You correctly applied the definition of the "xy-plane" in your first approach, but not in the second. A point (x,y,z) is on the xy-plane if and only if z = 0. As such, our system of ...

Hint: The Frobenius norm of an m \times n matrix A is defined as the square root of the sum of the absolute squares of its elements. Example: Consider matrix A = \left( \begin{array}{ccc} ~~~~1 & -2 & ~~~~~~3 \\ -4 & ~~5 & ~-6 \\ ~~~7 & -8 & ~~~~~~9 \\ \end{array} \right) ...

Since both the equations have infinite solutions, they must coincide with each other This gives: \frac{k}{a} = \frac{a}{k} = \frac{5}{k} Considering the equation \frac{a}{k} = \frac{5}{k} ...

This is more general. By definition, \|T\| = \sup_{x \ne 0} \|Tx\|/\|x\| = \sup_{\|x\|=1} \|Tx\| But for any z in the Hilbert space there is y with \|y \| = 1 such that \langle z, y \rangle = \|z\| ...

Suppose z = w this will maximize zw (relative to xy) z = w = \frac {x+y}{2} zw = \frac {x^2 + y^2 + 2xy}{4} = 2xy\\ x^2 + y^2 - 6xy = 0 divide through by y (\frac {x}{y})^2 - 6\frac {x}{y} + 1 = 0 ...

Don't multiply equations by 2: as 2 is not coprime to 8 you're not getting equivalent equations. One way: given: \begin{align}3x+7y\equiv 2 \pmod 8\\4x+5y\equiv 7\pmod 8\end{align} Take away ...