bell-shaped function

{{Short description|Mathematical function having a characteristic "bell"-shaped curve}}

File:Normal_Distribution_PDF.svg is the archetypal example of a bell shaped function]]

A bell-shaped function or simply 'bell curve' is a mathematical function having a characteristic "bell"-shaped curve. These functions are typically continuous or smooth, asymptotically approach zero for large negative/positive x, and have a single, unimodal maximum at small x. Hence, the integral of a bell-shaped function is typically a sigmoid function. Bell shaped functions are also commonly symmetric.

Many common probability distribution functions are bell curves.

Some bell shaped functions, such as the Gaussian function and the probability distribution of the Cauchy distribution, can be used to construct sequences of functions with decreasing variance that approach the Dirac delta distribution.{{Cite web|last=Weisstein|first=Eric W.|title=Delta Function|url=https://mathworld.wolfram.com/DeltaFunction.html|access-date=2020-09-21|website=mathworld.wolfram.com|language=en}} Indeed, the Dirac delta can roughly be thought of as a bell curve with variance tending to zero.

Some examples include:

Gaussian function, the probability density function of the normal distribution. This is the archetypal bell shaped function and is frequently encountered in nature as a consequence of the central limit theorem.

:: $f(x) = a e^{-(x-b)^2/(2c^2)}$

Fuzzy Logic generalized membership bell-shaped function{{cite web|url=http://researchhubs.com/post/engineering/fuzzy-system/fuzzy-membership-function.html|title=Fuzzy Logic Membership Function|accessdate=2018-12-29}}{{cite web|url=https://www.mathworks.com/help/fuzzy/gbellmf.html|title=Generalized bell-shaped membership function|accessdate=2018-12-29}}

:: $f(x) =\frac 1 {1+\left|\frac{x-c} a \right|^{2b}}$

Hyperbolic secant. This is also the derivative of the Gudermannian function.

:: $f(x) = \operatorname{sech}(x)=\frac{2}{e^x+e^{-x}}$

Witch of Agnesi, the probability density function of the Cauchy distribution. This is also a scaled version of the derivative of the arctangent function.

:: $f(x) = \frac{8a^3}{x^2+4a^2}$

Bump function

:: $\varphi_b(x)=\begin{cases}\exp\frac{b^2}{x^2-b^2} & |x|$

Raised cosines type like the raised cosine distribution or the raised-cosine filter

:: $f(x;\mu,s) = \begin{cases} \frac 1 {2s} \left[ 1 +\cos\left(\frac{x-\mu}s \pi\right)\right] & \text{for }\mu-s \le x \le \mu+s, \\[3pt] 0 & \text{otherwise.} \end{cases}$

Most of the window functions like the Kaiser window

The derivative of the logistic function. This is a scaled version of the derivative of the hyperbolic tangent function.

:: $f(x)=\frac{e^x}{\left(1+e^x\right)^2}$

Some algebraic functions. For example

:: $f(x)=\frac{1}{(1+x^2)^{3/2}}$

Gallery

Coth_sech_csch.svg|sech(x) (in blue)

Witch_of_Agnesi,_a_1,_2,_4,_8.svg|Witch of Agnesi

Mollifier_illustration.png|φ_b for b = 1

Raised cos pdf mod.svg|Raised cosine PDF

KaiserWindow.svg|Kaiser window

References

Category:Functions and mappings