The chain rule tells us how to find the derivative of a composite function. Brush up on your knowledge of composite functions, and learn how to apply the chain rule correctly.

I'm going to use the chain rule, and the chain rule comes into play every time, any time your function can be used as a composition of more than one function. And as that might not seem obvious right now, …

Let's explore multiple strategies to tackle derivatives involving both the product and chain rules. We start by applying the chain rule first, then the product rule.

Unravel the intricacies of applying the chain rule twice in a single problem. We'll dissect the process of finding the derivative of a function like sin (x^2)^3, demonstrating the power and adaptability of the …

Let's dive into the process of differentiating a composite function, specifically f (x)=sqrt (3x^2-x), using the chain rule. By breaking down the function into its components, sqrt (x) and 3x^2-x, we …

Yes, it is the same deal - but u-sub was born from reversing the chain rule, not the other way around. Be aware of both - use what works for you.

Chain rule Learn Chain rule Worked example: Derivative of cos³ (x) using the chain rule

We'll learn how to identify the structure of these expressions and decide the order of operations, using the chain rule and product rule. This strategy will help us tackle even the most elaborate expressions …

Proving the chain rule for derivatives. The chain rule tells us how to find the derivative of a composite function:

Well we just said u is equal to sine of x, you reverse substitute, and you're going to get exactly that right over here. So when we talk about the reverse chain rule, it's essentially just doing u-substitution in …