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Normal Distribution calculator calculates the area under a bell curve and gives the probability which is higher or lower than any arbitrary $X$. It's an online
statistics and probability tool requires range of variable, $X_1$ to $X_2$, mean of normal distribution and standard deviation to find the corresponding probabilities. More precisely, this Guassian distribution calculator help us to find: probability less than a $X_1$, probability greater than a $X_1$, probability less than a $X_2$, probability greater than a $X_2$ and probability between
$X_1$ and $X_2$.
It is necessary to follow the next steps:
- Enter the population mean, the standard deviation of the population and two value $X_1$ and $X_2$ in the box. These values must be real numbers.
- Press the "CALCULATE" button to make the computation.
- Normal distribution calculator will give the probabilities of a values which are higher or lower than $X_1$ and $X_2$. It also calculates the probability between $X_1$ and $X_2$ for a given mean and standard deviation.
Input: Four real numbers. The first two are representing the mean and standard deviation.
Output: Four numbers in range $[0,1]$ since the probability must be a real number between 0 and 1.
Normal Distribution Formula:
The probabilities are determined by the formulas
$$\begin{align} P(X \leq X_1)&=\frac1{\sqrt{2\pi \sigma^2}}\int_{-\infty}^{X_1} e^{-\frac{(x-\mu)^2}{2\sigma^2 }}dx\\ P(X \geq X_1)&=\frac1{\sqrt{2\pi \sigma^2}}\int^{\infty}_{X_1} e^{-\frac{(x-\mu)^2}{2\sigma^2 }}dx\end{align}$$
where $\mu$ is the population mean and $\sigma^2$ is the population variance and $e\approx 2.7183$ and $\pi\approx 3.1416$.
What is Normal Distribution?
The normal distribution plays an important role in probability theory. In 1809, C.F. Gauss gave the first application of the normal distribution. He modeled observational errors in
astronomy.
Normal (Gaussian) distribution is a continuous probability distribution. The normal distribution is connected with many natural phenomena so it can be used for many probability problems. The normal distribution is defined with the probability density function
$$f(x)=\frac1{\sqrt{2\pi \sigma^2}} e^{-\frac{(x-\mu)^2}{2\sigma^2 }}$$
where $\mu$ is the population mean and $\sigma^2$ is the population variance. Mathematical constants $e$ and $\pi$ are approximately equal
$2.7183$ and $3.1416$, respectively. If a random variable $X$ has the normal distribution, then it is denoted by $X\sim N(\mu, \sigma^2)$.
, Bell curve or Gaussian function is used to represent the distribution of probability density function. The mean determines the location of the center of the Bell curve, and the standard deviation determines the height and width of the Bell curve. Note that the total area under the curve is 1. A random variable with a normal distribution is called normally distributed. For a normally distributed random variable $X$ with the population mean $\mu$ and the population variance $\sigma^2$, it holds that
The standard normal distribution is the
. It is denoted as $N(0,1)$. In this case, the probability density function is $$f(x)=\frac1{\sqrt{2\pi}} e^{-\frac{x^2}{2 }}$$ and the graph of this function is:
Note that this concept applies mainly to populations rather than samples. The continuous normal distribution cannot be obtained from a sample.
How to Calculate Normal Distribution?
To find the probability $P(X_1 < X < X_2)$, we need to find the area under the normal curve between the points $X_1$ and $X_2.$
$z$-scores can be used to calculate probability by comparing the location of the $z$-score to the area under a normal curve either to the
left or right. $z$-score is determined by the formula $$z=\frac{x-\mu}{\sigma}$$ where $x$ is a random member, $\mu$ is an expected mean of population and $\sigma$ is the standard deviation of an entire population. Clearly, if $x<\mu$, the value of $z$ is negative, if $x>\mu$, the value of $z$ is positive and when $x=\mu$, the value of $z$ is zero.
Since the total area under the curve is $1$, and the curve is symmetric with respect to the $y$-axis, the areas under the curve in the
regions $x<0$ and $x>0$ are equal $0.5$, i.e $P(Z<0)=P(Z>0)=0.5$.
Because the standard normal distribution is used very often,
there exist tables to help us calculate probabilities (Standard Normal Table).
Let $A(X_1)$ be the area under the standard normal curve. So, $A(X_1)$ is the probability that the value of the random variable $X$ observed for an individual chosen at random from the population is less than or equal to $X_1$, i.e. $A(X_1) = P(X\leq X_1)$. To calculate probabilities, we should follow the
next rules:
$ P(X\leq X_1)=\left\{ \begin{array}{ll} A(X_1), & X_1>0\\ 1-A(X_1), & X_1<0 \end{array} \right.$
$ P(X\geq X_1)=\left\{ \begin{array}{ll} 1-A(X_1), & X_1>0\\ A(X_1), & X_1<0 \end{array} \right.$
$ P( X_1\leq X\leq X_2)=A(X_2)-A(X_1)$
The normal distribution calculator to finding the probability less than $1.5$, probability greater than $1.5$, probability less than $1$, probability greater than $1$ and probability between $1$ and $1.5$ with a mean of $0.5$ and standard deviation of $2$. For any other values, just supply the four real numbers and click on the "CALCULATE" button. The grade school students may use this Guassian distribution calculator to verify the results derived by hand or do their homework problems efficiently.