If the set of all , for which the roots of the equation are positive is , then is equal to _____
- A
- B
- C
- D
If the set of all , for which the roots of the equation are positive is , then is equal to _____
Correct answer:A
Standard Method
Given: The quadratic equation is
and both its roots are positive.
Find: The value of if the set of all such is .
For a quadratic to have both roots positive, we need:
Here,
From the product condition,
Since , this gives
So,
Now check the sum condition:
Because , we have . Hence for the fraction to be positive, we need
which means
This is already satisfied whenever . So no new restriction is added.
Now apply the discriminant condition:
Therefore,
a \in (-\infty,-3] \cup [0,\infty) $$](streamdown:incomplete-link)Combining with , we get
Thus,
\alpha = 3, \qquad \beta = 0, \qquad \gamma = 1 $$](streamdown:incomplete-link)Now compute:
Therefore, the correct option is A.
Using sum, product, and discriminant conditions
Given: The equation is
with both roots positive.
Find: The value of .
If roots are positive, then their product must be positive:
which immediately gives
The sum of roots is
For , the denominator is negative. So positivity of the sum requires the numerator to be negative too, which gives
This is automatically true under .
Now require real roots:
Hence,
Intersecting with gives
So the interval form matches
with the endpoint excluded already by . Hence,
Therefore,
So the correct option is A.
Using only the discriminant condition is incorrect because real roots do not guarantee positive roots. After checking , also apply the sum and product conditions for positivity.
Forgetting the product condition leads to missing the restriction . This condition is essential because both positive roots must have positive product.
Treating as incompatible with the given form is a mistake. Since the question already states , the endpoint is implicitly excluded.](streamdown:incomplete-link)
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