Problem 68
Question
For the following problems, perform the divisions. $$ \frac{3 y^{2}+3 y+5}{y^{2}+y+1} $$
Step-by-Step Solution
Verified Answer
Answer: The simplified form of the algebraic expression is \(\frac{3y^2 + 3y + 5}{y^2 + y + 1}\).
1Step 1: Identifying numerator and denominator
The given expression is a fraction, which means there are two parts: the numerator (the top part) and the denominator (the bottom part). We can identify them as:
Numerator: \(3y^2 + 3y + 5\)
Denominator: \(y^2 + y + 1\)
2Step 2: Simplify the numerator and denominator
In this case, both numerator and denominator are already simplified and do not share any common factors that can be cancelled out.
3Step 3: Perform the division or express the result as a rational function
Since we cannot simplify the numerator and denominator further and there's no common factor, the given expression is already a rational function in its simplest form:
$$
\frac{3y^2 + 3y + 5}{y^2 + y + 1}
$$
Key Concepts
Rational ExpressionsPolynomial DivisionSimplifying Algebraic Fractions
Rational Expressions
A rational expression is essentially a fraction in which both the numerator and the denominator are polynomials. In the exercise given, \(\frac{3 y^{2}+3 y+5}{y^{2}+y+1}\) is a rational expression where the numerator is \(3y^2 + 3y + 5\) and the denominator is \(y^2 + y + 1\). The fundamental aspect of working with rational expressions is to identify opportunities to simplify them. Simplification may involve factoring polynomials and cancelling common factors between the numerator and denominator.
Understanding rational expressions is crucial because they appear in various areas of mathematics, including algebra, calculus, and beyond. They are used to model and solve real-world problems where variables exhibit a direct or inverse relationship. Always remember that simplifying a rational expression can simplify the process of solving equations that involve them.
Understanding rational expressions is crucial because they appear in various areas of mathematics, including algebra, calculus, and beyond. They are used to model and solve real-world problems where variables exhibit a direct or inverse relationship. Always remember that simplifying a rational expression can simplify the process of solving equations that involve them.
Polynomial Division
When dividing polynomials, we can use either long division or synthetic division if the denominator is of first degree. Polynomial division is similar to long division with numbers. It involves dividing the terms of the polynomial in the numerator by the terms of the polynomial in the denominator, subtracting products, bringing down terms, and repeating until the terms in the numerator have all been divided.
However, in our exercise, since the degree of the numerator \(3 y^{2}+3 y+5\) is not higher than that of the denominator \(y^{2}+y+1\), the result can be expressed as the given fraction itself, which is a rational expression. Had the numerator been of a higher degree, we might have ended up with a quotient and possibly a remainder, which would be a separate term outside the fraction, adding a new layer of complexity to the simplification process.
However, in our exercise, since the degree of the numerator \(3 y^{2}+3 y+5\) is not higher than that of the denominator \(y^{2}+y+1\), the result can be expressed as the given fraction itself, which is a rational expression. Had the numerator been of a higher degree, we might have ended up with a quotient and possibly a remainder, which would be a separate term outside the fraction, adding a new layer of complexity to the simplification process.
Simplifying Algebraic Fractions
The process of simplifying algebraic fractions is very similar to simplifying numerical fractions. The goal is to reduce the fraction to its simplest form where no further factoring is possible, and no common factors exist between the numerator and the denominator. To do this, one should factor both the numerator and the denominator and cancel out any common factors.
In the given exercise, the step-by-step solution shows that the numerator and the denominator are already in their simplest form, with no common factors to cancel out. This means that \(\frac{3 y^{2}+3 y+5}{y^{2}+y+1}\) cannot be simplified further, and so the expression remains as is. Simplifying algebraic fractions is an essential skill that aids in solving equations and inequalities, as well as in various applications across different fields of algebra and calculus.
In the given exercise, the step-by-step solution shows that the numerator and the denominator are already in their simplest form, with no common factors to cancel out. This means that \(\frac{3 y^{2}+3 y+5}{y^{2}+y+1}\) cannot be simplified further, and so the expression remains as is. Simplifying algebraic fractions is an essential skill that aids in solving equations and inequalities, as well as in various applications across different fields of algebra and calculus.
Other exercises in this chapter
Problem 67
For the following problems, reduce each rational expression if possible. If not possible, state the answer in lowest terms. \(\frac{a}{a^{3}+a}\)
View solution Problem 68
For the following problems, perform the indicated operations. $$ (4 x+9)^{6} \div \frac{(4 x+9)^{2}}{(3 x+1)^{4}} $$
View solution Problem 68
For the following problems, solve each literal equation for the designated letter. \(F=\frac{S_{x}^{2}}{S_{y}^{2}}\) for \(S_{y}^{2}\).
View solution Problem 68
For the following problems, replace \(N\) with the proper quantity. $$ \frac{7 a}{5-a}=\frac{N}{a-5} $$
View solution