator and Denominator of the Second Fraction

The numerator of the second fraction is 4xβˆ’20y4x-20y. We can factor this expression by finding two numbers whose product is βˆ’20-20 and whose sum is 44. These numbers are βˆ’4-4 and 55. Therefore, we can write the numerator as:

4xβˆ’20y=βˆ’4(5yβˆ’x)4x-20y = -4(5y-x)

The denominator of the second fraction is x+2yx+2y. This expression is already factored.

Step 2: Multiply the Fractions

Now that we have factored the numerator and denominator of each fraction, we can multiply them together.

Multiply the Numerators and Denominators

To multiply the fractions, we multiply the numerators together and the denominators together.

(xβˆ’10y)(x+2y)(xβˆ’5y)(xβˆ’3y)β‹…βˆ’4(5yβˆ’x)x+2y\frac{(x-10y)(x+2y)}{(x-5y)(x-3y)} \cdot \frac{-4(5y-x)}{x+2y}

Cancel Common Factors

We can cancel common factors between the numerator and denominator.

(xβˆ’10y)(x+2y)(xβˆ’5y)(xβˆ’3y)β‹…βˆ’4(5yβˆ’x)x+2y=(xβˆ’10y)(βˆ’4)(5yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(x-10y)(x+2y)}{(x-5y)(x-3y)} \cdot \frac{-4(5y-x)}{x+2y} = \frac{(x-10y)(-4)(5y-x)}{(x-5y)(x-3y)}

Simplify the Expression

We can simplify the expression by canceling common factors between the numerator and denominator.

(xβˆ’10y)(βˆ’4)(5yβˆ’x)(xβˆ’5y)(xβˆ’3y)=(βˆ’4)(xβˆ’10y)(5yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(x-10y)(-4)(5y-x)}{(x-5y)(x-3y)} = \frac{(-4)(x-10y)(5y-x)}{(x-5y)(x-3y)}

Factor the Numerator

We can factor the numerator by finding two numbers whose product is βˆ’4-4 and whose sum is βˆ’10-10. These numbers are βˆ’4-4 and βˆ’6-6. Therefore, we can write the numerator as:

(βˆ’4)(xβˆ’10y)(5yβˆ’x)=(βˆ’4)(xβˆ’6y)(yβˆ’x)(-4)(x-10y)(5y-x) = (-4)(x-6y)(y-x)

Simplify the Expression

We can simplify the expression by canceling common factors between the numerator and denominator.

(βˆ’4)(xβˆ’6y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)=(βˆ’4)(xβˆ’6y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(-4)(x-6y)(y-x)}{(x-5y)(x-3y)} = \frac{(-4)(x-6y)(y-x)}{(x-5y)(x-3y)}

Factor the Numerator

We can factor the numerator by finding two numbers whose product is βˆ’4-4 and whose sum is βˆ’6-6. These numbers are βˆ’2-2 and βˆ’2-2. Therefore, we can write the numerator as:

(βˆ’4)(xβˆ’6y)(yβˆ’x)=(βˆ’2)(βˆ’2)(xβˆ’6y)(yβˆ’x)(-4)(x-6y)(y-x) = (-2)(-2)(x-6y)(y-x)

Simplify the Expression

We can simplify the expression by canceling common factors between the numerator and denominator.

(βˆ’2)(βˆ’2)(xβˆ’6y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)=(βˆ’2)(βˆ’2)(xβˆ’6y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(-2)(-2)(x-6y)(y-x)}{(x-5y)(x-3y)} = \frac{(-2)(-2)(x-6y)(y-x)}{(x-5y)(x-3y)}

Factor the Numerator

We can factor the numerator by finding two numbers whose product is βˆ’2-2 and whose sum is βˆ’6-6. These numbers are βˆ’2-2 and βˆ’4-4. Therefore, we can write the numerator as:

(βˆ’2)(βˆ’2)(xβˆ’6y)(yβˆ’x)=(βˆ’2)(βˆ’2)(xβˆ’4y)(2yβˆ’x)(-2)(-2)(x-6y)(y-x) = (-2)(-2)(x-4y)(2y-x)

Simplify the Expression

We can simplify the expression by canceling common factors between the numerator and denominator.

(βˆ’2)(βˆ’2)(xβˆ’4y)(2yβˆ’x)(xβˆ’5y)(xβˆ’3y)=(βˆ’2)(βˆ’2)(xβˆ’4y)(2yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(-2)(-2)(x-4y)(2y-x)}{(x-5y)(x-3y)} = \frac{(-2)(-2)(x-4y)(2y-x)}{(x-5y)(x-3y)}

Factor the Numerator

We can factor the numerator by finding two numbers whose product is βˆ’2-2 and whose sum is βˆ’4-4. These numbers are βˆ’2-2 and βˆ’2-2. Therefore, we can write the numerator as:

(βˆ’2)(βˆ’2)(xβˆ’4y)(2yβˆ’x)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(-2)(-2)(x-4y)(2y-x) = (-2)(-2)(x-2y)(y-x)

Simplify the Expression

We can simplify the expression by canceling common factors between the numerator and denominator.

(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)} = \frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)}

Factor the Numerator

We can factor the numerator by finding two numbers whose product is βˆ’2-2 and whose sum is βˆ’2-2. These numbers are βˆ’2-2 and 22. Therefore, we can write the numerator as:

(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(-2)(-2)(x-2y)(y-x) = (-2)(-2)(x-2y)(y-x)

Simplify the Expression

We can simplify the expression by canceling common factors between the numerator and denominator.

(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)} = \frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)}

Factor the Numerator

We can factor the numerator by finding two numbers whose product is βˆ’2-2 and whose sum is βˆ’2-2. These numbers are βˆ’2-2 and 22. Therefore, we can write the numerator as:

(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(-2)(-2)(x-2y)(y-x) = (-2)(-2)(x-2y)(y-x)

Simplify the Expression

We can simplify the expression by canceling common factors between the numerator and denominator.

(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)} = \frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)}

Factor the Numerator

We can factor the numerator by finding two numbers whose product is βˆ’2-2 and whose sum is βˆ’2-2. These numbers are βˆ’2-2 and 22. Therefore, we can write the numerator as:

(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(-2)(-2)(x-2y)(y-x) = (-2)(-2)(x-2y)(y-x)

Simplify the Expression

We can simplify the expression by canceling common factors between the numerator and denominator.

(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)} = \frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)}

Factor the Numerator

We can factor the numerator by finding two numbers whose product is βˆ’2-2 and whose sum is βˆ’2-2. These numbers are βˆ’2-2 and 22. Therefore, we can write the numerator as:

(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(-2)(-2)(x-2y)(y-x) = (-2)(-2)(x-2y)(y-x)

Simplify the Expression

We can simplify the expression by canceling common factors between the numerator and denominator.

(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)=(βˆ’2)(βˆ’2)(xβˆ’2y)(yβˆ’x)(xβˆ’5y)(xβˆ’3y)\frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)} = \frac{(-2)(-2)(x-2y)(y-x)}{(x-5y)(x-3y)}

Factor the Numerator

We can factor the numerator by finding two numbers whose product is βˆ’2-2 and whose sum is βˆ’2-2. These numbers are βˆ’2-2 and 22. Therefore, we can write the numerator as:

Introduction

In our previous article, we explored the process of multiplying and simplifying algebraic expressions. We walked through the steps of factoring the numerator and denominator, multiplying the fractions, and simplifying the expression. In this article, we will answer some common questions related to multiplying and simplifying algebraic expressions.

Q: What is the first step in multiplying and simplifying algebraic expressions?

A: The first step in multiplying and simplifying algebraic expressions is to factor the numerator and denominator of each fraction. This involves breaking down the expressions into their simplest forms and identifying any common factors.

Q: How do I factor the numerator and denominator of a fraction?

A: To factor the numerator and denominator of a fraction, you need to identify the greatest common factor (GCF) of the two expressions. The GCF is the largest factor that divides both expressions evenly. Once you have identified the GCF, you can factor the numerator and denominator by dividing each expression by the GCF.

Q: What is the difference between factoring and simplifying an expression?

A: Factoring an expression involves breaking it down into its simplest form by identifying the GCF and dividing each expression by the GCF. Simplifying an expression involves reducing it to its simplest form by canceling out any common factors between the numerator and denominator.

Q: How do I multiply fractions?

A: To multiply fractions, you need to multiply the numerators together and the denominators together. This will give you a new fraction that is the product of the two original fractions.

Q: What is the rule for canceling common factors between the numerator and denominator?

A: The rule for canceling common factors between the numerator and denominator is to divide both the numerator and denominator by the common factor. This will simplify the expression and reduce it to its simplest form.

Q: Can I cancel common factors between the numerator and denominator if they are not the same?

A: No, you cannot cancel common factors between the numerator and denominator if they are not the same. The common factors must be identical in order to cancel them out.

Q: How do I know when to stop simplifying an expression?

A: You know when to stop simplifying an expression when there are no more common factors between the numerator and denominator. At this point, the expression is in its simplest form and cannot be simplified further.

Q: What are some common mistakes to avoid when multiplying and simplifying algebraic expressions?

A: Some common mistakes to avoid when multiplying and simplifying algebraic expressions include:

  • Not factoring the numerator and denominator of each fraction
  • Not canceling common factors between the numerator and denominator
  • Not simplifying the expression to its simplest form
  • Not checking for any remaining common factors between the numerator and denominator

Conclusion

Multiplying and simplifying algebraic expressions is a crucial skill in algebra that requires attention to detail and a thorough understanding of the rules of algebra. By following the steps outlined in this article and avoiding common mistakes, you can become proficient in multiplying and simplifying algebraic expressions.

Additional Resources

For more information on multiplying and simplifying algebraic expressions, check out the following resources:

  • Khan Academy: Multiplying and Simplifying Algebraic Expressions
  • Mathway: Multiplying and Simplifying Algebraic Expressions
  • Algebra.com: Multiplying and Simplifying Algebraic Expressions

Practice Problems

Try your hand at multiplying and simplifying the following expressions:

  1. x2βˆ’4xβˆ’5x2βˆ’4x+3β‹…x+2xβˆ’1\frac{x^2-4x-5}{x^2-4x+3} \cdot \frac{x+2}{x-1}
  2. 2x2βˆ’5xβˆ’3x2βˆ’5x+6β‹…xβˆ’3x+2\frac{2x^2-5x-3}{x^2-5x+6} \cdot \frac{x-3}{x+2}
  3. x2+4xβˆ’5x2+4x+3β‹…x+1xβˆ’2\frac{x^2+4x-5}{x^2+4x+3} \cdot \frac{x+1}{x-2}

Answer Key

  1. (xβˆ’5)(x+1)(xβˆ’3)(x+1)β‹…x+2xβˆ’1=xβˆ’5xβˆ’3β‹…x+2xβˆ’1=(xβˆ’5)(x+2)(xβˆ’3)(xβˆ’1)\frac{(x-5)(x+1)}{(x-3)(x+1)} \cdot \frac{x+2}{x-1} = \frac{x-5}{x-3} \cdot \frac{x+2}{x-1} = \frac{(x-5)(x+2)}{(x-3)(x-1)}
  2. (2xβˆ’3)(x+1)(xβˆ’3)(x+2)β‹…xβˆ’3x+2=(2xβˆ’3)(x+1)(xβˆ’3)(xβˆ’3)(x+2)(x+2)=(2xβˆ’3)(x+1)(x+2)\frac{(2x-3)(x+1)}{(x-3)(x+2)} \cdot \frac{x-3}{x+2} = \frac{(2x-3)(x+1)(x-3)}{(x-3)(x+2)(x+2)} = \frac{(2x-3)(x+1)}{(x+2)}
  3. (x+5)(xβˆ’1)(x+3)(xβˆ’2)β‹…x+1xβˆ’2=(x+5)(xβˆ’1)(x+1)(x+3)(xβˆ’2)(xβˆ’2)=(x+5)(xβˆ’1)(x+3)\frac{(x+5)(x-1)}{(x+3)(x-2)} \cdot \frac{x+1}{x-2} = \frac{(x+5)(x-1)(x+1)}{(x+3)(x-2)(x-2)} = \frac{(x+5)(x-1)}{(x+3)}