Presentation is loading. Please wait.

Presentation is loading. Please wait.

Introductory Statistics Introductory Statistics

Published byJunior West Modified over 6 years ago

Similar presentations

Presentation on theme: "Introductory Statistics Introductory Statistics"— Presentation transcript:

1 Introductory Statistics Introductory Statistics

2 Outline of Lesson 05 Videos
Density Curve Rule Z-Score Converting Z-Score to Probability Percentiles for Normal Distribution QQ-Plots – Assessing Normality

3 The total area under the curve equals 1.
Density Curve The total area under the curve equals 1. The density curve always lies on or above the horizontal axis. Area inside curve equals 1. Horizontal Axis

4 Outline of Lesson 05 Videos
Density Curve Rule Z-Score Converting Z-Score to Probability Percentiles for Normal Distribution QQ-Plots – Assessing Normality

5 68-95-99.7 Rule The empirical rule:
Approx. 68% of all of the data fall within 1 standard deviation of the mean Approx. 95% of all of the data fall within 2 standard deviations of the mean Approx. 99.7% of all of the data fall within 3 standard deviations of the mean Mean - (# of Std Deviations * σ) = Lower Value Mean + (# of Std Deviations * σ) = Upper Value Sketching the normal distribution is strongly recommended. The mean incubation time of fertilized chicken eggs kept at a certain temperature is 21 day. Incubation times are normally distributed with a standard deviation (σ) of one day. According to the Empirical Rule, approximately 95% of incubations will have times between which two values? (1) = (19,23)

6 Rule

7 Rule The council for Graduate Medical Education found that medical residents’ mean number of hours worked in a week is The number of hours worked per week is normally distributed with a standard deviation of 6.9 hours. According to the Empirical Rule, approximately 95% of students will have work times per week between which two values? 95% of Data will fall within: *(6.9) = (67.9,95.5) What about 99.7% of students? 99.7% of Data will fall within: *(6.9) = (61,102.4) What approximate percent of data will fall between 74.8 hours and 88.6 hours? Both 74.8 and 88.6 are 1 standard deviation from the mean so 68% of the data will fall within those two points

8 Rule

9 Outline of Lesson 05 Videos
Density Curve Rule Z-Score Converting Z-Score to Probability Percentiles for Normal Distribution QQ-Plots – Assessing Normality

10 Standard Normal Distribution
Suppose the variable X is normally distributed with mean µ and standard deviation σ. Then the random variable Z is normally distributed with mean 0 and standard deviation of 1. The Z-Score is calculated as follows: Z-Score represents the number of standard deviations a value (X) is away from the mean (µ). Uses for the Z-Score Determine values that may be extreme Compare values from two different types of normal distributions Being capable of using normal probabilities to calculate the probabilities of specific events

11 Determining Extreme Values
The mean incubation time of fertilized chicken eggs kept at a certain temperature is 21 day. Incubation times are normally distributed with a standard deviation of one day. What is the Z-Score of an incubation time of 20.5 days? Would that be considered extreme? How about 25 days? Z= /1 = -0.5 – Not too extreme Z=25-21/1 = 4 Appears to be extreme The council for Graduate Medical Education found that medical residents’ mean number of hours worked in a week is The number of hours worked per week is normally distributed with a standard deviation of 6.9 hours. What is the Z-Score of a study time in a week of 84 hours? Would that be considered extreme? How about 110 hours? Z=( )/6.9 = Not too extreme Z=( )/6.9 = Appears to be extreme

12 Comparing Scores across different distributions
Who had the best baseball season?

13 Outline of Lesson 05 Videos
Density Curve Rule Z-Score Converting Z-Score to Probability Percentiles for Normal Distribution QQ-Plots – Assessing Normality

14 Steps to Finding Area or Probability Under Normal Curve
Convert (standardize) the values of X using the standard normal variable Z (Find the Z-Score) Find the area under the standard normal curve by using the applet

15 Steps to Finding Area or Probability Under Normal Curve
The length of human pregnancies from conception to birth is normally distributed with mean 266 Days and a standard deviation of 16 days. What is the probability of a pregnancy lasts less than 240 day? Convert (standardize) the values of X using the standard normal variable Z (Find the Z-Score) Find the area under the standard normal curve (Using the applet) Z = (240 – 266) / 16 = 0.052

16 Steps to Finding Area or Probability Under Normal Curve
The length of human pregnancies from conception to birth is normally distributed with mean 266 Days and a standard deviation of 16 days. What is the probability of a pregnancy lasts more than 270 days? Convert (standardize) the values of X using the standard normal variable Z (Find the Z-Score) Find the area under the standard normal curve (Using the applet) Z = (270 – 266) / 16 = 0.25 0.401

17 Steps to Finding Area or Probability Under Normal Curve
The length of human pregnancies from conception to birth is normally distributed with mean 266 Days and a standard deviation of 16 days. What is the probability that a pregnancy lasts between 241 and 291 days? Convert (standardize) the values of X using the standard normal variable Z (Find the Z-Score) Find the area under the standard normal curve (Using the applet) Z = (241 – 266) / 16 = Z = (291 – 266) / 16 = 1.563 0.882

18 Outline of Lesson 05 Videos
Density Curve Rule Z-Score Converting Z-Score to Probability Percentiles for Normal Distribution QQ-Plots – Assessing Normality

19 Steps to Finding a value when given the area or percentile (less than 50th Percentile)
If needed, click on the areas with the normal distribution curve so that the only area shaded in blue is on the left side of the left line Type in the Percentile number in decimal form in the area box. (e.g. 40th Percentile) Use the Z score under the left red line and put into the formula X = µ + (Z*σ) to find the value of interest (X) which is the percentile you are looking for (e.g. µ = 266 Days and σ = 16 days for human pregnancies. X = µ + (Z*σ) = (-.253 * 16) =

20 Steps to Finding a value when given the area or percentile (greater than 50th Percentile)
If needed, click on the areas with the normal distribution curve so that the areas shaded in blue are on the left side of the left line and in between both red lines Type in the Percentile number in decimal form in the area box. (e.g. 90th Percentile) Use the Z score under the right red line and put into the formula X = µ + (Z*σ) to find the value of interest (X) which is the percentile you are looking for (e.g. µ = 266 Days and σ = 16 days for human pregnancies. X = µ + (Z*σ) = (1.28 * 16) =

21 Outline of Lesson 05 Videos
Density Curve Rule Z-Score Converting Z-Score to Probability Percentiles for Normal Distribution QQ-Plots – Assessing Normality

22 QQ Plot Normally Distributed Not Normally Distributed

Download ppt "Introductory Statistics Introductory Statistics"

Similar presentations

Chapter 2: The Normal Distributions

Chapter 2: The Normal Distributions
Chapter 6 Continuous Random Variables and Probability Distributions

Chapter 6 Continuous Random Variables and Probability Distributions
The Normal Distribution

The Normal Distribution
Normal distribution. An example from class HEIGHTS OF MOTHERS CLASS LIMITS(in.)FREQUENCY 52-530.5 53-541.5 54-551 55-562 56-576.5 57-5818 58-5934.5 59-6079.5.

Normal distribution. An example from class HEIGHTS OF MOTHERS CLASS LIMITS(in.)FREQUENCY
The Normal Distributions

The Normal Distributions
The Normal Distributions

The Normal Distributions
1. Normal Curve 2. Normally Distributed Outcomes 3. Properties of Normal Curve 4. Standard Normal Curve 5. The Normal Distribution 6. Percentile 7. Probability.

1. Normal Curve 2. Normally Distributed Outcomes 3. Properties of Normal Curve 4. Standard Normal Curve 5. The Normal Distribution 6. Percentile 7. Probability.
Statistics Normal Probability Distributions Chapter 6 Example Problems.

Statistics Normal Probability Distributions Chapter 6 Example Problems.
§ 5.2 Normal Distributions: Finding Probabilities.

§ 5.2 Normal Distributions: Finding Probabilities.
Chapter 7: Normal Probability Distributions

Chapter 7: Normal Probability Distributions
Using the Empirical Rule. Normal Distributions These are special density curves. They have the same overall shape  Symmetric  Single-Peaked  Bell-Shaped.

Using the Empirical Rule. Normal Distributions These are special density curves. They have the same overall shape  Symmetric  Single-Peaked  Bell-Shaped.
Section 7.1 The STANDARD NORMAL CURVE

Section 7.1 The STANDARD NORMAL CURVE
The Standard Normal Distribution Z-score Empirical Rule Normal Distribution.

The Standard Normal Distribution Z-score Empirical Rule Normal Distribution.
Essential Statistics Chapter 31 The Normal Distributions.

Essential Statistics Chapter 31 The Normal Distributions.
AP Statistics Chapter 2 Notes. Measures of Relative Standing Percentiles The percent of data that lies at or below a particular value. e.g. standardized.

AP Statistics Chapter 2 Notes. Measures of Relative Standing Percentiles The percent of data that lies at or below a particular value. e.g. standardized.
Copyright © 2013, 2009, and 2007, Pearson Education, Inc. Chapter 6 Probability Distributions Section 6.2 Probabilities for Bell-Shaped Distributions.

Copyright © 2013, 2009, and 2007, Pearson Education, Inc. Chapter 6 Probability Distributions Section 6.2 Probabilities for Bell-Shaped Distributions.
Using the Empirical Rule. Normal Distributions These are special density curves. They have the same overall shape  Symmetric  Single-Peaked  Bell-Shaped.

Using the Empirical Rule. Normal Distributions These are special density curves. They have the same overall shape  Symmetric  Single-Peaked  Bell-Shaped.
Standard Deviation and the Normally Distributed Data Set

Standard Deviation and the Normally Distributed Data Set
§ 5.3 Normal Distributions: Finding Values. Probability and Normal Distributions If a random variable, x, is normally distributed, you can find the probability.

§ 5.3 Normal Distributions: Finding Values. Probability and Normal Distributions If a random variable, x, is normally distributed, you can find the probability.
CONTINUOUS RANDOM VARIABLES

CONTINUOUS RANDOM VARIABLES

Similar presentations

Ads by Google