\displaystyle{A}-{B}={\left(\begin{array}{cc} -{7}&{x}-{6}\\{2}{y}+{3}&-{1}\end{array}\right)} Explanation: In a matrix problem like this, all you have to do is subtract each element of \displaystyle{B} ...

What you do is correct. I just suggest you to use other letters for the coordinates of the plane that you are looking for. For example you can write your equation as ax+by+cz=0. You found two ...

When you got that the x-intercept of the line is 3, it already means that when x=3, y=z=0. So your '?' in (3, ?,?) are both 0. For another part, you got the direction ratios to be (0,b,b). ...

Write the equation as : \frac{dx}{dv}=\frac{v}{F(x)} Then integrating, you get v^2(x)/2=\int_0^x F(p)dp Hence, for every value of x, you have a +v and -v value of v(x). Hence there is symmetry ...

Your guess is correct. From z=x+iy and f(z)=u(z)+iv(z), we form the vector function F(x,y) = {u(z) \choose v(z)} = {\Re f(x+iy) \choose \Im f(x+iy} from R^2 to R^2. Now use the chain rule.

You have the following linear program (LP) \begin{array}{ll} \text{minimize} & x_1 + x_2 + x_3 + x_4\\ \text{subject to} & 0.2 x_1 + 0.3 x_2 + 0.9 x_3 + 0.5 x_4 \geq 1\\ & 0.1 x_1 + 0.4 x_2 + 0.3 x_3 + 0.9 x_4 \geq 1\\ & 0.2 x_1 + 0.3 x_2 + 0.3 x_3 + 0.4 x_4 \geq 1\\ & 0.4 x_1 + 0.9 x_2 + 0.1 x_3 + 0.9 x_4 \geq 1\\ & 0.2 x_1 + 0.3 x_2 + 0.9 x_3 + 0.9 x_4 \geq 1\\ & 0.2 x_1 + 0.3 x_2 + 0.6 x_3 + 0.1 x_4 \geq 1\\ & 0.2 x_1 + 0.3 x_2 + 0.9 x_3 + 0.9 x_4 \geq 1\\ & 0.2 x_1 + 0.4 x_2 + 0.9 x_3 + 0.2 x_4 \geq 1\\ & 0.6 x_1 + 0.4 x_2 + 0.1 x_3 + 0.9 x_4 \geq 1\\ & 0.2 x_1 + 0.7 x_2 + 0.9 x_3 + 0.9 x_4 \geq 1\\ & 0.2 x_1 + 0.3 x_2 + 0.5 x_3 + 0.6 x_4 \geq 1\\ & x_1, x_2, x_3, x_4 \geq 0\end{array} ...