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Statistics 11/7/2005 1 Statistics: Normal Curve CSCE 115.

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Presentation on theme: "Statistics 11/7/2005 1 Statistics: Normal Curve CSCE 115."— Presentation transcript:

1 Statistics 11/7/2005 1 Statistics: Normal Curve CSCE 115

2 Statistics 11/7/2005 2 Normal distribution l The bell shaped curve l Many physical quantities are distributed in such a way that their histograms can be approximated by a normal curve

3 Statistics 11/7/2005 3 Examples l Examples of normal distributions: »Height of 10 year old girls and most other body measurements »Lengths of rattle snakes »Sizes of oranges l Distributions that are not normal: »Flipping a coin and count of number of heads flips before getting the first tail »Rolling 1 die

4 Statistics 11/7/2005 4 Flipping Coins Experiment l Experiment: Flip a coin 10 times. Count the number of heads l Expected results: If we flip a coin 10 times, on the average we would expect 5 heads. l Because tossing a coin is a random experiment, the number of heads may be more or less than expected.

5 Statistics 11/7/2005 5 Flipping Coins Experiment l Carry out the experiment l But the average was supposed to be 5 l What can we do to improve the results? l How many times do we have to carry out the experiment to get good results? l Faster: Use a computer simulation

6 Statistics 11/7/2005 6 Experiment: Flipping coins

7 Statistics 11/7/2005 7 Experiment: Flipping coins

8 Statistics 11/7/2005 8 Experiment: Flipping coins

9 Statistics 11/7/2005 9 Experiment: Flipping coins

10 Statistics 11/7/2005 10 Theory l If the number of trials of this type increase, the histogram begins to approximate a normal curve

11 Statistics 11/7/2005 11 Normal Curve l One can specify mean and standard deviation l The shape of the curve does not depend on mean. The curve moves so it is always centered on the mean l If the st. dev. is large, the curve is lower and fatter l If the st. dev, is small, the curve is taller and skinnier

12 Statistics 11/7/2005 12 Normal Curve The normal curve with mean = 0 and std. dev. = 1 is often referred to as the z distribution

13 Statistics 11/7/2005 13 Normal Curve

14 Statistics 11/7/2005 14 Normal Curve

15 Statistics 11/7/2005 15 Normal Curve

16 Statistics 11/7/2005 16 Normal Curve l 50% of the area is right of the mean l 50% of the area is left of the mean

17 Statistics 11/7/2005 17 Normal Curve l The total area under the curve is always 1. l 68% (about 2/3) of the area is between 1 st. dev. left of the mean to 1 st. dev. right of the mean. l 95% of the area is between 2 st. dev. left of the mean to 2 st. dev. right of the mean.

18 Statistics 11/7/2005 18 Normal Curve 99.7% 95.4% 68.2% 50%

19 Statistics 11/7/2005 19 Example: Test Scores l Several hundred students take an exam. The average is 70 with a standard deviation of 10. l About 2/3 of the scores are between 60 and 80 l 95% of the scores are between 50 and 90 l About 50% of the students scored above 70

20 Statistics 11/7/2005 20 Example: Test Scores

21 Statistics 11/7/2005 21 Example: Test Scores l Suppose that passing is set at 60. What percent of the students would be expected to pass? l Solution: (60 - 70)/10 = -1. Hence passing is 1 standard deviation below the mean. l 34.1% of the scores are between 60 and 70 l 50% of the scores are above 70 l 84.1% of students would expected to pass

22 Statistics 11/7/2005 22 Example: Test Scores Alternate solution l Suppose that passing is set at 60. What percent of the students would be expected to pass? l Solution: According to our charts, 15.9% of the scores will be less than 60 (less than –1 standard deviations below the mean). l 100% – 15.9% = 84.1% of the students pass because they are right of the –1 st. dev. line.

23 Statistics 11/7/2005 23 Grading on the Curve l Assumes scores are normal l Grades are based on how many standard deviations the score is above or below the mean l The grading curve is determined in advanced

24 Statistics 11/7/2005 24 Example: Grading on the Curve l A 1 st. dev. or greater above the mean l B From the mean to one st. dev. above the mean l C From one st. dev. below mean to mean l D From two st. dev below mean to one st. dev. below mean l F More than two st. dev. below mean Selecting these breaks is completely arbitrary. One could assign other grade break downs.

25 Statistics 11/7/2005 25

26 Statistics 11/7/2005 26 Example: Grading on the Curve l Range (in st. dev.) Expected percent Grade from to of scores A +1 50% - 34.1% = 15.9% B 0 +1 34.1% C -1 0 34.1% D -2 -1 13.6% F -2 50% - 34.1 - 13.6% = 2.3%

27 Statistics 11/7/2005 27 Example: Grading on a Curve l Assume that the mean is 70, st. dev. is 10 l Joan scores 82. What is her grade? (82-70)/10 = 12/10 = 1.2 She scored 1.2 st. dev. above the mean. She gets an A

28 Statistics 11/7/2005 28 Example: Grading on a Curve l Assume that the mean is 70, st. dev. 10 l Tom scores 55. What is his grade? (55 - 70)/10 = -15/10 = -1.5 He scored 1.5 st. dev. below the mean. He gets a D

29 Statistics 11/7/2005 29 Example: Light bulbs l Assume that the life span of a light bulb is normally distributed with a mean of 1000 hours and a standard deviation of 100. The manufacturer guaranties that the bulbs will last 800 hours. What percent of the light bulbs will fail before the guarantee is up?

30 Statistics 11/7/2005 30 Example: Light bulbs l Solution: (800-1000)/100 = -2 l The percentage of successes is 13.6% + 34.1% + 50% = 97.7% l The percentage of failures is 100% - 97.7% = 2.3%

31 Statistics 11/7/2005 31 Example: Mens socks l Assume that the length of men’s feet are normally distributed with a mean of 12 inches and a standard deviation of.5 inch. A certain brand of “one size fits all” strechy socks will fit feet from 11 inches to 13.5 inches. What % of all men cannot wear the socks?

32 Statistics 11/7/2005 32 Example: Mens socks l (11-12)/.5 = -2 l (13.5 – 12)/.5 = 3 l Hence men from 2 standard deviations below the mean and 3 standard deviations above the mean can wear the socks -2 to +2 st. dev. 95.4% +2 to +3 st. dev. 2.2% -2 to + 3 st. dev. 97.6% of men can wear the socks. 100% - 97.6% = 2.4% cannot wear them.

33 Statistics 11/7/2005 33 Normal Distributions l We might be interested in: »The normal probability (or frequency) »The cumulative area below the curve

34 Statistics 11/7/2005 34 Normal Curves

35 Statistics 11/7/2005 35 Normal Curves

36 Statistics 11/7/2005 36 Excel and the Normal Distribution l Cumulative probabilities are measured from “- infinity”. l NORMDIST(x, mean, st dev, cumulative) cumulative - true cumulative false probability l NORMINV(probability, mean, st dev) returns the x value that gives the specified cumulative probability

37 Statistics 11/7/2005 37 Excel and the Normal Distribution

38 Statistics 11/7/2005 38 Excel and the Normal Distribution l The following functions assume mean = 0 and st. dev. = 1 l NORMSDIST(x) returns cumulative distribution l NORMSINV(probability) returns the x value that obtains the specify cumulative probability

39 Statistics 11/7/2005 39 Example: Excel l Assume mean = 12, st. dev. =.5 and the men’s foot distribution used earlier. l What percent of the men’s feet would be expected to be 13 inches long or shorter? =NORMDIST(13, 12,.5, TRUE) =.977 or 97.7% l What is the probability that a randomly chosen foot would be exactly 13 inches long? =NORMDIST(13, 12,.5, FALSE) =.108

40 Statistics 11/7/2005 40 Example: Excel l Assume mean = 70, st. dev. = 10 and the grade distribution used earlier. l What percent of the students would be expected to score 90 or below? =NORMDIST(90, 70, 10, TRUE) =.977 or 97.7% l What is the probability that a randomly chosen person scores (exactly) 90? Because this is a discrete distribution =NORMDIST(90.5, 70, 10, TRUE) -NORMDIST(89.5, 70, 10, TRUE) =.0054

41 Statistics 11/7/2005 41 Example: Excel l Assume the grade distribution used earlier with a mean of 70 and st. dev. of 10. What percentage of the students are expected to pass with a D or C? (That is, with scores between 50 and 70)? Passing with a D 70 - 2 * 10 = 50 Passing with a B- 70 We are looking for 50 <= scores < 70 = NORMDIST(70, 70, 10, TRUE) - NORMDIST(50, 70, 10, TRUE) =.5 - NORMDIST(50, 70, 10, TRUE) =.477 or 47.7%

42 Statistics 11/7/2005 42 Example: Excel

43 Statistics 11/7/2005 43 Example: Excel l What score does one need to be in the top 10%? To be in the top 10%, the student must do better than 100% - 10% = 90% of the students. =NORMINV(90%, 70, 10) = 82.8 (or 83)

44 Statistics 11/7/2005 44 Example: Excel

45 Statistics 11/7/2005 45

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