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### Course: Differential Calculus > Unit 3

Lesson 3: Implicit differentiation- Implicit differentiation
- Worked example: Implicit differentiation
- Worked example: Evaluating derivative with implicit differentiation
- Implicit differentiation
- Showing explicit and implicit differentiation give same result
- Implicit differentiation review

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# Implicit differentiation review

Review your implicit differentiation skills and use them to solve problems.

## How do I perform implicit differentiation?

In implicit differentiation, we differentiate each side of an equation with two variables (usually $x$ and $y$ ) by treating one of the variables as a function of the other. This calls for using the chain rule.

Let's differentiate ${x}^{2}+{y}^{2}=1$ for example. Here, we treat $y$ as an implicit function of $x$ .

Notice that the derivative of ${y}^{2}$ is $2y\cdot {\displaystyle \frac{dy}{dx}}$ and not simply $2y$ . This is because we treat $y$ as a function of $x$ .

*Want a deeper explanation of implicit differentiation? Check out this video.*

## Want to join the conversation?

- Hi !

i dont understand why in PROBLEM 1 :

2x + y + *bold*x dy....

dx

why x dy

dx

thank you!(21 votes)- It's because of the product rule.

x*y differentiate into (1 (from differentiating the x))* (y) + (x) * (dy/dx (from differentiating the y)) = y + x*dy/dx(49 votes)

- Hi everyone, I have a quick question. We use the chain rule to differentiate "y^2" because we treat variable y as a function of x. However, when we have simple "y", we do not apply the chain rule and just express it as dy/dx. What is the difference between y^2 and y? Why to use chain rule in first case and not in the second one like 1(y(x))*dy/dx?(6 votes)
- We already know how to represent the derivative of y with respect to x: dy/dx, which is the thing we wish to find - in terms of x and y.

y² is a function of x AND of y.

Whenever we have a function of y we need to use the chain rule:

d/dx [ f(y) ] = d/dy [ f(y) ] · dy/dx

If it makes you feel easier we could say a 'simple *y"' is the identity function: f(y) = y.

Then d/dx [ f(y) ] = d/dy [ f(y) ] · dy/dx = dy/dy · dy/dx = 1 · dy/dx(27 votes)

- For problem 1, shouldn't it simplify to (-2x-y)/(x+3y^2)(5 votes)
- Yes it could, because (-2x-y) = -(2x+y). So you just distributed the minus one into the numerator, while it's left outside in the solution. It could also have been distributed into the denominator, since -1 = 1/-1.(24 votes)

- Why we can take derivative with respect to x or y both sides during implicit differentiation ?(2 votes)
- You learn in algebra that you can perform the same operation to both sides of an equation and the equation will still hold true. Taking a derivative just happens to be one such operation.(15 votes)

- Am I allowed to simplify an equation before doing implicit differentiation? Here is the question I was stuck on: y^2 = (x-1)/(x+1). When I attempt implicit differentiation the way it is and compare the answer to when I simplify the equation to (x+1)y^2= x-1, I got different answers.(4 votes)
- Excellent question!

Implicitly differentiating the original equation eventually yields dy/dx = 1/(y(x+1)^2).

Implicitly differentiating the simplified equation eventually yields dy/dx = (1-y^2)/(2y(x+1)).

So we compare 1/(y(x+1)^2) to (1-y^2)/(2y(x+1)), using y^2 = (x-1)/(x+1).

(1-y^2)/(2y(x+1))

= (1-(x-1)/(x+1))/(2y(x+1))

= (2/(x+1))/(2y(x+1))

= 1/(y(x+1)^2).

So the answers are really the same! The point is that the original equation or an equivalent form of this equation must be considered when comparing answers.

Have a blessed, wonderful day!(8 votes)

- Find the equation of the tangent line to the graph of the following equation at the point (-1,2) Implicit Differentiation

x^2 y - y^3 = 6x(0 votes)- => y(2x) + (x^2)(dy/dx) - 3(y^2)(dy/dx) = 6

=> dy/dx = (6 - 2xy) / (x^2 - 3y^2)(2 votes)

- Hi everyone!

Do you happen to know any tricks and tips for solving derivatives and limits? Especially for implicit differentiation? I just don't like how long the process is taking me because I am a bit slow at writing and for our exams we have to write and it is time consuming.

Any help is much appreciated. Thank you!(2 votes)- A short cut for implicit differentiation is using the partial derivative (
`∂/∂x`

). When you use the partial derivative, you treat all the variables, except the one you are differentiating with respect to, like a constant. For example`∂/∂x [2xy + y^2] = 2y`

. In this case, y is treated as a constant. Here is another example:`∂/∂y [2xy + y^2] = 2x + 2y`

. In this case, x is treated as the constant.`dy/dx = - [∂/∂x] / [∂/∂y]`

This is a shortcut to implicit differentiation.

Partial derivatives are formally covered in multivariable calculus.

Even though this is a multivariate topic, this method applies to single variable implicit differentiation because you are setting the output to be constant.

Hope this helps!(7 votes)

- I keep forgetting and recognizing that dy/dx(xy)=x'y+xy'. What lessons or video would be good for learning to recognize patterns in math like these, specifically ones having to do with Calculus?(2 votes)
- https://www.youtube.com/watch?v=YG15m2VwSjA

Here's a summary:`------- (df * g)`

|-----| |

f | | | (f * dg)

|-----| |

g

d/dx(fg) = f' g + f g'(4 votes)

- Guys.. I have a question that's been bugging me:

Find the derivative function dy/dx of

x³y³-3x²y+3y²=5xy

Trying to confirm my amswer.(3 votes)- What answer did you get?(2 votes)

- I have a question is that if I get a function e^(x/y)=x-y

can I do In both side which gives me x/y=In(x-y) in order to find the derivative?

or I have to d/dx (e^(x/y))=d/dx(x-y)(2 votes)- You can do either, so long as you apply the chain rule properly and end up solving for dy/dx.(2 votes)