Derivative of e^2x by First Principle

Answer: The derivative of e^2x by first principle is equal to 2e2x. In this article, we will find the derivative of e to the power 2x using the first principle.

Recall that for a function f(x) in one variable x, the derivative of f(x) from first principle is given by the limit below:

$\dfrac{d}{dx}(f(x))$ $=\lim\limits_{h \to 0} \dfrac{f(x+h)-f(x)}{h}$ $\quad \cdots$ (i)

Derivative of e^2x by first principle

 

Let us now differentiate e to the power 2x by the first principle.

Derivative of e^2x by first principle

Taking f(x)=e2x in the above formula (i), we get the derivative of e2x from first principle as follows:
 
$\dfrac{d}{dx}(e^{2x})$ $=\lim\limits_{h \to 0} \dfrac{e^{2(x+h)}-e^{2x}}{h}$
 
$=\lim\limits_{h \to 0} \dfrac{e^{2x+2h}-e^{2x}}{h}$
 
$=\lim\limits_{h \to 0} \dfrac{e^{2x} \cdot e^{2h}-e^{2x}}{h}$ as we know that $e^{a+b}$ $=e^a\cdot e^b$
 
$=\lim\limits_{h \to 0} \dfrac{e^{2x}(e^{2h}-1)}{h}$
 
$=e^{2x} \lim\limits_{h \to 0} \dfrac{e^{2h}-1}{h}$ as the function $e^{2x}$ is independent of h, so we can take it out of the limit
 
$=e^{2x} \lim\limits_{h \to 0} \dfrac{e^{2h}-1}{2h}$ $\times 2$
 
Let $2h=t$. So $t \to 0$ as h tends to zero. So the above limit is
 
$=2e^{2x} \lim\limits_{t \to 0} \dfrac{e^t-1}{t}$
 
= 2e2x × 1, using the limit formula limx→0 $\dfrac{e^{x}-1}{x}$ = 1.
 
= 2e2x.
 
Thus the derivative of e to the power 2x is 2e^2x. We achieve this by the first principle of derivatives.
 
 

Question Answer on Derivative of e2x

Question 1: Find the derivative of e2x at x=0 from first principle.
 
Answer:
 
The derivative of e2x using the first principle is $2e^{2x}$ (see the above proof).
 
Thus, the desired derivative at x=0 is
 
$[\dfrac{d}{dx}(e^{2x})]_{x=0}$ $=[2e^{2x}]_{x=0}$ $=2e^{2\cdot 0}$ $=2e^0$ $=2 \times 1$ $=2$
 
So the derivative of e^2x at x=0 by the first principle is equal to 2.
 
Question 2: Find the derivative of e^2.
 
Answer:
 
Note that $e^2$ is a constant number as the number e is so. We know that the derivative of a constant is zero (For a proof of this fact, click the page on Derivative of a constant is 0). So we conclude that the derivative of e square is zero.
 
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