Let be the largest open interval in which the function is strictly increasing, and be the largest open interval, in which the function is strictly decreasing. Then is equal to:
- A
- B
- C
- D
Let be the largest open interval in which the function is strictly increasing, and be the largest open interval, in which the function is strictly decreasing. Then is equal to:
Correct answer:C
Standard Method
Given: and .
Find: .
From the solution, for to be strictly increasing, we use .
Since is the largest open interval of increase, the endpoint condition is taken from the derivative expression shown in the solution. This gives the required value of .
For to be strictly decreasing, we use .
Factoring,
Then the interval is obtained by analyzing where .
The solution concludes that
Therefore, the correct option is C.
Extracted Working and Discrepancy Note
Given: and .
Find: .
The extracted solution shows:
and states that is strictly increasing when .
It also shows:
which is factored as
and simplified to
The page then claims values for , , and , but the intermediate numerical conclusion written there is inconsistent with the final boxed answer. Specifically, it writes a substituted value giving , while the same solution block and the solution both conclude the correct option is C and the final answer is .
Using the solution, the accepted answer is , so the correct option is C.
Differentiating incorrectly as . This ignores the shift inside the logarithm. Use the chain rule so that the derivative is .
Analyzing monotonicity of from itself instead of from . A function is strictly decreasing on intervals where its derivative is negative, so sign analysis must be done on .
Forgetting that and treating it as a sign-changing factor. Since it is a square, it does not change sign except becoming zero at . The sign of must be determined from the remaining linear factors.
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