the non zero constants $\alpha ,\beta$ and $\gamma$ of the equation $r=\frac{\alpha }{\beta +\gamma \sin \theta }$.

The equation $r=\frac{\alpha }{\beta +\gamma \sin \theta }$ is not in the standard form of the polar equation

$r=\frac{eu}{1+e\sin \theta }$

Convert the equation to the standard form by dividing with $\beta$ in the numerator and in the denominator.

Then,

$r=\frac{\frac{\alpha }{\beta }}{\frac{\beta +\gamma \sin \theta }{\beta }}$ since dividing by $\beta$

$r=\frac{\frac{\alpha }{\beta }}{\frac{\beta }{\beta }+\frac{\gamma \sin \theta }{\beta }}$

$r=\frac{\frac{\alpha }{\beta }}{1+\frac{\gamma }{\beta }·\sin \theta }$

Now multiply and divide by $\gamma$ in the numerator to make it in the standard form.

$r=\frac{\frac{\gamma }{\gamma }·\frac{\alpha }{\beta }}{1+\frac{\gamma }{\beta }·\sin \theta }$

$r=\frac{\frac{\gamma }{\beta }·\frac{\alpha }{\gamma }}{1+\frac{\gamma }{\beta }·\sin \theta }$

The equation $r=\frac{\frac{\gamma }{\beta }·\frac{\alpha }{\gamma }}{1+\frac{\gamma }{\beta }·\sin \theta }$ is in the standard form.

Now compare the equation $r=\frac{\frac{\gamma }{\beta }·\frac{\alpha }{\gamma }}{1+\frac{\gamma }{\beta }·\sin \theta }$ with $r=\frac{eu}{1+e\sin \theta }$.

For the polar equation $r=\frac{\frac{\gamma }{\beta }·\frac{\alpha }{\gamma }}{1+\frac{\gamma }{\beta }·\sin \theta }$ the eccentricity is equals to $\frac{\gamma }{\beta }$ which is taken as positive .so eccentricity is $\left|\frac{\gamma }{\beta }\right|$ and the directrix is $y=\frac{\alpha }{\gamma }$.

Hence it is proved.