Four points lie on a circle for :
- A
- B
- C
- D
Four points lie on a circle for :
Correct answer:C
Standard Method
Given: The points $$ (2k,3k), (1,0), (0,1), (0,0)
Find: The value of .
The points determine a unique circle. Using the circle with diameter joining and $$ (0,1)
(x-1)x + (y-1)y = 0
x^2 + y^2 - x - y = 0
Now substitute the point $$ (2k,3k)
(2k)^2 + (3k)^2 - 2k - 3k = 0
4k^2 + 9k^2 - 5k = 0
13k^2 - 5k = 0
k(13k-5) = 0
So the possible values are
Since makes the point , it is not a distinct fourth point. Hence the valid value is $$ \frac{5}{13}
Therefore, the correct option is C.
Using concyclic determinant condition
Given: The points $$ (2k,3k), (1,0), (0,1), (0,0)
Find: The value of .
A standard concyclicity test is
The first approach in the source shows this method but contains an arithmetic inconsistency in the working.
The reliable simplification comes from first finding the circle through and then checking whether $$ (2k,3k)
x^2 + y^2 - x - y = 0
13k^2 - 5k = 0
k = 0 nd nd k = \frac{5}{13}
Discarding because it repeats the point , we get the required value . The source solution's final conclusion also states $$ \frac{5}{13}
Therefore, the correct option is C.
Using the wrong circle equation. The three fixed points lie on the circle , not on an arbitrary incorrectly simplified form. First determine the circle through the known three points, then substitute $$ (2k,3k)
Accepting without checking distinctness. If , then $$ (2k,3k)=(0,0)
Trusting a faulty intermediate determinant expansion. The source's first approach shows an arithmetic mismatch before jumping to the final answer. When determinant algebra becomes messy, verify the result by the simpler circle-equation method.
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