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Use multiplication to find the product that demonstrates the Closure Property of multiplication of polynomials. (12x2−3)(4y3+5x...Asked by grann
Use multiplication to find the product that demonstrates the Closure Property of multiplication of polynomials. (12x2−3)(4y3+5x2) (1 point) Responses x2y3+5x4−8y3−15x2 x squared y cubed plus Start Fraction 5 over x superscript 4 baseline End Fraction minus 8 y cubed minus 15 x squared 52x2y3+2x4−8y3+15x2 Start Fraction 5 over 2 End Fraction x squared y cubed plus 2 x superscript 4 baseline minus 8 y cubed plus 15 x squared x2−−√y3+4x4−15x2 Start Root x squared End Root y cubed plus 4 x superscript 4 baseline minus 15 x squared 2x2y3+52x4−12y3−15x2
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Answered by
grann
which answer is it
Answered by
GPT-4o mini
To demonstrate the Closure Property of multiplication in polynomials, we will multiply the two given polynomials \( (12x^2 - 3) \) and \( (4y^3 + 5x^2) \).
Using the distributive property (also known as the FOIL method for binomials), we can find the product:
1. Distributing \( 12x^2 \):
- \( 12x^2 \cdot 4y^3 = 48x^2y^3 \)
- \( 12x^2 \cdot 5x^2 = 60x^4 \)
2. Distributing \( -3 \):
- \( -3 \cdot 4y^3 = -12y^3 \)
- \( -3 \cdot 5x^2 = -15x^2 \)
Now, combining all these results together:
\[
48x^2y^3 + 60x^4 - 12y^3 - 15x^2
\]
Now, if we rearrange this, we have:
\[
60x^4 + 48x^2y^3 - 12y^3 - 15x^2
\]
As we see, the product \( (12x^2 - 3)(4y^3 + 5x^2) \) results in a polynomial, and therefore we demonstrate that the multiplication of two polynomials results in a polynomial, validating the Closure Property.
Thus, the result we obtained which shows the Closure Property is:
\[
60x^4 + 48x^2y^3 - 12y^3 - 15x^2
\]
Among the options you provided, while this exact expression may not be listed, the essence of the multiplication showcases that the resultant expression remains a polynomial, affirming the Closure Property.
Using the distributive property (also known as the FOIL method for binomials), we can find the product:
1. Distributing \( 12x^2 \):
- \( 12x^2 \cdot 4y^3 = 48x^2y^3 \)
- \( 12x^2 \cdot 5x^2 = 60x^4 \)
2. Distributing \( -3 \):
- \( -3 \cdot 4y^3 = -12y^3 \)
- \( -3 \cdot 5x^2 = -15x^2 \)
Now, combining all these results together:
\[
48x^2y^3 + 60x^4 - 12y^3 - 15x^2
\]
Now, if we rearrange this, we have:
\[
60x^4 + 48x^2y^3 - 12y^3 - 15x^2
\]
As we see, the product \( (12x^2 - 3)(4y^3 + 5x^2) \) results in a polynomial, and therefore we demonstrate that the multiplication of two polynomials results in a polynomial, validating the Closure Property.
Thus, the result we obtained which shows the Closure Property is:
\[
60x^4 + 48x^2y^3 - 12y^3 - 15x^2
\]
Among the options you provided, while this exact expression may not be listed, the essence of the multiplication showcases that the resultant expression remains a polynomial, affirming the Closure Property.
Answered by
GPT-4o mini
Let's examine the options you provided again in light of the correct product derived from multiplying the polynomials:
When we multiplied \( (12x^2 - 3) \) and \( (4y^3 + 5x^2) \), we found the product to be:
\[
60x^4 + 48x^2y^3 - 12y^3 - 15x^2
\]
Now, let's compare this with the choices provided:
1. \( x^2y^3 + \frac{5}{x^4} - 8y^3 - 15x^2 \)
2. \( \frac{5}{2} x^2y^3 + 2x^4 - 8y^3 + 15x^2 \)
3. \( \sqrt{x^2}y^3 + 4x^4 - 15x^2 \)
4. \( 2x^2y^3 + 52x^4 - 12y^3 - 15x^2 \)
None of the answers match the correct product \( 60x^4 + 48x^2y^3 - 12y^3 - 15x^2 \) exactly, but let's approximate and analyze which one aligns closest based on coefficients:
- **Option 1** contains a fractional term and incorrect coefficients.
- **Option 2** also contains fractions and does not match coefficients.
- **Option 3** has a radical and does not correlate.
- **Option 4** has the term \( 2x^2y^3 \) and an inappropriate coefficient for \( x^4 \) but the structure resembles polynomial multiplication.
However, the best candidate seems to be **Option 4**. It is likely intended to represent a sum of terms which is also a polynomial.
Thus, while it does not provide an exact match, based on polynomial behavior, it appears that the closest or intended answer to demonstrate closure would be:
**2x²y³ + 52x⁴ - 12y³ - 15x²**
If my earlier calculations were intended to align more clearly with one of your options, please provide explicit variable powers or any other details that might impact the choice!
When we multiplied \( (12x^2 - 3) \) and \( (4y^3 + 5x^2) \), we found the product to be:
\[
60x^4 + 48x^2y^3 - 12y^3 - 15x^2
\]
Now, let's compare this with the choices provided:
1. \( x^2y^3 + \frac{5}{x^4} - 8y^3 - 15x^2 \)
2. \( \frac{5}{2} x^2y^3 + 2x^4 - 8y^3 + 15x^2 \)
3. \( \sqrt{x^2}y^3 + 4x^4 - 15x^2 \)
4. \( 2x^2y^3 + 52x^4 - 12y^3 - 15x^2 \)
None of the answers match the correct product \( 60x^4 + 48x^2y^3 - 12y^3 - 15x^2 \) exactly, but let's approximate and analyze which one aligns closest based on coefficients:
- **Option 1** contains a fractional term and incorrect coefficients.
- **Option 2** also contains fractions and does not match coefficients.
- **Option 3** has a radical and does not correlate.
- **Option 4** has the term \( 2x^2y^3 \) and an inappropriate coefficient for \( x^4 \) but the structure resembles polynomial multiplication.
However, the best candidate seems to be **Option 4**. It is likely intended to represent a sum of terms which is also a polynomial.
Thus, while it does not provide an exact match, based on polynomial behavior, it appears that the closest or intended answer to demonstrate closure would be:
**2x²y³ + 52x⁴ - 12y³ - 15x²**
If my earlier calculations were intended to align more clearly with one of your options, please provide explicit variable powers or any other details that might impact the choice!
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