Ask Uncle Colin: Parametric Second Derivatives
Dear Uncle Colin,
I have a pair of parametric equations giving $x$ and $y$ each as a function of $t$. I’m happy with the first derivative being $\diff{y}{t} \div \diff{x}{t}$, but I struggle to find the second derivative. How would I do that?
- Can’t Handle An Infinitesimal Nuance
Hi, CHAIN, and thanks for your message!
This always used to trip me up as well - it stood to reason that if the first derivative was $\diff yt \div \diff xt$, then the second derivative should be $\diffn 2yt \div \diffn 2xt$. If only life were so simple.
Instead, the thing to do is to treat your first derivative, $\diff yx$ as a function of $t$ - let’s call it $z(t)$ and differentiate it with respect to $x$. That gives you $\diff zx = \diff zt \div \diff xt$. ((I’ll switch to Newton notation here; this is one of the few places it comes out more neatly.)). However, we still need to figure out $\dot z$, which we can do using the quotient rule: because $z = \frac{\dot y}{\dot x}$, we have $\dot z = \frac{\dot x \ddot y - \ddot x \dot y}{\dot x^2}$.
This finally gives you $\diffn 2yx = \dot z = \frac{\dot x \ddot y - \ddot x \dot y}{\dot x^3}$ for the second derivative.
Hope that helps!
-- Uncle Colin