I am looking at the Hopf-fibration and I am looking at the preimage of the equator in $\mathbb{S}^2$. I think that I have proved that this is just the flat torus and now I want to calculate the principal curvatures of this torus. My general approach to the problem has been:
I consider $\mathbb{R}^4$ as $\mathbb{C}^2$ and $\mathbb{S}^3$ to be "the unit circle" in this "plane", every point on the circle determines a line through the origion. And the lines through the origion intersects the sphere in a unique circle. Mapping $\mathbb{S^3}$ to the space of lines through the origion gives me an onto map to $\mathbb{C}\mathbb{P}^1$ which I diffeomorphically identify with $\mathbb{S}^2$. The preimage of any point $(z_1:z_2)$ in $\mathbb{S}^3$ is just the circle $\frac{z_1}{z_2}=z$. Hence the preimage of the equator is all circles satisfying $\frac{|z_1|}{|z_2|}=1$, i.e $|z_1|=|z_2|$, hence the preimage is a product of two circles, i.e a torus.
Since my torus is just $S^1\times S^1$ in $\mathbb{C}\times \mathbb{C}$ it is equipped with the product metric, and hence in this case flat.
I am now stuck, here is two ways I would like to go forward:
Calculating the Weingarten map. Using the parametrization $(e^{i\theta },e^{i\psi })$, what is the normal direction inside of $\mathbb{S}^3$?
I have also tried to look at the normal curvature of curves in $S^1\times S^1$ are these just "circles wrapping around the torus" the smaller ones curving more then the bigger? This way of thinking would give me principal curvature $1$ and something depending on where on the torus I am being $-1$ in "the inner circle"?