Derivatives of Inverse Trigonometric Functions - Online Tutor, Practice Problems & Exam Prep

At this point, we've learned a ton of different rules for finding derivatives, and we know how to find the derivatives of basic trigonometric functions like sine or cosine. But we'll also need to know how to find the derivatives of inverse trigonometric functions, and that's exactly what we're going to start looking at here, focusing specifically on the derivatives of inverse sine and inverse cosine. Now we're going to walk through a familiar process to actually find the derivative of the inverse sine function to hopefully give you a bit of intuition as to why these rules are what they are. But once we have these rules, we can then use them to actually find the derivatives of some functions. So let's go ahead and jump into things here.

Now if y is equal to the inverse sine of x, that means that x is then equal to the sine of y. Since these are equivalent statements and we know how to find the derivative of sine, we can then use implicit differentiation to ultimately find the derivative that we're looking for of the inverse sine. So coming down here, having rewritten this as x equals sine of y, remember that based on our inverse sine function, y is restricted by these values. It has to be between negative pi over 2 and positive pi over 2. But now that we have this x equals sine y, let's start our process of implicit differentiation.

So we need to start here by taking the derivative d/dx on each side. Now we know that the derivative of x with respect to x is just 1. So then moving over to this right-hand side, the derivative with respect to x of the sine of y, I know that the derivative of sine is cosine, so this gives me cosine of y. Then having to apply the chain rule here because we're taking the derivative with respect to x. So we need to multiply here by the derivative of y with respect to x. That's dy/dx. Now this dy/dx is ultimately the derivative that we want to find. So we need to get that all by itself, which we can do by dividing both sides by the cosine of y in order to get that to cancel. Doing some rearranging here, this then gives me that dy/dx is equal to 1 over the cosine of y. So I've successfully found dy/dx.

But when we're working with derivatives with respect to x, we typically want our answer in terms of x rather than in terms of y. So in order to get this in terms of x, we're going to look to our trigonometric identities. Remember that sine squared plus cosine squared is equal to 1. So if I rearrange this, solving for the cosine of y, this then gives me that the cosine of y is equal to plus or minus the square root of 1 minus the sine squared of y. So I can plug this back into my equation over here.

This gives me
over a plus or minus the square root of  minus  sine squared y. Now based on our original restrictions on y, this plus or minus square root is not going to work because we do not want the negative square root there. So we're only going to work with the positive square root. This is a positive value. Now, you may be thinking this is still in terms of y, so we have the same exact problem here.

But remember that we can rewrite the sine squared of y as sine of y squared. And what is the sine of y? The sine of y is just x. That's what we were working with from the very beginning. So I can just replace that sine y with x to ultimately give me that the derivative of the inverse sine of x, that's dy/dx, is equal to 1 over the square root of 1 minus x squared, having just replaced that sine of y with the x that I know it is.

So this is our rule for finding the derivative of the inverse sine function. Now there is a restriction on our x value here based on this being the inverse sine. The absolute value of x must be less than 1. Remember that with these restrictions, we don't want to think of them as another thing that we have to memorize and stress over. We want to focus on our rule because those restrictions follow just from our knowledge of functions.

So now that we have this rule, let's actually apply it to finding the derivative of a function. Here, we want to find the derivative of f(x) is equal to the inverse sine of 3x + 2. So we want to find here f'(x), our derivative. Now since here, I'm taking the inverse sine of 3x + 2 and not just x. That means I'm going to have to apply the chain rule.

But starting from my outermost function, that's the inverse sine. Based on the rule that we just found, we know that this derivative is equal to 1 over the square root of 1 minus in this case, it was x squared. But because here I'm taking the inverse sine of 3x + 2, that's what I need to plug in for x here. So this is 1 minus (3x + 2)^2. And then using the chain rule here, multiplying by the derivative of 3x + 2, which is just 3.

Now I can ultimately just write this 3 on the top of my fraction here to give me my final derivative here, f'(x). Now we ultimately found the derivative of the inverse sine using implicit differentiation, and we could follow that same exact process in order to determine the derivative of the inverse cosine. Now if we were to follow that process, we would find that the derivative of the inverse cosine is equal to negative one over the square root of 1 minus x squared, so the exact same thing that we got for sine except negative. Now we have that same exact restriction on x that its absolute value must be less than 1. So with this rule for finding the derivative of inverse cosine, let's work through one final example here and find the derivative of this function, g(x).

This is 4 times the inverse cosine of 6x. So finding our derivative here, g'(x), since I have this constant 4, I can just pull that out front and focus on the derivative of the inverse cosine of 6x. Now again, here, we're not just taking the inverse cosine of x, but 6x. So we need to attack this the same exact way we did in example a. So starting with our outermost function, the inverse cosine, we know based on the rule that we just learned that this derivative is equal or this derivative is equal to negative one over the square root of 1 minus, in this case, 6x because that's my inside function, so 6x squared.

Then applying my chain rule here, I need to multiply by the derivative of that inside function 6x, x, which is just 6. So I fully found my derivative here, but we can simplify this a little bit. If I go ahead and multiply that 4 times negative one times 6, that gives me negative 24 on the top. And then on the bottom, the square root of 1 minus 36 x squared, going ahead and squaring those values. So this gives me my final derivative here, g'(x).

Now as we saw for our basic trigonometric functions, we're also going to want to memorize these derivatives of our inverse trigonometric functions because they're going to come up a lot as we take more and more derivatives. But if you ever forget them, we know the process to figuring these out, and you can always look back to implicit differentiation to determine what these derivatives are. Now we're going to get some more practice using these derivatives of inverse sine and cosine coming up next. I'll see you there.

In this problem, we're given this equation, 4times(sin-1(x))+(cos-1(y))=π3. Now we want to find dy/dx at the ordered pair (0, 1/2). So, in order to do that, we're going to have to use implicit differentiation on this equation here and take ddx of each side. So this is going to be a ddx of 4times(sin-1(x))+(cos-1(y)). And this is then equal to ddx, my derivative of π3.

So now we need to take these derivatives with our ultimate goal to find dy/dx. Now starting with the easiest side, I know that the derivative of this constant is just 0. So taking it back to our left side here, the derivative of 4times(sin-1(x)) is just going to be 4/1-(x2). Then the inverse cosine of y taking this derivative is a bit more complicated because this is y and not x. We're adding this together with -1/1-(y2), then applying the chain rule here.

This is times dy/dx, which is ultimately what we want to find here. So our goal from this point is just to get this dy/dx by itself. So I'm going to go ahead and subtract this over to the other side. So this becomes -1/1-(y2) times dy/dx is then equal to -4, since I'm subtracting this over to the other side, over the square root of 1 minus x squared. Then from here, I can go ahead and multiply by the square root of 1 minus y squared.

And I can go ahead and cancel these negatives on either side, since I have a negative on each side, they cancel each other out. So this multiplication by the square root of 1 minus y squared will cancel over here, and I'm just left with dy/dx. And then this is equal to 4times1-(y2) over the square root of 1 minus x squared. But here, we were given values for x and y.

So that means that from here, we can actually plug these values in. We were given that y is equal to 0 and x is equal to 1/2. So that's what we want to plug in and now that we're at this final step. So this is 4times1-(122) over the square root of 1 minus 0 squared. Now on the bottom, that zero goes away.

We're just left with the square root of 1. That's just 1. Now up here in my top square root in my numerator, this then becomes 4times1-(122). That is 1 minus 1 fourth. 1 minus 1 fourth is 3 fourths, so this is the square root of 3 fourths.

Now we can simplify that further because the square root of 3 fourths is root 3 over 2. So this is then equal to 4root3/2. And further simplifying that, 4 over 2 just gives me 2. So this has been 2 root 3. For my final answer here, dy/dx at the ordered pair (0, 1/2).

Let us know if you have any questions here, and let's keep going.

We just learned our rules for finding the derivatives of inverse sine and inverse cosine, and we found that we could actually find what those rules are using the process of implicit differentiation. And we know that there are other inverse trig functions besides sine and cosine. We have the inverse tangent, inverse cotangent, inverse secant, and inverse cosecant. And we could follow this same exact process of implicit differentiation in order to find a derivative rule for all of these other inverse trig functions. And you can feel free to go through that process on your own.

Here, we're going to work through these remaining derivatives for our inverse trig functions in practice, alongside all of the other rules for derivatives that we've already learned so far. So let's go ahead and jump right into our first example. Here, we want to find the derivative of \( f(x) = 4x^2 \cdot \text{arctan}(x) \). Now here, I know since I have 2 functions being multiplied, that I need to use the product rule in order to find my derivative \( f'(x) \). Remember, our memory tool for the product rule tells us left d right plus right d left.

So I want to take that left-hand function \( 4x^2 \) and multiply it by the derivative of my right-hand function, that inverse tangent of \( x \). Now the derivative of the inverse tangent of \( x \) is going to be \( \frac{1}{1 + x^2} \). So I'm multiplying this \( 4x^2 \) by \( \frac{1}{1 + x^2} \) using that rule for the inverse tangent. Then continuing on with my product rule here, I have a plus, a right d left, so that's the inverse tangent of \( x \), times the derivative of this \( 4x^2 \), which is \( 8x \). Now I can rewrite this a little bit more compactly with that \( \frac{4x^2}{1 + x^2} \), and then adding this together, moving that \( 8x \) to the front, \( 8x \cdot \text{arctan}(x) \).

And this is my full derivative here, \( f'(x) \), having used my product rule alongside my new rule for the inverse tangent. Let's work through another example and take a look at some other inverse trig functions. Here, we want to find the derivative of \( g(x) = 6 \cdot \text{arccot}(x) + 4 \cdot \text{arcsec}(3x + 1) \). Now here, since I have 2 derivatives being added together, that means that I need to add their derivatives.

So \( g'(x) \) here is going to be equal to 6 times the derivative of the inverse cotangent. Now looking back up to my table here, the derivative of the inverse cotangent is \(-\frac{1}{1 + x^2}\). So it's just the negative of what the derivative of inverse tangent was. So this gives me \( 6 \cdot \left(-\frac{1}{1 + x^2}\right) \). Then adding this together with this second derivative here, the derivative of 4 times the inverse secant of \( 3x + 1 \), pulling that constant out front, then I look for the inverse secant coming up to my table here.

The derivative of the inverse secant is going to be \( \frac{1}{|\text{interior function}| \cdot \sqrt{\text{interior function}^2 - 1}} \). Now here, since I have the inverse secant of \( 3x+1 \) and not just \( x \), I need to keep that in mind as I take this derivative. So this gives me \( \frac{1}{|3x + 1|} \times \text{derivative of } (3x + 1)^2 - 1 \). I need to apply the chain rule here, working to that inside function, multiplying by the derivative of \( 3x + 1 \), which is just 3.

Now we can clean this up a little bit. In this first term, 6 times -1 is -6. So this is \( -\frac{6}{1 + x^2} \). Then for this second term here, multiplying 4 times 3 gives me 12 in my numerator.

My denominator is rather long. It is the absolute value of \( 3x+1 \) times the square root of \( (3x + 1)^2 - 1 \). And that's my full derivative here, \( g'(x) \). Now we have one final example to work through. We want to find the derivative of this function \( h(x) \), which is the inverse cosecant of \( x \), and all of that is getting cubed.

Now in order to find our derivative here, since this stuff is being cubed, we need to start with our power rule. So to find our derivative here, \( h'(x) \), we're going to pull that 3 out front using the power rule, and then decrease it by 1. This getKeyframeAreaBoxSize \( 3 \cdot (\text{arccsc}(x))^2 \), having used that power rule. Then using the chain rule, I need to multiply by the derivative of the inverse cosecant of \( x \). This is our last remaining rule for our inverse trig functions.

Now the derivative of the inverse cosecant is going to be \(-\frac{1}{|x| \cdot \sqrt{x^2 - 1}}\). So again, here, we can see that it's just the negative version of the derivative of the inverse secant. So multiplying by this, this is \(-\frac{1}{|x| \cdot \sqrt{x^2 - 1}}\). That inside function is just \( x \). So I can just use that rule as is.

Now I can rewrite this altogether in one fraction. This gives me \(-3 \cdot (\text{arccsc}(x))^2 \over |x| \cdot \sqrt{x^2 - 1}\). And this is my final derivative for this function, \( h'(x) \). Now, I have one more thing to mention here. Just as we had a restriction on our \( x \) value for the inverse sine and inverse cosine, we also have one for the inverse secant and inverse cosecant.

For these two derivatives, the absolute value of \( x \) must be greater than 1 rather than less than 1. And this is based on the original domains of these functions. Now as I've said before, whenever we're working with derivatives of trig functions, it's going to be easiest to memorize them so that we can work through examples quicker. But remember that if you're ever unsure of what these derivatives are, you can go back through your process of implicit differentiation. Either way, this process is going to get easier and quicker as we work through additional examples, and that's exactly what we're doing coming up next.

I'll see you there.