Two matrices A and B are given below: \[{\text{A}} = \left[ {\begin{array}{*{20}{c}} {\text{p}}&{\text{q}} \\ {\text{r}}&{\text{s}} \end{array}} \right]{\text{;}}\,{\text{B}} = \left[ {\begin{array}{*{20}{c}} {{{\text{p}}^2} + {{\text{q}}^2}}&{{\text{pr}} + {\text{qs}}} \\ {{\text{pr}} + {\text{qs}}}&{{{\text{r}}^2} + {{\text{s}}^2}} \end{array}} \right]\] If the rank of matrix A is N, then the rank of matrix B is A. \[\frac{{\text{N}}}{2}\] B. N – 1 C. N D. 2N

”[ rac{{ ext{N}}}{2}\
” option2=”N – 1″ option3=”N” option4=”2N” correct=”option1″]

The correct answer is $\boxed{\text{B. N – 1}}$.

The rank of a matrix is the number of linearly independent rows or columns in the matrix. The rank of a product of two matrices is always less than or equal to the minimum of the ranks of the two matrices.

In this case, the rank of matrix $A$ is $N$. This means that there are $N$ linearly independent rows in matrix $A$. The rank of matrix $B$ is therefore at most $N$.

To determine the rank of matrix $B$, we can use Gaussian elimination. We can first eliminate the first row of matrix $B$ by subtracting $\frac{r}{p}$ times the first row from the second row. This gives us the following matrix:

$$\left[\begin{array}{cc} {p^2 + q^2} & {pr + qs} \ {0} & {\frac{r^2 + s^2 – pr – qs}{p}} \end{array}\right]$$

We can then eliminate the second row of matrix $B$ by adding $\frac{r^2 + s^2 – pr – qs}{p(p^2 + q^2)}$ times the second row to the first row. This gives us the following matrix:

$$\left[\begin{array}{cc} {p^2 + q^2} & {0} \ {0} & {\frac{r^2 + s^2 – pr – qs}{p}} \end{array}\right]$$

Since the first row of matrix $B$ is now a multiple of the second row, the rank of matrix $B$ is $N – 1$.

Therefore, the rank of matrix $B$ is $\boxed{\text{N – 1}}$.