This is the question:
$E$ is a point on the side $AB$ of a rectangle $ABCD$ such that $DE=6$ cm, $DA= 8cm$ and $DC=6cm$. If $CE$ extended meets the circumcircle of the rectangle at $F$, then what is the value of $BF$ ? (use $\sqrt{2}$=$1.414$).
Here is how I tried to solve it
In $\Delta BCD$, $\frac{CD}{BC} = \frac{DG}{BG}$ (Since CG is the Angle bisector of $\langle C$ )
From this, DG = $\frac{30}{7} cm$; BG= $\frac{40}{7} cm $
$\langle FCD $ = $\langle FAD$ = $\langle FBD$ = $45°$
Therefore, $\Delta CED$ ~ $\Delta AEF$ ; i.e. $\Delta AEF$ is a right isosceles triangle like $\Delta CED $
Hence, EF = AF = $\sqrt 2 cm $
In $\Delta CED $, CE = 6$\sqrt2$ cm
Now consider $\Delta CGD$ & $\Delta BGF $
$\Delta CGD$ ~ $\Delta BGF $
Assume the value of $GE = x$ $cm$
$\Delta GCD$ ~ $\Delta GBF$
$\frac {GC}{GB}$ = $\frac {CD}{BF}$ = $\frac {GD}{GF}$
$\frac {(6 \sqrt 2 -x)}{\frac{40}{7}}$ = $\frac {6}{BF}$ = $\frac {\frac{30}{7}}{(x+\sqrt 2)}$
$(x+\sqrt 2)(6 \sqrt 2 - x)$ = $\frac{30}{7}$ .$\frac{40}{7}$
My plan was to find the value of $x$ so that I could get the ratio and then evaluate $BF$. However, it looks like I am going wrong as I am getting complicated values for $x$. Could anyone please guide?
By law of sines for $\Delta CFB$ we obtain: $$BF=AC\cdot\sin45^{\circ}=\sqrt{6^2+8^2}\sin45^{\circ}=5\sqrt2.$$