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Introduction

Whenever a random experiment is replicated, the Random Variable that equals the average (or total) result over the replicates tends to have a normal distribution as the number of replicates becomes large.
It is one of the cornerstones of probability theory and statistics, because of the role it plays in the Central Limit Theorem, and because many real-world phenomena involve random quantities that are approximately normal (e.g., errors in scientific measurement).
It is also known by other names such as: Gaussian Distribution, Bell shaped Distribution.

Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)

It can be observed from the above graph that the distribution is symmetric about its center, which is also the mean (0 in this case). This makes the probability of events at equal deviations from the mean, equally probable. The density is highly centered around the mean, which translates to lower probabilities for values away from the mean.

Probability Density Function

The probability density function of the general normal distribution is given as:
Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)
In the above formula, all the symbols have their usual meanings, σ is the Standard Deviation and μ is the Mean.
It is easy to get overwhelmed by the above formula while trying to understand everything in one glance, but we can try to break it down into smaller pieces so as to get an intuition as to what is going on.
The z-score is a measure of how many standard deviations away a data point is from the mean. Mathematically,
Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)
The exponent of e in the above formula is the square of the z-score times -1 / 2. This is actually in accordance to the observations that we made above. Values away from the mean have a lower probability compared to the values near the mean. Values away from the mean will have a higher z-score and consequently a lower probability since the exponent is negative. The opposite is true for values closer to the mean.
This gives way for the 68-95-99.7 rule, which states that the percentage of values that lie within a band around the mean in a normal distribution with a width of two, four and six standard deviations, comprise 68%, 95% and 99.7% of all the values. The figure given below shows this rule-

Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)

The effects of μ and δ on the distribution are shown below. Here μ is used to reposition the center of the distribution and consequently move the graph left or right, and σ is used to flatten or inflate the curve-

Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)

Expectation
Expected value E[x] can be found by simply multiply the probability distribution function with x and integrate over all possible values
Let ‘X’ be a normal distributed random variable with parameters μ and σ2.
we know that area or the region inside normal distribution curve is 1 (because probability is 1)
therefore Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)
Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)
writing x as (x - μ) + μ yields
Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)
letting y = x-μ
Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)
first one is symmetric about y-axis, hence value of that integral is 0.
Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)
E[x] = 0 + μ * 1
therefore ,
expectation E[x] = μ
variance =  δ2
standard deviation Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)

Standard Normal Distribution

In the General Normal Distribution, if the Mean is set to 0 and the Standard Deviation is set to 1, then the corresponding distribution obtained is called the Standard Normal Distribution.
The Probability Density function now becomes:
Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)
The cumulative density function of normal distribution does not give a closed formula. Hence precomputed values formulated in tables are used where-ever required. But these tables only contain data for the standard distribution. In order to find the cumulative probability for a general normal distribution, it is first standardized and then computed using the value tables.
This is beneficial in two ways:

  1. First, there needs to be only one table to compute probabilities for all normal distributions.
  2. Second, the table size is limited to 40 to 50 rows and 10 columns. This is due 68-95-99.7 rule explained above, which says that values within 3 standard deviations of the mean account for 99.7% probability. So beyond X = 3 (μ + 3σ = 0 + 3 * 1 = 3) the probabilities are approximately 0.
    Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)

Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE)

If X is a normal random variable with E(X) = μ and V(X) = σ2,
the random variable  Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE) is a normal random variable with E(Z) = 0 and V(Z) = 1.
That is, Z is a standard normal random variable.

Example: Suppose that the current measurements in a strip of wire are assumed to follow a normal distribution with a mean of 10 milliamperes and a variance of four (milliamperes)2. What is the probability that a measurement exceeds 13 milliamperes?
Solution: Let X denote the current in milliamperes. The requested probability can be represented as P (X > 13).
Let Z = (X ? 10) 2. With the Normal Distribution now standardized, the probability P(X > 13) = P(Z > 1.5) can now be easily computed.
Looking at the above table, first we find 1.5 in the X column, and then since there are no more digits of significance we look for 0.00 in the Y column. The corresponding cell gives us the value of P(Z ≤ 1.5) = 0.93319
So,
P(Z ≥ 1.5) = 1 - P(Z ≤ 1.5) = 1 - 0.93319 = 0.06681
Expected value, variance, standard deviation
The expected value of a standard normal random variable X is
expected value E[x] = 0
variance V[x] = 1
standard deviation = 1

The document Probability Distributions (Normal Distribution) | Engineering Mathematics - Civil Engineering (CE) is a part of the Civil Engineering (CE) Course Engineering Mathematics.
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FAQs on Probability Distributions (Normal Distribution) - Engineering Mathematics - Civil Engineering (CE)

1. What is a normal distribution?
Ans. A normal distribution is a probability distribution that is symmetric and bell-shaped, with the mean, median, and mode all equal. It is commonly used to model data that clusters around a central value, with fewer values farther away from the center.
2. How is the normal distribution characterized?
Ans. The normal distribution is characterized by its mean and standard deviation. The mean represents the center of the distribution, while the standard deviation measures the spread or dispersion of the data. These two parameters determine the shape and location of the bell curve.
3. What is the empirical rule for the normal distribution?
Ans. The empirical rule, also known as the 68-95-99.7 rule, states that approximately 68% of the data falls within one standard deviation of the mean, 95% falls within two standard deviations, and 99.7% falls within three standard deviations. This rule provides a quick way to estimate the proportion of data within certain ranges in a normal distribution.
4. How can the normal distribution be used in statistics?
Ans. The normal distribution is widely used in statistics for hypothesis testing, confidence intervals, and making predictions. Many statistical tests and techniques assume that the data follows a normal distribution, allowing for the use of mathematical formulas and methods that simplify analysis and interpretation.
5. Can real-world data always be modeled by a normal distribution?
Ans. No, not all real-world data can be perfectly modeled by a normal distribution. While many natural phenomena and human characteristics tend to approximate a normal distribution, there are cases where other distributions, such as skewed or bimodal distributions, are more appropriate. It is important to assess the data and choose the most suitable distribution for accurate analysis and inference.
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