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Apply the properties of integer exponents to generate an equivalent expression to (7^-3)^7 x 7^20/6^-2 with only positive expon...Asked by Denki
Apply the Properties of Integer Exponents to generate equivalent expressions to (7^−3)^7 ⋅ 7^20/6^−2 with only positive exponents, then solve the expression. Provide the answer as an improper fraction.(1 point)
Answers
Answered by
Denki
Simplify the expression (4x^3)^2 using the properties of integer exponents.(1 point)
16x^6
16 x superscript 6 baseline
16x^5
16 x superscript 5 baseline
4x^6
4 x superscript 6 baseline
8x^6
16x^6
16 x superscript 6 baseline
16x^5
16 x superscript 5 baseline
4x^6
4 x superscript 6 baseline
8x^6
Answered by
Denki
Apply the properties of integer exponents to generate an equivalent algebraic expression to (4x^4y^−4)^3/(x^7y^3)^2 .(1 point)
Responses
x^2y^18/64
Start Fraction x squared y superscript 18 baseline over 64 End Fraction
4/x^2y^18
Start Fraction 4 over x squared y superscript 18 baseline End Fraction
64/x^20
Start Fraction 64 over x superscript 20 baseline End Fraction
64/x^2y^18
Responses
x^2y^18/64
Start Fraction x squared y superscript 18 baseline over 64 End Fraction
4/x^2y^18
Start Fraction 4 over x squared y superscript 18 baseline End Fraction
64/x^20
Start Fraction 64 over x superscript 20 baseline End Fraction
64/x^2y^18
Answered by
Denki
which option?
Answered by
Denki
Thank you
Answered by
Denki
Apply the product rule of integer exponents to find the numerical equivalent of 12^−5⋅12^7 . Show your work and explain how you used the product rule of integer exponents.
Answered by
GPT 3.5
To simplify the expression and apply the properties of integer exponents, we start by raising the base of the first term, 7, to the power outside the parentheses, which is -3 for a negative exponent:
(7^(-3))^7 = 7^(-3*7) = 7^(-21)
Then, we can multiply this expression by the second term, 7^20, using the property of multiplying exponents with the same base:
7^(-21) * 7^20 = 7^(-21+20) = 7^(-1)
Finally, we can divide this expression by 6^(-2) by using the property of dividing exponents with the same base:
7^(-1) / 6^(-2) = 7^(-1) * 6^2 = 7^(-1) * 36 = 36/7
So the simplified expression is 36/7, which can be written as an improper fraction.
(7^(-3))^7 = 7^(-3*7) = 7^(-21)
Then, we can multiply this expression by the second term, 7^20, using the property of multiplying exponents with the same base:
7^(-21) * 7^20 = 7^(-21+20) = 7^(-1)
Finally, we can divide this expression by 6^(-2) by using the property of dividing exponents with the same base:
7^(-1) / 6^(-2) = 7^(-1) * 6^2 = 7^(-1) * 36 = 36/7
So the simplified expression is 36/7, which can be written as an improper fraction.
Answered by
GPT 3.5
The expression (4x^3)^2 can be simplified using the property of raising a power to a power, which states that (a^m)^n = a^(m*n). In this case, a is 4x^3, m is 2, and n is 1.
So, applying the property:
(4x^3)^2 = 4^(2*1) * (x^3)^(2*1) = 4^2 * x^(3*2) = 16 * x^6
Therefore, the simplified expression is 16x^6.
So, applying the property:
(4x^3)^2 = 4^(2*1) * (x^3)^(2*1) = 4^2 * x^(3*2) = 16 * x^6
Therefore, the simplified expression is 16x^6.
Answered by
GPT 3.5
To generate an equivalent algebraic expression to (4x^4y^−4)^3/(x^7y^3)^2, we can apply the properties of integer exponents.
First, we raise each term within the parentheses to the power outside of it:
(4x^4y^−4)^3 = 4^3 * (x^4)^3 * (y^−4)^3 = 64x^12y^−12
(x^7y^3)^2 = (x^7)^2 * (y^3)^2 = x^14y^6
Next, we divide the two expressions using the property of dividing exponents with the same base:
(64x^12y^−12)/(x^14y^6) = 64/(x^14/x^12) * (x^12/y^6)/(y^12/y^6)
Simplifying further, we get:
64 * x^(12-14) * (x^12/y^6) * (y^6/y^12) = 64 * x^(-2) * (x^12/y^6) * (1/y^6)
Combining like terms and simplifying, we have:
64 * (x^12 * x^(-2))/(y^6 * y^6) = 64 * x^10/y^12
Therefore, the equivalent algebraic expression is 64x^10/y^12.
First, we raise each term within the parentheses to the power outside of it:
(4x^4y^−4)^3 = 4^3 * (x^4)^3 * (y^−4)^3 = 64x^12y^−12
(x^7y^3)^2 = (x^7)^2 * (y^3)^2 = x^14y^6
Next, we divide the two expressions using the property of dividing exponents with the same base:
(64x^12y^−12)/(x^14y^6) = 64/(x^14/x^12) * (x^12/y^6)/(y^12/y^6)
Simplifying further, we get:
64 * x^(12-14) * (x^12/y^6) * (y^6/y^12) = 64 * x^(-2) * (x^12/y^6) * (1/y^6)
Combining like terms and simplifying, we have:
64 * (x^12 * x^(-2))/(y^6 * y^6) = 64 * x^10/y^12
Therefore, the equivalent algebraic expression is 64x^10/y^12.
Answered by
GPT 3.5
I apologize for the confusion. The correct equivalent algebraic expression is 64/x^2y^18.
Answered by
GPT 3.5
You're welcome! If you have any more questions, feel free to ask.
Answered by
GPT 3.5
The product rule of integer exponents states that when multiplying two numbers with the same base, you add their exponents.
To find the numerical equivalent of 12^(-5) * 12^7, we can apply this rule.
We start by multiplying the base, which is 12, and then add the exponents -5 and 7:
12^(-5) * 12^7 = 12^(-5 + 7)
Simplifying the exponent, we have:
12^2 = 144
Therefore, the numerical equivalent of 12^(-5) * 12^7 is 144.
To find the numerical equivalent of 12^(-5) * 12^7, we can apply this rule.
We start by multiplying the base, which is 12, and then add the exponents -5 and 7:
12^(-5) * 12^7 = 12^(-5 + 7)
Simplifying the exponent, we have:
12^2 = 144
Therefore, the numerical equivalent of 12^(-5) * 12^7 is 144.