Statistical Process Control

1. Statistical Process Control • Take periodic samples from a process • Plot the sample points on a control chart • Determine if the process is within limits • Correct the process before defects occur

2. Common Causes

3. Assignable Causes Average Grams (a) Mean

4. Assignable Causes Average Grams (b) Spread

5. Assignable Causes Average Grams (c) Shape

6. Control Chart Examples UCL Nominal Variations LCL Sample number

7. Control Charts Assignable causes likely UCL Nominal LCL 1 2 3 Samples

8. Mean -3 -2 -1 +1 +2 +3 68.26% 95.44% 99.74% The Normal Distribution  = Standard deviation

9. Control Limits and Errors Type I error: Probability of searching for a cause when none exists UCL Process average LCL (a) Three-sigma limits

10. Control Limits and Errors Type I error: Probability of searching for a cause when none exists UCL Process average LCL (b) Two-sigma limits

11. Control Limits and Errors Type II error: Probability of concluding that nothing has changed UCL Shift in process average Process average LCL (a) Three-sigma limits

12. Control Limits and Errors Type II error: Probability of concluding that nothing has changed UCL Shift in process average Process average LCL (b) Two-sigma limits

13. Constructing a Control Chart • Decide what to measure or count • Collect the sample data • Plot the samples on a control chart • Calculate and plot the control limits on the control chart • Determine if the data is in-control • If non-random variation is present, discard the data (fix the problem) and recalculate the control limits

14. Types of Data • Attribute data • Product characteristic evaluated with a discrete choice • Good/bad, yes/no • Variable data • Product characteristic that can be measured • Length, size, weight, height, time, velocity

15. Control Charts For Attributes • p Charts • Calculate percent defectives in a sample; • an item is either good or bad • c Charts • Count number of defects in an item

16. p - Charts Based on the binomial distribution

17. UCL = p + 3 p(1-p) /n = 0.10 + 3 0.10 (1-0.10) /100 = 0.190 p-Chart Calculations Proportion SampleDefect Defective 1 6 .06 2 0 .00 3 4 .04 . . . . . . 20 18 .18 200 • LCL= p - 3 p(1-p) /n • = 0.10 + 3 0.10 (1-0.10) /100 • = 0.010 100 jeans in each sample total defectives total sample observations 200 20 (100) p = = = 0.10

18. Example p - Chart 0.2 0.18 0.16 0.14 0.12 0.1 Proportion defective 0.08 0.06 0.04 0.02 0 Sample number 0 2 4 6 8 10 12 14 16 18 20 . .

19. c - Charts Based on the Poisson distribution

20. c - Chart Calculations Count # of defects per roll in 15 rolls of denim fabric. SampleDefects 1 12 2 8 3 16 . . . . 15 15 190

21. Example c - Chart 24 21 18 15 . 12 Number of defects 9 6 3 0 0 2 4 6 8 10 12 14 Sample number

22. Control Charts For Variables • Mean chart (X-Bar Chart) • Measures central tendency of a sample • Range chart (R-Chart) • Measures amount of dispersion in a sample • Each chart measures the process differently. Both the process average and process variability must be in control for the process to be in control.

23. Example: Control Charts for Variable Data Slip Ring Diameter (cm) Sample 1 2 3 4 5 X R 1 5.02 5.01 4.94 4.99 4.96 4.98 0.08 2 5.01 5.03 5.07 4.95 4.96 5.00 0.12 3 4.99 5.00 4.93 4.92 4.99 4.97 0.08 4 5.03 4.91 5.01 4.98 4.89 4.96 0.14 5 4.95 4.92 5.03 5.05 5.01 4.99 0.13 6 4.97 5.06 5.06 4.96 5.03 5.01 0.10 7 5.05 5.01 5.10 4.96 4.99 5.02 0.14 8 5.09 5.10 5.00 4.99 5.08 5.05 0.11 9 5.14 5.10 4.99 5.08 5.09 5.08 0.15 10 5.01 4.98 5.08 5.07 4.99 5.03 0.10 50.09 1.15

24. Constructing a Range Chart

25. Constructing A Mean Chart

26. 3s Control Chart Factors Sample size X-chart R-chart nA2D3D4 2 1.88 0 3.27 3 1.02 0 2.57 4 0.73 0 2.28 5 0.58 0 2.11 6 0.48 0 2.00 7 0.42 0.08 1.92 8 0.37 0.14 1.86

27. Process Capability • Range of natural variability in process • Measured with control charts • Process cannot meet specifications if natural variability exceeds tolerances • 3-sigma quality • specifications equal the process control limits. • 6-sigma quality • specifications twice as large as control limits

28. Process Capability Natural control limits Natural control limits Design specs PROCESS PROCESS Process can meet specifications Process cannot meet specifications Natural control limits Design specs PROCESS Process capability exceeds specifications

29. Acceptance Sampling Outline • Sampling • Some sampling plans • A single sampling plan • Some definitions • Operating characteristic curve • Developing a single sampling plan

30. Necessity of Sampling • In most cases 100% inspection is too costly. • In some cases 100% inspection may be impossible. • If only the defective items are returned, repair or replacement may be cheaper than improving quality. But, if the entire lot is returned on the basis of sample quality, then the producer has a much greater motivation to improve quality.

31. Some Sampling Plans • Single sampling plans: • Most popular and easiest to use • Two numbers n and c • If there are more than c defectives in a sample of size n the lot is rejected; otherwise it is accepted • Double sampling plans: • A sample of size n1 is selected. • If the number of defectives is less than or equal to c1 than the lot is accepted. • Else, another sample of size n2 is drawn. • If the cumulative number of defectives in both samples is more than c2 the lot is rejected; otherwise it is accepted.

32. Some Sampling Plans • Sequential sampling • An extension of the double sampling plan • Items are sampled one at a time and the cumulative number of defectives is recorded at each stage of the process. • Based on the value of the cumulative number of defectives there are three possible decisions at each stage: • Reject the lot • Accept the lot • Continue sampling

33. A Single Sampling Plan Consider a single sampling plan with n = 10 and c = 2 • Compute the probability that a lot will be accepted with a proportion of defectives, p = 0.10 • If a producer wants a lot with p = 0.10 to be accepted, the sampling plan has a risk of _______________

34. A Single Sampling Plan • Compute the probability that a lot will be accepted with a proportion of defectives, p = 0.30 • If a consumer wants to reject a lot with p = 0.30, the sampling plan has a risk of _____________

35. Some Definitions • Acceptable quality level (AQL) Acceptable fraction defective in a lot • Lot tolerance percent defective (LTPD) Maximum fraction defective accepted in a lot • Producer’s risk,  Type I error = P(reject a good lot) • Consumer’s risk,  Type II error = P(accept a bad lot)

36. { 0.80 0.60 0.40 0.20 { 0.20 0.18 0.02 0.04 0.06 0.08 0.10 0.12 0.14 0.16 Operating Characteristic Curve 1.00 1-a = 0.05 OC curve for n and c Probability of acceptance, Pa b = 0.10 Percent defective AQL LTPD

37. Example • Develop a sampling plan with AQL = 0.1 LTPD = 0.3  = 0.05  = 0.10

38. Average Outgoing Quality

39. Average Outgoing Quality

40. Average Outgoing Quality

41. AOQ Curve 0.015 AOQL 0.010 Average Outgoing Quality 0.005 0.10 0.09 0.01 0.02 0.03 0.04 0.05 0.06 0.07 0.08 AQL LTPD (Incoming) Percent Defective

42. Reading and Exercises • Reading • Chapter 8 pp. 323-36 (self-study) • Technical Note 8 pp. 346-60 • Exercises: • Technical Note Problems 3,12,13