Mister Exam
Other calculators
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- The intersection points of functions
-
How to use it?
- Graphing y =:
- x³-2x²+x+3
- x^2/4+x/16+1/4
- -x^2-3x+10
- 2x^3+3x^2
- Integral of d{x}:
-
e^(2*x)+3
- Derivative of:
- e^(2*x)+3
-
Identical expressions
- e^(two *x)+ three
- e to the power of (2 multiply by x) plus 3
- e to the power of (two multiply by x) plus three
- e(2*x)+3
- e2*x+3
- e^(2x)+3
- e(2x)+3
- e2x+3
- e^2x+3
-
Similar expressions
- e^(2*x)-3
Graphing y = e^(2*x)+3
The solution
The graph of the function
The points of intersection with the X-axis coordinate
Graph of the function intersects the axis X at f = 0
so we need to solve the equation:
$$e^{2 x} + 3 = 0$$
Solve this equation
Solution is not found,
it's possible that the graph doesn't intersect the axis X
so we need to solve the equation:
$$e^{2 x} + 3 = 0$$
Solve this equation
Solution is not found,
it's possible that the graph doesn't intersect the axis X
Extrema of the function
In order to find the extrema, we need to solve the equation
$$\frac{d}{d x} f{\left(x \right)} = 0$$
(the derivative equals zero),
and the roots of this equation are the extrema of this function:
$$\frac{d}{d x} f{\left(x \right)} = $$
the first derivative
$$2 e^{2 x} = 0$$
Solve this equation
Solutions are not found,
function may have no extrema
$$\frac{d}{d x} f{\left(x \right)} = 0$$
(the derivative equals zero),
and the roots of this equation are the extrema of this function:
$$\frac{d}{d x} f{\left(x \right)} = $$
the first derivative
$$2 e^{2 x} = 0$$
Solve this equation
Solutions are not found,
function may have no extrema
Inflection points
Let's find the inflection points, we'll need to solve the equation for this
$$\frac{d^{2}}{d x^{2}} f{\left(x \right)} = 0$$
(the second derivative equals zero),
the roots of this equation will be the inflection points for the specified function graph:
$$\frac{d^{2}}{d x^{2}} f{\left(x \right)} = $$
the second derivative
$$4 e^{2 x} = 0$$
Solve this equation
Solutions are not found,
maybe, the function has no inflections
$$\frac{d^{2}}{d x^{2}} f{\left(x \right)} = 0$$
(the second derivative equals zero),
the roots of this equation will be the inflection points for the specified function graph:
$$\frac{d^{2}}{d x^{2}} f{\left(x \right)} = $$
the second derivative
$$4 e^{2 x} = 0$$
Solve this equation
Solutions are not found,
maybe, the function has no inflections
Horizontal asymptotes
Let’s find horizontal asymptotes with help of the limits of this function at x->+oo and x->-oo
$$\lim_{x \to -\infty}\left(e^{2 x} + 3\right) = 3$$
Let's take the limit
so,
equation of the horizontal asymptote on the left:
$$y = 3$$
$$\lim_{x \to \infty}\left(e^{2 x} + 3\right) = \infty$$
Let's take the limit
so,
horizontal asymptote on the right doesn’t exist
$$\lim_{x \to -\infty}\left(e^{2 x} + 3\right) = 3$$
Let's take the limit
so,
equation of the horizontal asymptote on the left:
$$y = 3$$
$$\lim_{x \to \infty}\left(e^{2 x} + 3\right) = \infty$$
Let's take the limit
so,
horizontal asymptote on the right doesn’t exist
Inclined asymptotes
Inclined asymptote can be found by calculating the limit of E^(2*x) + 3, divided by x at x->+oo and x ->-oo
$$\lim_{x \to -\infty}\left(\frac{e^{2 x} + 3}{x}\right) = 0$$
Let's take the limit
so,
inclined coincides with the horizontal asymptote on the right
$$\lim_{x \to \infty}\left(\frac{e^{2 x} + 3}{x}\right) = \infty$$
Let's take the limit
so,
inclined asymptote on the right doesn’t exist
$$\lim_{x \to -\infty}\left(\frac{e^{2 x} + 3}{x}\right) = 0$$
Let's take the limit
so,
inclined coincides with the horizontal asymptote on the right
$$\lim_{x \to \infty}\left(\frac{e^{2 x} + 3}{x}\right) = \infty$$
Let's take the limit
so,
inclined asymptote on the right doesn’t exist
Even and odd functions
Let's check, whether the function even or odd by using relations f = f(-x) и f = -f(-x).
So, check:
$$e^{2 x} + 3 = 3 + e^{- 2 x}$$
- No
$$e^{2 x} + 3 = -3 - e^{- 2 x}$$
- No
so, the function
not is
neither even, nor odd
So, check:
$$e^{2 x} + 3 = 3 + e^{- 2 x}$$
- No
$$e^{2 x} + 3 = -3 - e^{- 2 x}$$
- No
so, the function
not is
neither even, nor odd