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Marshall is comparing the growth rates of f(x)=6(1.5)^x and g(x)=5x+10 using this graph. Based on the graph, he concludes that...Question
Marshall is comparing the growth rates of f(x)=6(1.5)x
and g(x)=5x+10
using this graph. Based on the graph, he concludes that the growth rate of g(x)=5x+10
is always greater than the growth rate of f(x)=6(1.5)x
. Where is his mistake?
(1 point)
Responses
Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f(x)=6(1.5)x
eventually surpasses the growth rate of g(x)=5x+10
for negative values of x.
Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f of x is equal to 6 times 1 point 5 to the x th power eventually surpasses the growth rate of g of x is equal to 5 x plus 10 for negative values of x.
The growth rate of g(x)=5x+10
is only greater than the growth rate of f(x)=6(1.5)x
when x is greater than approximatel -1.3
The growth rate of g of x is equal to 5 x plus 10 is only greater than the growth rate of f of x is equal to 6 times 1 point 5 to the x th power when x is greater than approximatel -1.3
Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f(x)=6(1.5)x
eventually surpasses the growth rate of g(x)=5x+10
for large values of x.
Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f of x is equal to 6 times 1 point 5 to the x th power eventually surpasses the growth rate of g of x is equal to 5 x plus 10 for large values of x.
Marshall is backward. The growth rate of f(x)=6(1.5)x
is always greater than the growth rate of g(x)=5x+10
and g(x)=5x+10
using this graph. Based on the graph, he concludes that the growth rate of g(x)=5x+10
is always greater than the growth rate of f(x)=6(1.5)x
. Where is his mistake?
(1 point)
Responses
Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f(x)=6(1.5)x
eventually surpasses the growth rate of g(x)=5x+10
for negative values of x.
Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f of x is equal to 6 times 1 point 5 to the x th power eventually surpasses the growth rate of g of x is equal to 5 x plus 10 for negative values of x.
The growth rate of g(x)=5x+10
is only greater than the growth rate of f(x)=6(1.5)x
when x is greater than approximatel -1.3
The growth rate of g of x is equal to 5 x plus 10 is only greater than the growth rate of f of x is equal to 6 times 1 point 5 to the x th power when x is greater than approximatel -1.3
Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f(x)=6(1.5)x
eventually surpasses the growth rate of g(x)=5x+10
for large values of x.
Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f of x is equal to 6 times 1 point 5 to the x th power eventually surpasses the growth rate of g of x is equal to 5 x plus 10 for large values of x.
Marshall is backward. The growth rate of f(x)=6(1.5)x
is always greater than the growth rate of g(x)=5x+10
Answers
There are no human answers yet.
Answered by
GPT-4o mini
Marshall's mistake is that he is only considering a small portion of the domains of the functions. Specifically, the correct response is:
**Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f(x)=6(1.5)x eventually surpasses the growth rate of g(x)=5x+10 for large values of x.**
This reflects the fact that while \( g(x) \) is a linear function and grows at a constant rate, the exponential function \( f(x) = 6(1.5)^x \) will eventually grow faster than the linear function as \( x \) becomes larger.
**Marshall is only considering a small portion of the domains of the functions. If he went farther to the right on the graph, he would observe that the growth rate of f(x)=6(1.5)x eventually surpasses the growth rate of g(x)=5x+10 for large values of x.**
This reflects the fact that while \( g(x) \) is a linear function and grows at a constant rate, the exponential function \( f(x) = 6(1.5)^x \) will eventually grow faster than the linear function as \( x \) becomes larger.
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