Section 3.12 : Higher Order Derivatives
10. Determine the second derivative of \(2{x^3} + {y^2} = 1 - 4y\)
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Start SolutionNot much to this problem other than to take two derivatives so each step will show each successive derivative until we get to the second. Note however that we are going to have to do implicit differentiation to do each derivative.
Here is the work for the first derivative. If you need a refresher on implicit differentiation go back to that section and check some of the problems in that section.
\[\begin{align*}6{x^2} + 2y\,y' & = - 4y'\\ \left( {2y + 4} \right)y' & = - 6{x^2}\hspace{0.25in}\hspace{0.25in} \Rightarrow \hspace{0.5in}y' = \frac{{ - 6{x^2}}}{{2y + 4}} = \frac{{ - 3{x^2}}}{{y + 2}}\end{align*}\] Show Step 2Now, the second derivative will also need implicit differentiation. Note as well that we can work with the first derivative in its present form which will require the quotient rule or we can rewrite it as,
\[y' = - 3{x^2}{\left( {y + 2} \right)^{ - 1}}\]and use the product rule.
These get messy enough as it is so we’ll go with the product rule to try and keep the “mess” down a little. Using implicit differentiation to take the derivative of first derivative gives,
\[y'' = \frac{d}{{dx}}\left( {y'} \right) = - 6x{\left( {y + 2} \right)^{ - 1}} + 3{x^2}{\left( {y + 2} \right)^{ - 2}}y'\] Show Step 3Finally, recall that we don’t want a \(y'\) in the second derivative so to finish this out we need to plug in the formula for \(y'\) (which we know…) and do a little simplifying to get the final answer.
\[y'' = - 6x{\left( {y + 2} \right)^{ - 1}} + 3{x^2}{\left( {y + 2} \right)^{ - 2}}\left( { - 3{x^2}{{\left( {y + 2} \right)}^{ - 1}}} \right) = \require{bbox} \bbox[2pt,border:1px solid black]{{ - 6x{{\left( {y + 2} \right)}^{ - 1}} - 9{x^4}{{\left( {y + 2} \right)}^{ - 3}}}}\]