Answer:
b)
Step-by-step explanation:
A is invertible if and only if det(A)≠0. Let's compute the determinant of A and find the values k for which it is nonzero.
Using Sarrus's rule, we obtain that
[tex]\det A=0(k)(4)+1(-6)(2)+k(2)(7)-2(k)(k)-7(-6)(0)-4(2)(1)=-12+14k-2k^2-8=-2k^2+14k-20=-2(k^2-7k+10)=2(k-5)(k-2)[/tex]
Note that the determinant is a quadratic equation on k, which can be factored as above.
Now the determinant is only zero if k=5 or k=2 (the zeroes of the quadratic polynomial). Therefore, if k≠2,5 the determinant is nonzero so A is invertible.
Answer:
All real k except 2 and 5.
Step-by-step explanation:
For a matrix to be invertible the determinant of it should not be equal to zero.
A matrix P is invertible if |P| ≠ 0
The matrix given here is:
[tex]\left[\begin{array}{ccc}0&1&k\\2&k&-6\\2&7&4\end{array}\right][/tex]
For the above matrix to be invertible:
[tex]0\times(4k+42)-1\times(8+12)+k\times(14-2k)\neq 0\\-20+14k-2k^{2}\neq 0\\k^{2}-7k+10\neq 0\\(k-2)(k-5)\neq 0\\k\neq 2,k\neq 5[/tex]
Matrix is invertible for all real k except 2 and 5.
