Functions
Limits and Derivatives
Applications of Differentiation
Integration

Deriving Polynomials Using the Power Rule and Simple Derivative Properties

The Power Rule for Monomials

Let’s start out by seeing if there is a pattern to the derivatives of powers of \(x\); that is, maybe we can come up with a rule for deriving functions of the form \(f(x)=x^n\) (where \(n\) is any positive whole number, simply by looking at the derivatives of \(x^1\), \(x^2\), \(x^3\), \(x^4\), etc. See the table below for the final computations of the derivatives of these sorts of functions. Note that the video above goes through how one gets the results for a few of them.

\(f(x)=x^n\)\(f'(x)=\lim_{h\rightarrow 0} \frac{f(x+h)-f(x)}{h}\)
\(x^1\)\(f'(x)=1\)
\(x^2\)\(f'(x)=2x\)
\(x^3\)\(f'(x)=3x^2\)
\(x^4\)\(f'(x)=4x^3\)
\(x^5\)\(f'(x)=5x^4\)

As you can probably tell, the pattern for computing \(f'(x)\) from \(f(x)=x^n\) is given by the following rule. It turns out that the rule that can be determined from the pattern you see above also holds when the exponent is not a positive whole number as well. All this is baked into the following rule.

So, what this rule is saying is “to find the derivative of a function of the form \(f(x)=x^n\), move the exponent down to the front of the \(x\) (multiplying it by what’s already there, if anything) and subtract \(1\) from the exponent (no matter what the exponent \(n\) originally was).

As said before, the power rule basically tells us to “move the exponent to the front (multiplying by what is already there, if anything) and mindlessly subtract \(1\) from the exponent. This gives us:

$$f'(x)=3.52x^{3.52-1}=3.52x^{2.52}


Deriving Functions with Numbers Out in Front

This was hinted at when describing how to derive powers of \(x\) above. The following rule helps us derive constant multiples of functions, or “functions with numbers out in front.”

What this rule is saying is essentially: “derive the ‘function part,’ and bring the constant coefficient along for the ride, multiplying it by the end-result of your differentiation of the ‘main function part.” This is illustrated in the example below.

Using the idea of the rule above for deriving constant multiples of a function, we will ignore the \(2.5\) coefficient out in front while we derive the \(x^6\) and multiply that \(2.5\) to the result. This gives us

$$\frac{d}{dx}\ 2.5x^6=2.5\cdot(6x^5)=15\cdot x^5$$

Yep. That simple. just bring the coefficient along for the ride and multiply it at the end.


Deriving Polynomials and Linear Combinations of Functions

The following property of derivatives vastly expands the number of functions that we can find the derivative of using the power rule.

Basically, what this rule is saying is that when you have functions that are being added or subtracted, who may also have a number out in front of the functions, you can derive just the “main functions” and bring the constant coefficients along for the ride.

Furthermore, the above rule can be generalized to where several functions are being added or subtracted, with constant coefficients. All this good stuff is exhibited in the example below.

To derive this, we simply derive the exponential expressions \(x^2\), \(-4x^5\), and \(3.5x^3\) using the ideas we’ve developed, and then add all the results at the end. Thus:

$$\begin{align}\frac{d}{dx}\ (x^2-4x^5+3.5x^3) &= 2x^1-4(5x^4)+3.5(3x^2)\\&= 2x-20x^4+10.5x^2\end{align}$$


Finding Derivatives at Specific \(x\)-Values Using Rules

According to the above method, we first find the derivative of \(f\) and then plug \(2\) in at the end… super easy.

$$\begin{align}f'(x)&=3(4x^3)\\&=12x^3\end{align}$$

Thus, \(f'(2)=12(2)^3=96\). Done.


Finding Tangent Lines (is now easier)

The glorious thing about having new, simpler, rules for finding derivatives is that it makes short(er) work of finding tangent lines and doing other derivative-related things. Below is an example of finding the equation of a tangent line using the power rule.

Remember: to find a tangent line, we need two ingredients: a point on the line (specifically, the point where the line touches the graph of \(f\)) and the slope of the line (which comes from the derivative of \(f\)).

To find the slope of the tangent line, compute the derivative of \(f\) at \(x=1\). Using the power rule, we compute the derivative of \(f\) to be

$$\begin{align}\frac{d}{dx}\ f(x)&=\frac{d}{dx}\ 3x^2+3x^3\\&=3\cdot(2x)+3\cdot(3x^2)\\&=6x+9x^2\end{align}$$

Then, to find \(f'(1)\), just plug \(1\) into the derivative above! Super simple.

$$\begin{align} f'(1)&=6(1)+9(1)^2\\&=15\end{align}$$

This is your \(m\) (i.e. your slope of the tangent line). Now, to find a point on the tangent line, we are already given the \(x\) value of that point, namely \(x=1\). Now to find the \(y\)-value of the point, plug \(x=1\) into the original function (not the derivative). Thus,

$$\begin{align}f(1)&=3(1)^2+3(1)^3\\&=6\end{align}$$

So, in summary, our ingredients for the tangent line are: \(m=15\), \(x_0=1\) and \(y_0=6\). Plug this all into point-slope form \((y-y_0)=m(x-x_0)\) as shown below, and then solve for \(y\). The algebra is skipped.

$$(y-6)=15(x-1)$$

which gives us equation of the tangent line \(y=15x-9\).

Find the Derivative of the Following Functions

Use the power rule on each term

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=2x+2\)

Use the power rule on each term

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=15x^4+10x-2\)

Use the power rule on each term

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=-6.9x^2+10.8x\)

Technically, there is a power of 1 on that \(x\)

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=1\)

Think about what a derivative represents (i.e. slope).  What is the slope of a function that has the same height everywhere?

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=0\)

Use the power rule on each term

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=-x+2x^2\)

Use the power rule on each term

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=3.14x^{2.14}-0.5x^{-0.5}+1\)

Use the power rule on each term

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=11.6x^{4.8}-6x^5-13.863x^{3.621}+10x\)

Use the power rule on each term.  Don’t let the weird exponent scare you.  Just be careful with how you subtract 1 from the exponent

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=\frac{1}{2}x^{-\frac{1}{2}}+\frac{3}{4}x^{-\frac{1}{4}}-\frac{1}{3}x^{-\frac{2}{3}}\)

First convert all radicals to fractional powers.  Then hit it with power rule!

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=\frac{1}{2}x^{-\frac{3}{4}}+\frac{1}{2}x^{-\frac{1}{2}}+\frac{2}{3}x^{-\frac{2}{3}}\)

First convert all radicals to fractional powers.  Then hit it with power rule!

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=\frac{3}{2}x^{-\frac{1}{2}}-\frac{4}{3}x^{-\frac{2}{3}}+x^{-\frac{4}{5}}\)

https://player.vimeo.com/video/717608320?h=8e9ecc5d60&badge=0&autopause=0&player_id=0&app_id=58479

First convert all radicals to fractional powers.  Then hit it with power rule!

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

\(f'(x)=\frac{3}{2}x^{\frac{1}{2}}+\frac{2}{3}x^{-\frac{1}{3}}-\frac{5}{4}x^{\frac{1}{4}}\)

First convert all radicals to fractional powers.  Then hit it with power rule!

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

\(f'(x)=\frac{10}{3}x^{-\frac{1}{3}}-8x^{\frac{3}{2}}+2x\)

The power rule works the same no matter what the power on x is; even negative powers.

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=3x^2+2x^{-3}-3x^{-4}\)

The power rule works the same no matter what the power on x is; even negative powers.

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

\(f'(x)=-4x^{-5}-6x^{-3}-20x^{-6}\)

Bring the powers of x up to the numerator, making the exponent negative; i.e. \(\frac{1}{x^2}=x^{-2}\)

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

\(f'(x)=-2x^{-3}-x^{-2}-3x^{-4}\)

Bring the powers of x up to the numerator, making the exponent negative; i.e. \(\frac{1}{x^2}=x^{-2}\)

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

\(f'(x)=\frac{-4}{x^2}+\frac{4}{x^3}-\frac{15}{x^4}\)  or \(f'(x)=-4x^{-2}+4x^{-3}-15x^{-4}\)

Convert radicals to fractional powers, then bring the powers of x up to the numerator, making the exponent negative; i.e. \(\frac{1}{x^2}=x^{-2}\)

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

\(f'(x)=\frac{-2}{x^3}-\frac{1}{2x^{\frac{1}{2}}}-\frac{1}{2x^{\frac{3}{2}}}\)  or \(f'(x)=-2x^{-3}-\frac{1}{2}x^{-\frac{1}{2}}-\frac{1}{2}x^{-\frac{3}{2}}\)

Convert radicals to fractional powers, then bring the powers of x up to the numerator, making the exponent negative; i.e. \(\frac{1}{x^2}=x^{-2}\)

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

\(f'(x)=-\frac{1}{2}x^{-\frac{3}{2}}-\frac{1}{3}x^{-\frac{4}{3}}+x^{-2}\)  or \(f'(x)=-\frac{1}{2x^{\frac{3}{2}}}-\frac{1}{3x^{\frac{4}{3}}}+\frac{1}{x^2}\)

Convert radicals to fractional powers, then bring the powers of x up to the numerator, making the exponent negative; i.e. \(\frac{1}{x^2}=x^{-2}\)

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

\(f'(x)=-x^{-\frac{4}{3}}+6x^{-\frac{5}{2}}-\frac{5}{3}x^{-\frac{8}{3}}\) or \(f'(x)=\frac{-1}{x^{\frac{4}{3}}}+\frac{6}{x^{\frac{5}{2}}}-\frac{5}{3x}\)

Convert radicals to fractional powers, then bring the powers of x up to the numerator, making the exponent negative; i.e. \(\frac{1}{x^2}=x^{-2}\)

Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)

For deriving powers of x:  bring the power down in front, multiplying by whatever is already there, then subtract 1 from the exponent.

\(f'(x)=-2x^{-3}-17.5x^{-\frac{9}{2}}+9.23x^{-2.24}\) or \(f'(x)=\frac{-2}{x^3}-\frac{17.5}{x^{\frac{9}{2}}}+\frac{9.23}{x^{2.42}}\)


Find the line tangent to the graph of the functions below at the specified points

Since you’re given an x and y-value, start by finding slope of the tangent line \(m=f'(2)\)

  • Find \(y_0=f(x_0)\), i.e. the y-value of the given x-value (if not provided already)
  • Compute \(f'(x)\)
  • Compute \(m=f'(x_0)\), i.e. plug in given x-value into derivative found in step 2.
  • Plug \(x_0,y_0,m\) into point-slope formula \(y-y_0)=m\cdot(x-x_0)\) and solve for \(y\).
  • Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)
  • Point-Slope Form:  \((y-y_0)=m\cdot(x-x_0)\)

\(y=-4x+8\)

Since you’re given an x and y-value, start by finding slope of the tangent line \(m=f'(2)\)

  • Find \(y_0=f(x_0)\), i.e. the y-value of the given x-value (if not provided already)
  • Compute \(f'(x)\)
  • Compute \(m=f'(x_0)\), i.e. plug in given x-value into derivative found in step 2.
  • Plug \(x_0,y_0,m\) into point-slope formula \(y-y_0)=m\cdot(x-x_0)\) and solve for \(y\).
  • Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)
  • Point-Slope Form:  \((y-y_0)=m\cdot(x-x_0)\)

\(y=0\)

First find the y-value of the point on your tangent line by finding \(y_0=f(1)\).  Then find the slope of your tangent line \(m=f'(1)\)

  • Find \(y_0=f(x_0)\), i.e. the y-value of the given x-value (if not provided already)
  • Compute \( ‘(x)\)
  • Compute \(m=f'(x_0)\), i.e. plug in given x-value into derivative found in step 2.
  • Plug \(x_0,y_0,m\) into point-slope formula \(y-y_0)=m\cdot(x-x_0)\) and solve for \(y\).
  • Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)
  • Point-Slope Form:  \((y-y_0)=m\cdot(x-x_0)\)

\(y=\frac{1}{2}x+\frac{1}{2}\)

First find the y-value of the point on your tangent line by finding \(y_0=f(-1)\).  Then find the slope of your tangent line \(m=f'(-1)\)

  • Find \(y_0=f(x_0)\), i.e. the y-value of the given x-value (if not provided already)
  • Compute \(f'(x)\)
  • Compute \(m=f'(x_0)\), i.e. plug in given x-value into derivative found in step 2.
  • Plug \(x_0,y_0,m\) into point-slope formula \(y-y_0)=m\cdot(x-x_0)\) and solve for \(y\).
  • Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)
  • Point-Slope Form:  \((y-y_0)=m\cdot(x-x_0)\)

\(y=3x+3\)

Since you’re given an x and y-value, start by finding slope of the tangent line \(m=f'(-1)\)

  • Find \(y_0=f(x_0)\), i.e. the y-value of the given x-value (if not provided already)
  • Compute \(f'(x)\)
  • Compute \(m=f'(x_0)\), i.e. plug in given x-value into derivative found in step 2.
  • Plug \(x_0,y_0,m\) into point-slope formula \(y-y_0)=m\cdot(x-x_0)\) and solve for \(y\).
  • Power Rule:  \(\frac{d}{dx} cx^n=ncx^{n-1}\)
  • Point-Slope Form:  \((y-y_0)=m\cdot(x-x_0)\)

\(y=2x-3\)

Scroll to Top