Consider two circles $C,C'$ in euclidean plane which intersect in exactly two points $Q,R$ and consider the line $QR$ through these points.
The claim is that a point point $P$ lies on the line $QR$ if and only if for any two lines $\ell,\ell'$ through $P$ with $C\cap\ell=\lbrace A,B \rbrace$ and $C'\cap\ell'=\lbrace A',B' \rbrace$ the following formula line segments hold $$\vert PA\vert\cdot \vert PB\vert=\vert PA'\vert\cdot \vert PB'\vert.$$
Unfortunatley I have no idea how to prove this claim. Could someone be so kind and help me?
Best wishes
The notion involved is that of "power of a point" with respect to a circle. Leaving aside some details that you may check in some textbook, given a circle $C$ and a point $P$ on the plane, one considers the intersections of $C$ and any line through $P$, say points $A$ and $B$. Then one proves that the product $PA \cdot PB$ is independent of the line chosen, and this is called the "power" of $P$ with respect to $C$.
So we can recast your question as the statement: for two circles $C$ and $C'$ intersecting at points $Q$ and $R$, the set of points of the plane with same power with respect to both circles is precisely line $QR$ (the usual terminology is "radical axis").
In order to prove this, I would suggest you to recast the condition $PA \cdot PB=PA' \cdot PB'$ into something about similar triangles.