Examples with detailed solutions on how to calculate second order partial derivatives are presented.

Definitions and Notations of Second Order Partial Derivatives

Examples with Detailed Solutions on Second Order Partial Derivatives

Example 2
Find f_xx, f_yy, f_xy, f_yx given that f(x , y) = x³ + 2 x y.
Solution

f_xx is calculated as follows
f_xx = ∂²f / ∂x² = ∂(∂f / ∂x) / ∂x
= ∂(∂[ x³ + 2 x y ]/ ∂x) / ∂x
= ∂( 3 x² + 2 y ) / ∂x
= 6x
f_yy is calculated as follows
f_yy = ∂²f / ∂y² = ∂(∂f / ∂y) / ∂y
= ∂(∂[ x³ + 2 x y ]/ ∂y) / ∂y
= ∂( 2x ) / ∂y
= 0
f_xy is calculated as follows
f_xy = ∂²f / ∂y∂x = ∂(∂f / ∂x) / ∂y
= ∂(∂[ x³ + 2 x y ]/ ∂x) / ∂y
= ∂( 3 x² + 2 y ) / ∂y
= 2
f_yx is calculated as follows
f_yx = ∂²f / ∂x∂y = ∂(∂f / ∂y) / ∂x
= ∂(∂[ x³ + 2 x y ]/ ∂y) / ∂x
= ∂( 2x ) / ∂x
= 2

Example 3
Find f_xx, f_yy, f_xy, f_yx given that f(x , y) = x³y⁴ + x² y.
Solution

f_xx is calculated as follows
f_xx = ∂²f / ∂x² = ∂(∂f / ∂x) / ∂x
= ∂(∂[ x³y⁴ + x² y ]/ ∂x) / ∂x
= ∂( 3 x²y⁴ + 2 x y) / ∂x
= 6x y⁴ + 2y
f_yy is calculated as follows
f_yy = ∂²f / ∂y² = ∂(∂f / ∂y) / ∂y
= ∂(∂[ x³y⁴ + x² y ]/ ∂y) / ∂y
= ∂( 4 x³y³ + x² ) / ∂y
= 12 x³y²
f_xy is calculated as follows
f_xy = ∂²f / ∂y∂x = ∂(∂f / ∂x) / ∂y
= ∂(∂[ x³y⁴ + x² y ]/ ∂x) / ∂y
= ∂( 3 x²y⁴ + 2 x y ) / ∂y
= 12 x²y³ + 2 x
f_yx is calculated as follows
f_yx = ∂²f / ∂x∂y = ∂(∂f / ∂y) / ∂x
= ∂(∂[ x³y⁴ + x² y ]/ ∂y) / ∂x
= ∂(4 x³y³ + x²) / ∂x
= 12 x²y³ + 2x

More References and Links to Partial Derivatives and Multivariable Functions