Chapter 6 The Normal Probability Distribution PDF
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Ahmad Farooqi, PhD
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This document is a set of lecture notes on the normal probability distribution, covering continuous random variables, probability distributions, and the normal distribution. It's meant to be used with a textbook for a statistics course.
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Chapter 6: The Normal Probability Distribution By Ahmad Farooqi, PhD 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 1 Outlines of Chapter 6 C...
Chapter 6: The Normal Probability Distribution By Ahmad Farooqi, PhD 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 1 Outlines of Chapter 6 Continuous Random Variables Probability Distributions for Continuous Random Variables The Normal Distribution Calculation of areas associated with the normal probability distribution Chapter Review 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 2 Learning Outcomes of Chapter On completion of this chapter, with the aid of your course textbook, you should be able to know: 1) What is the normal distribution, what is the standard normal distribution. 2) How to compute the probabilities of the standard normal distribution from the standard normal Table (Table 3 in the textbook). 3) How to compute the probabilities of any normal distribution using the standard normal Table. 4) The normal approximation to the Binomial probability distribution: how to compute a Binomial probability by using the normal distribution. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 3 Introduction We know a discrete random variables take on only a finite or countably infinite number of values that can be used to model some real-life scenarios. There are continuous random variables that can assume the infinitely many values corresponding to points on a line interval can also be used to model many real-life scenarios. The normal probability distribution can be served as models for many practical applications with such kind of continuous random variable. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 4 Continuous Random Variables Continuous random variables: Random variables that can assume the infinitely many possible values corresponding to points on a line interval. Examples: Heights, weights, Marks, Age can assume any possible values. Length of life of a particular product. Experimental laboratory error. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 5 Probability Histograms As the number of measurements becomes very large and the class widths become very narrow, the relative frequency histogram appears like a smooth curve, called a probability histogram as shown below. This smooth curve describes the probability distribution of the continuous random variable. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 6 Continuous Probability Distribution The depth or density of the probability, which varies with x, may be described by a mathematical formula f(x), called the probability distribution or probability density function for the continuous random variable x. There are many different types of continuous random variables. We will briefly introduce the uniform distribution and exponential distribution, then focus on the normal distribution. We try to pick a model that: Fits the data well. Allows us to make the best possible inferences using the data. Note: A smooth graph of continuous probability distribution is called a curve. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 7 Area Under the Curve Note that the Total area under the curve is always equal to (relating to the total probability equal to 1). Area under the curve between and as shown in blue. In other words, probability of an event between and as shown in blue. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 8 Properties of Continuous Probability Distributions If we can calculate the area under the curve, we can solve for the probability of falling within the given arbitrary intervals. There is no probability attached to any specific value of a continuous random variable. In other words, probability of a continuous r.v at a specific value will always zero, mathematically That is,. where is any specific value. This implies that and. This is not true in general for discrete random variables! 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 9 Continuous Uniform Probability Distribution The Uniform Random Variable is used to model the behavior of a continuous random variable whose values are uniformly or evenly distributed over a given interval. If takes on values between and , then probability density function for uniform distribution is given by This results in an area under the curve of 1, which is easy to confirm as it produces a rectangle with width and height , Note: The values of a uniform random variable are evenly distributed over a given interval. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 10 Uniform Probability Distribution-Example Example (Textbook) Rounding Error: The error introduced by rounding an observation to the nearest centimeter has a Uniform Distribution over the interval. What is the probability that the rounding error is less than 0.2? Solution: 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 11 Exponential Probability Distribution The Exponential Random Variable is used to model continuous random variables such as waiting times, or more importantly, lifetimes (life length) associated with electronic components. In general, the Exponential probability density function is given by / Parameter is the mean of the distribution. It can be shown that / for. Memoryless Property: A unique property of the exponential distribution is 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 12 Exponential Probability Distribution-Example Example 6.1 (Textbook) Waiting Time: The waiting time at a Canadian supermarket checkout has an exponential distribution with an average time of five minutes. The probability density function is visualized below. What is the probability that you need to wait 10 minutes or more? Solution: 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 13 The Normal Random Variable Recall a continuous random variable, then the probability distribution discovered by Gauss in 1890, based on continuous r.v. Normal Random Variable: A random variable, X is said to be a normal random variable, with mean μ and standard deviation σ, if it can assume all possible values in an interval [-∞, ∞]. For example, the height of a person, the temperature of the place, etc. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 14 The Normal Probability Distribution Let a continuous random variable X follows a bell-shaped curve called a normal distribution with mean (μ) and SD (σ), then its probability function is defined as: ( ) for Where, μ= Mean of Normal distribution, σ= SD of Normal distribution , A typical normal curve looks like this: We indicate that a random variable X is normally distributed as X N(μ, ). 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 15 Characteristics of Normal Probability Distribution A normal distribution is a bell-shaped curve. A range of normal curve is from. The mean and SD of normal distribution is μ and σ respectively. μ A normal curve is symmetric about the mean μ. The area under an entire normal curve is. The height of any normal curve is maximized at x = µ. The shape of any normal curve depends on its mean μ and SD σ. Increasing the mean shifts the density curve to the right... Increasing the SD flattens the density curve... 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 16 Characteristics of Normal Probability Distribution (can’t) Since a normal curve is symmetrical about the mean therefore, Mean=Median=Mode The 68% of the data fall between μ The 95% of the data fall between μ The 99% of the data fall between μ The first and third quartiles are The 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 17 The Area in Normal Probability Distribution The probability density function for a normal distribution with mean and standard deviation looks like with of area above the mean and of area below the mean : 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 18 The Location and Shape of Normal Distribution The shape and location of the normal curve changes as the mean and standard deviation change. The mean locates the centre of the distribution. The shape of the distribution is determined by , the population standard deviation. Large values of reduce the height of the curve and increase the spread. Small values of increase the height of the curve and reduce the spread. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 19 Standard Normal Random Variable Standard Normal Random variable: A random variable, z=(( −μ)/σ ) is said to be a Standard Normal Random variable (z score), with mean μ and SD σ. The probability distribution of z is called a Standard Normal distribution. To find ( < < ), we need to find the area under the appropriate normal curve. To simplify the tabulation of these areas, we standardize each value of by expressing it as a z-score, the number of standard deviations it lies from the mean : Equivalently, = +z. Note: 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 20 Characteristics of Standard Normal Random Variable Mean ; Standard deviation When Symmetric about Values of z to the left of Centre are negative Values of z to the right of Centre are positive Total area under the curve is 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 21 The Area in Standardized Normal Distribution Random variable z has a normal distribution with and. We can solve for cumulative probabilities using Table 3 (page: 720-721 textbook). The shaded area represents. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 22 Finding Area Using Table 3 The 4-digit probability in a particular row and column of Table 3 (page:720-721 textbook) gives the area under the z curve to the left that specific value of. What is ? Area for z0 = 1.00 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 23 Finding Area Using Table 3-Example A probability of the form can be obtained from Table 3 (page:720-721 textbook) directly. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 24 Finding Area Using Table 3-Example A probability of the form can be calculated based on the complement probability. To find an area to the right of a z-value, find the area in Table 3 (page:720-721 textbook) and subtract from 1. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 25 Finding Area Using Table 3-Example Like with our discrete distributions, a probability of the form can be calculated from two cumulative probabilities. To find an area between two values of , find the two areas in Table 3, and subtract one from the other. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 26 Finding The Value of z Using Table 3-Example One can use Table 3 (page:720-721 textbook) to solve for the value of that results in a given area or probability. Example Working Backwards 1: Find the value of such that Solution: 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 27 Finding The Value of z Using Table 3-Example Again, one can use Table 3 (page:720-721 textbook) to solve for the value of that results in a given area or probability. Example Working Backwards 2: Find the value of such that.. Solution: 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 28 Finding The Value of z Using Table 3-Example Example Working Backwards 3: Find the value of such that 0.95 of the area is within standard deviations of the mean. Solution: By symmetry of the standard normal distribution, there must be an area of. to the right of and to the left of , for. Thus, the area to the left of equals This number is found in the interior of Table 3 in the row for and the column. So,. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 29 The Empirical Rule Recall: By the Empirical Rule, approximately of measurements lie within standard deviations of the mean. We have now shown that there is exactly within standard deviations of the mean, which rounds to. 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 30 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 31 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 32 Finding Area (Probability) Using Table 3-Exercise Exercise: Use Table 3 (page:720-721 textbook) to compute area or probabilities with given z-values for a standard normal random variable. 1. =? 2. =? 3. =? 4. =? 5. =? 6. =? 7. =? 8. =? 9. =? 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 33 Finding Area (Probability) Using Table 3-Exercise (cont’d) 1. Since the standard normal Table gives only areas to the left of a given z values, we can re-write this probability as the difference between two probabilities, each involving area to the left of a number (see also portions of the Table indicating this computations): (1.24 < z < 1.70) = (z < 1.70) − (z < 1.24) = 0.9554-0.8925 = 0.0629 9/26/2024 Chapter 6: The Normal Probability Distribution by Ahmad Farooqi, PhD 34 Finding Area (Probability) Using Table 3-Exercise (cont’d) 8. This area is to the left of a number and so we don't have to manipulate. However, the number -0.437 falls between -0.43 and -0.44 but it is close to -0.44. Therefore, you have two options, either find the areas P(z< -0.44) and P(z