Critical Point Calculator – Find & Classify Critical Points

Critical Point Calculator

Find x where f'(x)=0 (critical points) numerically and classify them (local min / max / saddle) using numeric derivatives.

Function (use JavaScript/Math syntax; e.g. Math.sin(x), x**3-3*x)

Search range: min x

max x

Scan step (sampling)

Root tolerance (bisection)

Derivative h (finite difference)

How it works: the tool samples the numeric first derivative using central differences, finds sign changes (or near-zero values), refines roots via bisection, and evaluates the second derivative to classify points. This is a numeric method — results depend on range, step, and h.

Results

No calculation yet. Click Find Critical Points.

Example functions:

x**3 - 3*x → critical points at x = -1, 1
Math.sin(x) → critical points at x = k·π/2 where derivative 0 at k·π

Detailed output & interpretation

Refinement steps, raw derivative values and classification are shown after calculation.

How to Use the Critical Point Calculator

Enter the equation or function f(x)f(x)f(x).
Choose whether you want to find first derivatives, second derivatives, or both.
Click Calculate to find where the derivative equals zero or is undefined — these are the critical points.
View the results including the x-values of critical points and whether they represent maximum, minimum, or saddle points.

What Is a Critical Point?

A critical point of a function occurs where the first derivative f′(x)f'(x)f′(x) is either zero or undefined.
Critical points help determine where a function’s graph changes direction, showing local maxima, local minima, or points of inflection.

Formula

To find critical points: f′(x)=0f'(x) = 0f′(x)=0

Solve this equation for xxx. The resulting xxx-values are the critical points.

If you compute the second derivative f′′(x)f”(x)f′′(x):

If f′′(x)>0f”(x) > 0f′′(x)>0 → local minimum
If f′′(x)<0f”(x) < 0f′′(x)<0 → local maximum
If f′′(x)=0f”(x) = 0f′′(x)=0 → possible inflection point

Examples

f(x)=x2+4x+4f(x) = x^2 + 4x + 4f(x)=x2+4x+4
→ f′(x)=2x+4f'(x) = 2x + 4f′(x)=2x+4
→ Set 2x+4=02x + 4 = 02x+4=0 → x=−2x = -2x=−2
Critical Point: (-2, 0) → Local Minimum
f(x)=x3−3xf(x) = x^3 – 3xf(x)=x3−3x
→ f′(x)=3×2−3=0f'(x) = 3x^2 – 3 = 0f′(x)=3×2−3=0
→ x=±1x = ±1x=±1
Critical Points: (-1, 2), (1, 2)

Uses of the Critical Point Calculator

Quickly identify where a function increases or decreases.
Determine turning points in polynomial, trigonometric, or exponential functions.
Useful for calculus homework, optimization, and graph analysis.
Saves time by automating differentiation and zero-solving.

Why Use a Critical Point Calculator?

A Critical Point Calculator is an essential tool for students, teachers, and math enthusiasts. It simplifies finding critical points of functions by automatically computing derivatives and solving for zeros, saving both time and effort.

This calculator is especially helpful for:

Identifying local maxima and minima
Analyzing concavity and inflection points
Solving calculus optimization problems
Studying polynomial, trigonometric, and exponential functions

By using a Critical Point Calculator, you can quickly and accurately determine where a function changes direction, making graphing and function analysis more efficient and less error-prone.

Advantages of Using This Tool

The main advantage of a Critical Point Calculator is its ability to handle complex calculations in seconds. It allows students to focus on understanding concepts rather than manual computation. Teachers and professionals can also use it to check work or demonstrate solutions effectively.

Final Thoughts

The Critical Point Calculator is a valuable tool for students, educators, and professionals. It simplifies finding maxima, minima, and turning points, saves time, and ensures accurate function analysis.