Let the length of the latus rectum of an ellipse be . If its eccentricity is the maximum value of the function , then is equal to
- A
- B
- C
- D
Let the length of the latus rectum of an ellipse be . If its eccentricity is the maximum value of the function , then is equal to
Correct answer:D
Standard Method
Given: The ellipse is with , the length of its latus rectum is , and its eccentricity equals the maximum value of .
Find: The value of .
First, find the maximum value of the quadratic function.
For a quadratic opening downward, the maximum occurs at
Hence,
Therefore, the eccentricity is
Now use the latus rectum formula for the ellipse:
So,
Using the eccentricity relation for an ellipse,
Substitute and :
Thus,
Now compute :
Therefore,
So, the correct option is D.
Using vertex form of the quadratic
Given: and the eccentricity equals its maximum value.
Find: for the ellipse.
Rewrite the function in vertex form:
Since , the maximum value is . Hence,
For the ellipse,
and
Substituting gives
Now replace by :
So,
which gives
Then,
Hence,
Therefore, the answer is .
Taking the maximum value of incorrectly. A common error is to substitute a wrong vertex formula or sign for the quadratic coefficient. Since the coefficient of is negative, the parabola opens downward and the vertex gives the maximum value.
Using the wrong latus rectum formula. For the ellipse with major axis along the -axis, the length of the latus rectum is , not .
Confusing with after getting . The correct rearrangement is . Replacing it by leads to an incorrect eccentricity equation.
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