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Engineering Probability and Statistics - SE-205 -Chap 1 By S. O. Duffuaa.

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Presentation on theme: "Engineering Probability and Statistics - SE-205 -Chap 1 By S. O. Duffuaa."— Presentation transcript:

1 Engineering Probability and Statistics - SE-205 -Chap 1 By S. O. Duffuaa

2 Course Objectives w Introduce the students to basic probability and statistics and demonstrate its wide application in the area of Systems Engineering.

3 Main Course Outcomes w Students should be able to perform: Summarize and present data Describe probability distributions Compute probabilities using density/mass functions Conduct interval estimation Make inference about populations Use statistical package/Minitab

4 Text Book and References w “Applied Statistics and Probability for Engineers “ by D. C. Montgomery and Runger, 1994. w “Probability and Statistics for Engineers and Scientists” 5 th by Walpole and Mayers. w Statistics by Murry Speigel

5 Course Policy w Home-works and attendance 15% w Quizzes 15% w Exam1 20% w Exam II 20% w Final Exam 30%

6 SE- 205 Place in SE Curriculum w Central Course w Prerequisite for 7 SE courses SE 303, SE 320, SE 323, SE 325, SE 447, SE 480, SE 463 and may be others. See SE Curriculum Tree

7 Engineering Problem Solving w Develop clear and concise problem description w Identify the important factors in the problem. w Propose a model for the problem w Conduct appropriate experimentation w Refine the model

8 Engineering Problem Solving w Validate the solution w Conclusion and recommendations

9 Statistics Science of data collection, summarization, presentation and analysis for better decision making. How to collect data ? How to summarize it ? How to present it ? How do you analyze it and make conclusions and correct decisions ?

10 Role of Statistics w Many aspects of Engineering deals with data – Product and process design w Identify sources of variability w Essential for decision making

11 Data Collection w Observational study Observe the system Historical data w The objective is to build a system model usually called empirical models w Design of experiment Plays key role in engineering design

12 Data Collection w Sources of data collection:  Observation of something you can’t control (observe a system or historical data)  Conduct an experiment  Surveying opinions of people in social problem

13 Statistics w Divided into : Descriptive Statistics Inferential Statistics

14 Forms of Data Description w Point summary w Tabular format w Graphical format w Diagrams

15 Point Summary 1) Central tendency measures Sample Mean x =  x i /n Population Mean(µ) Median --- Middle value Mode --- Most frequent value Percentile

16 Point Summary 2) Variability measures Range = Max x i - Min x i Variance = V = S 2 =  (x i – x ) 2 / n-1 also = Standard deviation = S S = Square root (V) Coefficient of variation = S/ x Inter-quartile range (IQR)  (x i 2 ) – {[(  x i ) 2 ]/n} n -1

17 Diagrams: Dot Diagram w A diagram that has on the x-axis the points plotted : Given the following grades of a class: 50, 23, 40, 90, 95, 10, 80, 50, 75, 55, 60, 40. 010050....

18 Dot Diagram w A diagram that has on the x-axis the points plotted : Given the following grades of a class: 50, 23, 40, 90, 95, 10, 80, 50, 75, 55, 60, 40. 010050....

19 Graphical Format Time Frequency Plot The Time Frequency Plot tells the following : 1) The Center of Data 2) The Variability 3) The Trends or Shifts in the data Control Chart

20 Time Frequency Plot

21

22 Lower control limit = 82.54 x = 91.50 Upper control limit = 100.5 Control Charts

23 Central Line = Average ( X ) Lower Control Limit (LCL)= X – 3S Upper Control Limit (UCL)= X + 3S Control Charts

24 Lecture Objectives w Sample and population w Random sample w Present the following: w Stem-leaf diagram w The frequency distribution w Histogram

25 Population and Sample w Population is the totality of observations we are concerned with. w Example: All Engineers in the Kingdom, All SE students etc. w Sample : Subset of the population 50 Engineers selected at random, 10 SE students selected at random.

26 Mean and Variance w Sample mean X-bar w Population mean µ w Sample variance S 2 w Population variance σ 2

27 Stem-And –Leaf Diagram w Each number x i is divided into two parts the stem consisting of one or two leading digits w The rest of the digits constitute the leaf. w Example if the data is 126 then 12 is stem and 6 is the leaf. What is the stem and leaf for 76

28 Data Table 1.1 Compressive Strength of 80 Aluminum Lithium Alloy 105 221 183 186 121 181 180 143 97 154 153 174 120 168 167 141 245 228 174 199 181 158 176 110 163 131 154 115 160 208 158 133 207 180 190 193 194 133 156 123 134 178 76 167 184 135 229 146 218 157 101 171 165 172 158 169 199 151 142 163 145 171 148 158 160 175 149 87 160 237 150 135 196 201 200 176 150 170 118 149

29 Stem-And-Leaf f Stem leaf frequency 7 61 8 71 9 71 10 5 12 11 5 0 83 12 1 0 33 13 4 1 3 5 3 5 6 14 2 9 5 8 3 1 6 9 8 15 4 7 1 3 4 0 8 8 6 8 0 8 12 16 3 0 7 3 0 5 0 8 7 9 10 17 8 5 4 4 1 6 2 1 0 6 10 18 0 3 6 1 4 1 0 7 19 9 6 0 9 3 4 6 20 7 1 0 8 4 21 8 1 22 1 8 93 23 7 1 24 5 1

30 Number of Stems Considerations StemLeaf 6 1 3 4 5 5 6 7 0 1 1 3 5 7 8 8 9 8 1 3 4 4 7 8 8 9 2 3 5

31 Stem number considerations Stem leaf 6L1 3 4 6U5 5 6 7L0 1 1 3 7U5 7 8 8 8L1 3 4 4 8U7 8 8 9L2 3 9U5

32 Number of Stems w Between 20 and 5 w Roughly  n where n number of data points

33 Percentiles w Pth percentile of the data is a value where at least P% of the data takes on this value or less and at least (1-P)% of the data takes on this value or more. w Median is 50 th percentile. ( Q 2 ) w First quartile Q 1 is the 25 th percentile. w Third quartile Q 3 is the 75 th percentile.

34 Percentile Computation : Example Data : 5, 7, 25, 10, 22, 13, 15, 27, 45, 18, 3, 30 Compute 90 th percentile. 1. Sort the data from smallest to largest 3, 5, 7, 10, 13, 15, 18, 22, 25, 27, 30, 45 2. Multiply 90/100 x 12 = 10.8 round it to to the next integer which is 11. Therefore the 90 th percentile is point # 11 which is 30.

35 Percentile Computation : Example w If the product of the percent with the number of the data came out to be a number. Then the percentile is the average of the data point corresponding to this number and the data point corresponding to the next number. w Quartiles computation is similar to the percentiles.

36 w Pth percentile = (P/ 100)*n = r double (round it up & take its rank) (r) integer (take Avg. of its rank & # after) w Inter-quartile range = Q 3 – Q 1 w Frequency Distribution Table : 1) # class intervals (k) = 5 < k < 20 k ~  n 2) The width of the intervals (W) = Range/k = (Max-Min) /  n

37 Class Interval (psi) Tally (# data in this interval ) Frequency Relative Frequency = (Frequency/ n) Cumulative Relative Frequency 70 ≤ x < 90||20.0250 90 ≤ x < 110|||30.03750.0625 110 ≤ x < 130|||| |60.07500.1375 130 ≤ x < 150|||| |||| ||||140.17500.3125 150 ≤ x < 170|||| |||| |||| |||| ||220.27500.5875 170 ≤ x <1 90|||| |||| |||| ||170.21250.8000 190 ≤ x < 210|||| 100.12500.9250 210 ≤ x < 230||||40.05000.9750 230 ≤ x < 250||20.02501.0000

38 70 90 110 130 150 170 190 210 230 250 Compressive Strength (psi) Frequency 25 20 15 10 5 0

39 Histogram: is the graph of the frequency distribution table that shows class intervals V.S. freq. or (Cumulative) Relative freq. 100 150 200 250

40 1.5 IQR IQR1.5 IQR Outliers Extreme OutliersOutliers First QuartileSecond Quartile Third Quartile Whisker extends to largest data point within 1.5 interquartile ranges from third quartile Whisker extends to smallest data point within 1.5 interquartile ranges from first quartile Extreme Outliers

41 100 150 200 250 Strength

42 120 110 100 90 80 70 1 2 3 Plant Quantity Index


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