All Calculus 3 Resources
Example Questions
Example Question #21 : Differentials
Find the differential of the following function:
The differential of the function is given by
The partial derivatives are
, ,
Example Question #21 : Differentials
Find the differential of the following function:
The differential of a function is given by
To find the given partial derivative of the function, we must treat the other variable(s) as constants.
The partial derivatives are
Example Question #22 : Differentials
Find the differential of the following function:
The differential of a function is given by
To find the given partial derivative of the function, we must treat the other variable(s) as constants.
The partial derivatives are
Example Question #23 : Differentials
Find the total differential of the following function:
The total differential of a function is given by
To find the given partial derivative of the function, we must treat the other variable(s) as constants.
The partial derivatives are
, ,
Example Question #24 : Differentials
Find the total differential of the function:
The total differential of a function is given by
To find the given partial derivative of the function, we must treat the other variable(s) as constants.
The partial derivatives are
, ,
Example Question #26 : Differentials
If , calculate the total differential .
The total differential of a function is defined as the sum of the partial derivatives of with respect to each of its variables; that is,
In this case, , and so we use the sum rule, the rule for derivatives of a variable raised to a power, the rule for the derivative of , and the chain rule to calculate the partial derivatives and , as shown:
,
.
In both cases, we treated the variable not being differentiated as a constant, and applied the chain rule to to calculate its partial derivatives. Now that and have been calculated, all that remains is to substitute them into the definition of the total derivative:
Example Question #27 : Differentials
If , calculate the total differential .
The total differential of a function is defined as the sum of the partial derivatives of with respect to each of its variables; that is,
In this case, , and so we use the product rule and the rule for differentiating to calculate the partial derivatives and , as shown:
,
In both cases, we treated the variable not being differentiated as a constant, and applied the product rule to calculate its partial derivatives. Now that and have been calculated, all that remains is to substitute them into the definition of the total derivative:
Example Question #25 : Differentials
Compute the differentials for the following function.
What we need to do is take derivatives, and remember the general equation.
When taking the derivative with respect to y recall that the product rule needs to be used.
Example Question #26 : Differentials
Compute the differentials for the following function.
What we need to do is take derivatives, and remember the general equation.
When taking the derivative with respect to y recall that the product rule needs to be used.