Process Capability Principles

Quick reference

• 00:05 Hi, I'm Ray Sheen.
• 00:06 We've talked about process stability.
• 00:09 Now, I wanna talk about process capability.
• 00:12 Process capability is a quantified metric that compares the needs
• 00:17 of the customer with the process performance.
• 00:20 Think that is the voice of the customer divided by the voice of the process.
• 00:24 The voice of the customer will be expressed as a specification target value
• 00:29 and tolerance limits on that process parameter.
• 00:32 In particular, we'll need the upper spec limit and the lower spec limit for
• 00:36 the performance parameter.
• 00:38 For the voice of the process,
• 00:39 we'll be using some of the descriptive statistic values.
• 00:42 The parameter mean and the standard deviation will be used for
• 00:45 variable data and the yield for attribute data.
• 00:49 With quantified voice of the customer and
• 00:51 quantified voice of the process, we can create the process capability metrics.
• 00:56 With variable data,
• 00:57 we calculate ratios that serve as the process capabilities indices.
• 01:01 These ratios of customer expectations divided by process performance are Cp and
• 01:06 Cpk for short term data and Pp and Ppk for long term data sets.
• 01:13 Attribute data uses a ratio of success and a look-up table.
• 01:17 The success ratio is the yield, defects per unit DPU, defects per opportunity DPO,
• 01:22 defects per million opportunity, DPMO and parts per million, PPM.
• 01:27 Once the yield has been calculated that value is used with look-up table to
• 01:31 determine the process capability index.
• 01:35 Now, all of this assumes the data is normal or at least near normal.
• 01:39 When the data is not normal, there are special statistical tools and
• 01:43 techniques that must be used to calculate process capability.
• 01:46 Frankly, if it's not normal,
• 01:47 the first thing I try to do is get the process to a condition of normalcy,
• 01:51 removing any special causes before I even begin to work on process capability.
• 01:57 So let's dig in to these indices of associated with the variable data.
• 02:00 The Cp, Cpk, Pp and Ppk, all four indices follow the same pattern.
• 02:06 There's a ratio of the desired performance for
• 02:08 a parameter divided by the actual process performance for that parameter.
• 02:13 The desired performance will be expressed using the specification limits, and
• 02:17 the actual process performance will be expressed using our descriptive statistics
• 02:21 of the process parameter.
• 02:23 So you may be wondering why there are four indices.
• 02:25 Each of them is a different take on the process performance data.
• 02:28 The Cp and Pp indices will provide a best case perspective.
• 02:33 These ratios assume the processes managed as designed and all is going well.
• 02:38 While the Cpk and Ppk indices will look at the current performance.
• 02:43 That means that the Cpk and
• 02:44 Ppk are what the customer and process are actually feeling.
• 02:48 So one immediate insight we have is that the best case that we'll ever have
• 02:52 are the Cc and Pp ratios.
• 02:55 Now, another perspective of the indices is that Cp and Cpk are short term
• 03:00 looks at the data, while Pp and Ppk are long term looks at the data.
• 03:05 So bottom line, Cpk is what the customer's feeling right now, and
• 03:09 Ppk is what the customer's been feeling for some time.
• 03:12 So let's look at the calculations.
• 03:14 I will talk about Cp and Pp first.
• 03:17 These are calculated in exactly the same manner.
• 03:20 The only difference is that the Cp is using the standard deviation from recent
• 03:23 experience, and Pp is using the standard deviation from the longer term history.
• 03:28 This calculation is the allowable range of performance
• 03:32 divided by the span of normal variation within the process output.
• 03:36 The allowable range based upon customer expectation
• 03:38 is the span from the upper spec limit to the lower spec limit.
• 03:42 And the normal performance variation will be the span for -3 standard deviations to
• 03:47 +3 standard deviations, which is a total of 6 standard deviations.
• 03:51 And as I said, the only difference between Cp and
• 03:54 Pp is the size of the data set used to calculate the standard deviation.
• 03:58 So, what does this look like?
• 04:00 Well, let's first consider the case where the Cp is greater than 1.
• 04:04 In that case, the span between the spec limits is greater than the span
• 04:08 between the 3 standard deviation lines.
• 04:11 And you can see in this diagram, the spec limits
• 04:14 are outside the 3 standard deviation lines of the normal distribution.
• 04:19 But when Cp is less than 1, the opposite condition exists.
• 04:23 The spec lines are still the same, but
• 04:25 the variation in the parameter is much higher, so the distribution is much wider.
• 04:30 Therefore, the span from -3 standard deviations to +3 standard deviations is
• 04:35 greater than the spec limits, and that means the ratio is less than 1.
• 04:40 The implication of this is that if the ratio was less than 1,
• 04:43 the process is always generating some out of spec results.
• 04:47 While if the ratio is greater than 1, the process has the potential to be generating
• 04:51 good results virtually every time.
• 04:54 Notice I said the potential.
• 04:56 We'll use the Cpk and Ppk to look at the reality.
• 04:59 The reality is that the process is seldom perfectly centered
• 05:03 in the middle of the specification limits.
• 05:05 It's either a little high or a little low, so a Cpk and
• 05:08 Ppk calculation will adjust for that.
• 05:11 They will modify the numerator to pick the distance from the mean or
• 05:14 average value of the data, to the closest specification limit.
• 05:19 The formula looks like this.
• 05:21 The minimum at the beginning of the formula just means that
• 05:23 you will use the smaller of the two ratios.
• 05:26 But since you're no longer using the full span,
• 05:29 from the upper spec limit to the lower spec limit, but
• 05:31 only a portion, you also need to use only a portion of the denominator.
• 05:35 In our case, that means we will only use the one side of the normal distribution,
• 05:39 which is just 3 standard deviations.
• 05:42 So let's us look at the diagram again.
• 05:44 In this case, the Cpk is less than 1, although the Cp is greater than 1.
• 05:49 You can see that the distribution of the actual values is shifted to the left or
• 05:52 the low side of the allowable range.
• 05:54 The difference from the lower spec limit to the mean or
• 05:57 x bar is significantly less than the width of the 3 standard deviations.
• 06:01 If the process output had been centered,
• 06:04 all of it could have fit within the spec limits,
• 06:06 which is why the Cp is greater than 1, even though the Cpk is now less than 1.
• 06:11 Let me wrap up with an illustration that I hope you can relate to.
• 06:16 Let's say we have a nice little garage or car port.
• 06:19 The width of the garage will be my upper spec limits and
• 06:22 lower spec limits, and I can either drive a car or ride a motorbike.
• 06:26 The width of the car or motorbike is analogous to my process width of -3
• 06:30 standard deviations to +3 standard deviations.
• 06:34 If I park the motorbike in the center of the garage, I have lots of
• 06:38 room on either side, and both the Cp and Cpk are much greater than 1.
• 06:43 If I park my car in the garage, it just barely fits.
• 06:47 In that case, my Cp and Cpk are just barely over 1.
• 06:51 Now, let's say it's late at night,
• 06:53 and I've been out with friends and maybe a little overtired.
• 06:57 As I pull my motorbike into the garage,
• 07:00 I don't quite line it up to be in the center.
• 07:02 Well, that's still okay.
• 07:04 Since the Cp was much greater than 1, I can be off to one side and
• 07:08 still have a Cpk greater than 1.
• 07:11 But if I'm driving my car, and I'm off to one side, I have a problem.
• 07:15 There was no allowance for a little bit of drift.
• 07:18 And while my Cp is still slightly greater than 1,
• 07:21 because I'm not centered, my Cpk is less than 1.
• 07:24 And I've got a problem. Process capability relates the actual performance
• 07:31 of the process to the specification limits we receive from the customer.
• 07:36 With these indices, we can quickly see if we have a design problem or
• 07:41 a process control problem.

Lesson notes are only available for subscribers.