Let and . Then is equal to:
- A
- B
- C
- D
Let and . Then is equal to:
Correct answer:D
Standard Method
Given:
Find:
For set , factor the given equation:
Since , we get
The solution states that the right-hand side is negative and lies outside the range of . Therefore, there is no solution in . Hence,
For set , the domain requires
Let
Then the equation becomes
So,
Squaring both sides,
Rearranging,
the solution states that this quartic gives four distinct solutions for in set . Thus,
Therefore,
So, the correct option is D.
Using the provided set-wise analysis
Given: the two sets and as defined in the question.
Find: the number of distinct elements in .
The hint suggests solving each set separately and then counting the unique solutions in their union.
For , first simplify the trigonometric equation by taking out the common factor:
This gives
The solution notes that the obtained value is not attainable by , because that expression can vary only within
Therefore has no element.
For , use the substitution
with the domain coming from the radicals. Then rewrite the equation as
which becomes
Now square:
Hence,
According to the provided solution, this leads to four distinct admissible values of in set .
Thus,
Therefore, the correct option is D.
Assuming can take any real value. This is wrong because its range is bounded by . Always check the range of a trigonometric expression before solving.
Ignoring the domain restriction in set . This is wrong because requires . Always impose the radical domain before introducing substitutions.
Squaring the transformed equation for without tracking admissible roots. This is risky because squaring can introduce extraneous solutions. After solving, verify that the obtained values satisfy the original radical equation.
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