The real numbers y and k are such that $y = \sec 2x = k ^ 2 - 3k + 1$. Thus, $k$ can take all values of:
Answer: $[ \frac{7}{2}; 4 ]$
Why wouldn't it be $[2; 3]$ ? The intervals of $k$ would be $k\leq 0$ and $k \geq 1$
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$\sec2x\in (- \infty, -1]\cup[1, \infty)$
Therefore, $y\geq1$, or $y≤-1$
For $k^2-3k+1\geq1$, $k^2-3k\geq0$ or $k\in(- \infty, 0]\cup[3, \infty)$.
For $k^2-3k+1≤-1$, $k^2-3k+2\leq0$ or $k∈[1,2]$.
$\therefore$ The range of values of k is $k\in(- \infty, 0]\cup [1,2]\cup[3, \infty)$
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$\begingroup$ Does this match the answer to the question? $\endgroup$ Sep 13, 2021 at 12:24
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1$\begingroup$ @Behemooth It does. $[7/2;4]\subset [3;\infty).$ $\endgroup$– CiaPanSep 13, 2021 at 12:55