## Caustic curves and dual curves

Hello,
I'm investigating duality for plane curves, and I came across an 'original' interpretation of the Biduality theorem , that uses the notion of caustic curve. Because everything is still very obscure to me, I try to share the whole with you, in the hope that we can help to fix ideas.
Meanwhile, some definitions to introduce the argument:

Definition: Let $$\mathbb{P}^*$$ the projective plane dual of $$\mathbb{P}^2 (\mathbb{C})$$: every line of $$\mathbb{P}^2 (\mathbb{C})$$ identifies a point of $$\mathbb{P}^*$$ and, conversely, every line of$$\mathbb{P}^*$$ corresponds to a point of $$\mathbb{P}^2 (\mathbb{C})$$. Given a curve $$C \subset \mathbb{P}^2 (\mathbb {C})$$, we consider the totality of the tangents to $$C$$: it is a new curve in $$\mathbb{P}^*$$, the so-called dual curve $$C^*$$.

Biduality Theorem: For any projective curve $$C \subset \mathbb{P}^2 (\mathbb {C})$$ we have $$(C^*)^* = C$$. Moreover, if $$p$$ is a simple point of $$C$$ and $$h$$ is a simple point of $$C^*$$, then $$h$$ is tangent to $$C$$ in $$p$$ if and only if $$p$$, considered as a straight line in $$\mathbb{P}^*$$ is tangent to $$C^*$$ in $$h$$.

Now, from the book Discriminants, Resultants, and Multidimensional Determinants ( here the link to the page I quote ), reported verbatim:

To give an intuitive sense of Biduality Theorem in $$C \subset {\mathbb{P}^2} (\mathbb {C})$$, we express the notion of tangency in the dual projective plane $$\mathbb{P}^*$$ in terms of the original plane $$\mathbb{P}^2(\mathbb{C})$$. By definition, a tangent to a curve at some point is the line that contains this point and that is infinitely close to the curve near this point.
In our situation, a point of $$\mathbb {P}^*$$ is a line $$l \subset \mathbb{P}^2$$. A curve $$C$$ in $$\mathbb{P}^*$$ is a 1-parameter family of lines in $$C \subset \mathbb {P}^2 (\mathbb{C})$$. A line in $$\mathbb{P}^*$$ is a pencil $$P^*$$ of all the lines in $$C \subset \mathbb{P}^2 (\mathbb{C})$$ for a given point $$P$$ to $$C \subset \mathbb{P}^2 (\mathbb{C})$$. The condition that $$P^*$$ is tangent to $$C$$ in $$l$$ means that the line $$l$$ is a member of the family $$C$$, a point $$P$$ lies on $$l$$ and other lines of $$C$$ in the vicinity of $$l$$ are infinitely close to the pencil $$P^*$$. This is usually expressed by saying that $$P$$ is a caustic point for the family of lines $$C$$.
One can imagine that a beam of light of a certain intensity is coming along each line of $$C$$. Then the total brightness of the incoming light in an arbitrary small neighborhood of a caustic point $$P$$ is infinite, although there is only a ray (line of $$C$$) that meets the point [ tex] P [/tex] itself. The set of all caustic points of the family of lines is usually called the [b] caustic curve [/ b] of $$C$$. This is nothing but the dual projective curve $$C^* \subset \mathbb{P}^2$$.
Then the Biduality theorem states that any curve is the caustic of the family of its tangent lines (envelope of tangents). This is intuitively obvious.
The "dual" form of this theorem is less obvious: it means that every 1-parameter family in $$C$$ of lines in $$\mathbb{P}^2 (\mathbb{C})$$ is the tangent line to any curve in $$\mathbb{P}^2 (\mathbb{C})$$ and this curve is the caustic of $$C$$. An example of a 1-parameter family of straight lines, which is not derived a priori as tangent lines to some curve is given by the reflection of a beam of parallel light in a curved mirror.

So now I ask: the caustic curve we are talking about is the same as the curve that best known in physics is nothing but the envelope of the rays reflected from a curved surface, and coming from a light source? Or maybe the dual of a curve is nothing but the caustic of the curve, caustic in the 'physical' sense given above?
And then, why should it be 'intuitively obvious' that each curve coincides with the caustic of its tangent lines (because what is gathered, the text defines the caustic curve from a family of 1-parameter lines , but the fact that these result in a curve as their envelope is a different kettle of fish)?
Finally, the dual form of the above consideration seems to me sincerely as obvious: trivially, every 1-parameter family of straight lines are tangents to any curve. What's wrong?
 PhysOrg.com science news on PhysOrg.com >> Galaxies fed by funnels of fuel>> The better to see you with: Scientists build record-setting metamaterial flat lens>> Google eyes emerging markets networks
 Sorry, how could I give the correct Tex-view to my post? I'm afraid, sorry.

 Quote by mdoni Definition: Let $\mathbb{P}^*$ the projective plane dual of $\mathbb{P}^2 (\mathbb{C})$: every line of $\mathbb{P}^2 (\mathbb{C})$ identifies a point of $\mathbb{P}^*$ and, conversely, every line of$\mathbb{P}^*$ corresponds to a point of $\mathbb{P}^2 (\mathbb{C})$. Given a curve $C \subset \mathbb{P}^2 (\mathbb {C})$, we consider the totality of the tangents to $C$: it is a new curve in $\mathbb{P}^*$, the so-called dual curve $C^*$. Biduality Theorem: For any projective curve $C \subset \mathbb{P}^2 (\mathbb {C})$ we have $(C^*)^* = C$. Moreover, if $p$ is a simple point of $C$ and $h$ is a simple point of $C^*$, then $h$ is tangent to $C$ in $p$ if and only if $p$, considered as a straight line in $\mathbb{P}^*$ is tangent to $C^*$ in $h$. Now, from the book Discriminants, Resultants, and Multidimensional Determinants ( here the link to the page I quote ), reported verbatim: To give an intuitive sense of Biduality Theorem in $C \subset {\mathbb{P}^2} (\mathbb {C})$, we express the notion of tangency in the dual projective plane $\mathbb{P}^*$ in terms of the original plane $\mathbb{P}^2(\mathbb{C})$. By definition, a tangent to a curve at some point is the line that contains this point and that is infinitely close to the curve near this point. In our situation, a point of $\mathbb {P}^*$ is a line $l \subset \mathbb{P}^2$. A curve $C$ in $\mathbb{P}^*$ is a 1-parameter family of lines in $C \subset \mathbb {P}^2 (\mathbb{C})$. A line in $\mathbb{P}^*$ is a pencil $P^*$ of all the lines in $C \subset \mathbb{P}^2 (\mathbb{C})$ for a given point $P$ to $C \subset \mathbb{P}^2 (\mathbb{C})$. The condition that $P^*$ is tangent to $C$ in $l$ means that the line $l$ is a member of the family $C$, a point $P$ lies on $l$ and other lines of $C$ in the vicinity of $l$ are infinitely close to the pencil $P^*$. This is usually expressed by saying that $P$ is a caustic point for the family of lines $C$. One can imagine that a beam of light of a certain intensity is coming along each line of $C$. Then the total brightness of the incoming light in an arbitrary small neighborhood of a caustic point $P$ is infinite, although there is only a ray (line of $C$) that meets the point $P$ itself. The set of all caustic points of the family of lines is usually called the caustic curve of $C$. This is nothing but the dual projective curve $C^* \subset \mathbb{P}^2$. Then the Biduality theorem states that any curve is the caustic of the family of its tangent lines (envelope of tangents). This is intuitively obvious. The "dual" form of this theorem is less obvious: it means that every 1-parameter family in $C$ of lines in $\mathbb{P}^2 (\mathbb{C})$ is the tangent line to any curve in $\mathbb{P}^2 (\mathbb{C})$ and this curve is the caustic of $C$. An example of a 1-parameter family of straight lines, which is not derived a priori as tangent lines to some curve is given by the reflection of a beam of parallel light in a curved mirror. So now I ask: the caustic curve we are talking about is the same as the curve that best known in physics is nothing but the envelope of the rays reflected from a curved surface, and coming from a light source? Or maybe the dual of a curve is nothing but the caustic of the curve, caustic in the 'physical' sense given above? And then, why should it be 'intuitively obvious' that each curve coincides with the caustic of its tangent lines (because what is gathered, the text defines the caustic curve from a family of 1-parameter lines , but the fact that these result in a curve as their envelope is a different kettle of fish)? Finally, the dual form of the above consideration seems to me sincerely as obvious: trivially, every 1-parameter family of straight lines are tangents to any curve. What's wrong?
The  tags give in-line LATEX.

Thanks.