\displaystyle{\left|\begin{array}{ccc} {4}&{1}&{0}\\{5}&-{15}&-{1}\\-{2}&{10}&{7}\end{array}\right|}=-{413} Explanation: Expanding using row1 we have; \displaystyle{\left|\begin{array}{ccc} {4}&{1}&{0}\\{5}&-{15}&-{1}\\-{2}&{10}&{7}\end{array}\right|}={\left({4}\right)}{\left|\begin{array}{cc} -{15}&-{1}\\{10}&{7}\end{array}\right|}-{\left({1}\right)}{\left|\begin{array}{cc} {5}&-{1}\\-{2}&{7}\end{array}\right|}+{\left({0}\right)}{\left|\begin{array}{cc} {5}&-{15}\\-{2}&{10}\end{array}\right|} ...

The answer is \displaystyle=-{3183} Explanation: The determination of the determinant is as follows . \displaystyle{\left|\begin{array}{ccc} {25}&{36}&{15}\\{31}&-{12}&-{2}\\{17}&{15}&{9}\end{array}\right|} ...

\displaystyle{\left|\begin{array}{ccc} {2}&-{1}&{3}\\{3}&{0}&-{2}\\{1}&-{3}&{0}\end{array}\right|}=-{37} Explanation: If you take the determinant of a \displaystyle{3}\times{3} matrix \displaystyle{\left|\begin{array}{ccc} {a}&{b}&{c}\\{f}&{g}&{h}\\{x}&{y}&{z}\end{array}\right|} ...

\displaystyle{\left|\begin{array}{ccc} {8}&{9}&{3}\\{3}&{5}&{7}\\-{1}&{2}&{4}\end{array}\right|}=-{90} Explanation: \displaystyle{\left|\begin{array}{ccc} {8}&{9}&{3}\\{3}&{5}&{7}\\-{1}&{2}&{4}\end{array}\right|}={8}{\left|\begin{array}{cc} {5}&{7}\\{2}&{4}\end{array}\right|}-{9}{\left|\begin{array}{cc} {3}&{7}\\-{1}&{4}\end{array}\right|}+{3}{\left|\begin{array}{cc} {3}&{5}\\-{1}&{2}\end{array}\right|}= ...

\displaystyle{\left|{\begin{array}{ccc} {6}&{3}&-{1}\\{0}&{3}&{3}\\-{9}&{0}&{0}\end{array}}\right|}=-{108} Explanation: I will use a couple of properties of the determinant: The determinant is ...

Four times the first row is (4,16,4). -2 times the second row is (-4,2,0). Adding these up gives the third row (0,18,4). Hence, the rows of the given matrix have the relation 4R_1 -2R_2 - R_3 = 0 ...