QUESTION IMAGE
Question
which of the number(s) below are potential roots of the function?
(q(x) = 6x^3 + 19x^2 - 15x - 28)
(pm \frac{2}{3})
(pm \frac{7}{2})
(pm \frac{1}{7})
(pm 6)
(pm 14)
(pm \frac{3}{5})
🆕 New Concept Discovered: Rational Root Theorem
Finding possible rational solutions using factors of the first and last coefficients.
Step 1: Identify the leading coefficient and constant term
To find the potential rational roots of a polynomial function, we use the Rational Root Theorem. This theorem states that any potential rational root must be in the form:
\[ \pm \frac{p}{q} \]
where \( p \) is a factor of the constant term (the last number) and \( q \) is a factor of the leading coefficient (the coefficient of the highest power of \( x \)).
For the function \( q(x) = 6x^3 + 19x^2 - 15x - 28 \):
- The constant term is \( -28 \), so we look for factors of \( 28 \). Let's call these \( p \).
- The leading coefficient is \( 6 \), so we look for factors of \( 6 \). Let's call these \( q \).
Step 2: List the factors of each term
Find all integer factors for both numbers:
- Factors of the constant term \( 28 \) (\( p \)):
\[ p \in \{1, 2, 4, 7, 14, 28\} \]
- Factors of the leading coefficient \( 6 \) (\( q \)):
\[ q \in \{1, 2, 3, 6\} \]
Step 3: Test the given options
We construct potential roots by dividing any factor \( p \) by any factor \( q \):
\[ \text{Potential Roots} = \pm \frac{p}{q} \]
Let's check each of the given choices to see if they can be written in this form:
- \( \pm \frac{2}{3} \):
- Numerator \( 2 \) is a factor of \( 28 \) (\( p = 2 \)).
- Denominator \( 3 \) is a factor of \( 6 \) (\( q = 3 \)).
- This is a potential root.
- \( \pm \frac{7}{2} \):
- Numerator \( 7 \) is a factor of \( 28 \) (\( p = 7 \)).
- Denominator \( 2 \) is a factor of \( 6 \) (\( q = 2 \)).
- This is a potential root.
- \( \pm \frac{1}{7} \):
- Numerator \( 1 \) is a factor of \( 28 \) (\( p = 1 \)).
- Denominator \( 7 \) is not a factor of \( 6 \) (\( q
eq 7 \)).
- This is not a potential root.
- \( \pm 6 \) (which is \( \pm \frac{6}{1} \)):
- Numerator \( 6 \) is not a factor of \( 28 \) (\( p
eq 6 \)).
- This is not a potential root.
- \( \pm 14 \) (which is \( \pm \frac{14}{1} \)):
- Numerator \( 14 \) is a factor of \( 28 \) (\( p = 14 \)).
- Denominator \( 1 \) is a factor of \( 6 \) (\( q = 1 \)).
- This is a potential root.
- \( \pm \frac{3}{5} \):
- Numerator \( 3 \) is not a factor of \( 28 \) (\( p
eq 3 \)).
- Denominator \( 5 \) is not a factor of \( 6 \) (\( q
eq 5 \)).
- This is not a potential root.
Snap & solve any problem in the app
Get step-by-step solutions on Sovi AI
Photo-based solutions with guided steps
Explore more problems and detailed explanations
The potential roots of the function from the given choices are:
- \( \pm \frac{2}{3} \)
- \( \pm \frac{7}{2} \)
- \( \pm 14 \)