Six Sigma Principles

Quick reference

• 00:04 Hi, I'm Ray Sheen.
• 00:05 Well, we've looked at the foundational elements of Six Sigma and
• 00:09 Lean Manufacturing, it's now time to blend them together to get Lean Six Sigma.
• 00:14 Six Sigma projects are structured to solve problems.
• 00:19 At the strategic level,
• 00:20 Six Sigma solves the problem of achieving breakthrough performance improvement.
• 00:24 It finds and eliminates the root cause that creates problems and
• 00:28 issues for internal and external customers.
• 00:32 One way it does this is to change the mindset about quality.
• 00:36 The conventional quality mindset is that anything within specs out is good.
• 00:41 Outside the specs, it's bad.
• 00:43 A product or process could be operating just barely within spec, and that's not
• 00:48 considered to be a problem, even though a minor hiccup will turn things out of spec.
• 00:53 From a problem-solving perspective, we don't want to
• 00:56 rely on just barely being in spec in order to get desired performance.
• 01:00 We want a stable, predictable process that we can tune for exactly what is needed.
• 01:06 We want the formula so
• 01:07 we can precisely choose the input variables to get the desired output.
• 01:12 One of the values of Six Sigma is that it separates out the most significant root
• 01:18 causes, the vital few inputs to axis, that will deliver the desired output or why.
• 01:25 When Six Sigma delivers breakthrough performance,
• 01:28 it often changes the average output value known as the process mean to make it
• 01:33 much higher, lower, or closer to the target value.
• 01:36 It also reduces the uncertainty or variability.
• 01:40 This improves the predictability of the output and
• 01:44 can again change the game since the customer using the y output now
• 01:49 has rock solid confidence in the exact performance they will see.
• 01:54 Let me highlight some of the key principles.
• 01:57 In order to better understand the Six Sigma principles,
• 02:00 let's start with a quick review of the background of Six Sigma.
• 02:04 It was developed at Motorola for
• 02:06 the purpose of improving the quality of manufacturing products.
• 02:10 So it wasn't esoteric and philosophical, it was very practical and
• 02:15 implemented in manufacturing shops.
• 02:18 The methodology relies on the elimination of variation in the process,
• 02:22 inputs and outputs.
• 02:23 When variation occurs, the process must add steps to measure whether
• 02:28 the variation is beyond the allowable performance limits.
• 02:31 This adds inspection costs, and when that variation is too large, the business must
• 02:37 scrap or rework the product which adds additional costs and delays in production.
• 02:43 Variation is the enemy of smooth, low-cost manufacturing processes.
• 02:49 Six Sigma uses several measurements to monitor variation.
• 02:54 One that has become very well known is defects per million opportunities,
• 02:59 sending the message that any defect is a problem.
• 03:02 This measure and the process standard deviation can be translated into
• 03:07 a process sigma, which is a way of measuring the level of
• 03:10 uncertainty in any process input or output.
• 03:13 The Six Sigma methodology has a structured process for how the analysis is conducted.
• 03:19 The five phases define, measure, analyze, improve, and control,
• 03:24 guide the team through the problem-solving and problem-solution process.
• 03:29 In fact, these five steps are so
• 03:31 important to the methodology that I want to spend a little time on them.
• 03:35 The DMAIC process, which again stands for define, measure, analyze,
• 03:40 improve and control, provides a logical process for Six Sigma teams to follow.
• 03:46 The first two phases create the problem definition.
• 03:49 The define phase identifies the problem from the business standpoint and
• 03:54 sets the boundaries for the project.
• 03:56 The measure phase digs into the process and
• 03:59 the data to find the real problem and specify the magnitude of that problem.
• 04:04 Six Sigma has a reputation for going overboard on statistical analysis.
• 04:09 If that happens, it's during the analyze phase.
• 04:12 A key principle of this phase is that the analysis of the problem must be based on
• 04:17 statistically demonstrated facts.
• 04:19 It isn't enough that you think you know the reason for the problem, you must be
• 04:23 able to demonstrate with statistical data that you have the root cause or causes.
• 04:28 There is a structured approach for how you work through this phase.
• 04:31 The final two phases, improve and control, are now focused on the problem solution.
• 04:37 The first of these phases, improve, is the design and validation of the solution,
• 04:42 and the final phase, control, is the implementation of that solution.
• 04:47 Things don't get better just because someone did a study or issued a memo.
• 04:52 The process and procedures must be changed, people trained, and
• 04:56 an ongoing control plan put in place to make sure the improvements sticks.
• 05:00 Let me finish this session with a discussion about sigma.
• 05:05 Sigma takes its name from the Greek letter that is used to represent the standard
• 05:10 deviation, a statistical measure of the spread within a set of data.
• 05:15 The term process sigma refers to the ability of the process to consistently
• 05:20 provide results that are within the allowable limits of the process.
• 05:25 As I already mentioned, every process parameter has some inherent variability.
• 05:30 When that variability is due to a random cause, the bell-shaped curve is
• 05:35 a good representation of the level of variability.
• 05:39 That means that it is mostly in the center of the curve, but
• 05:42 occasionally things are higher or lower than normal.
• 05:46 In this picture you see two lines,
• 05:47 consider them to be the allowable process performance specification limits.
• 05:52 The first bell-shaped curve represents a two sigma process, and
• 05:56 you can see that the curve stretches beyond those specification lines.
• 06:00 That means that there will be some instances of the process output
• 06:05 being outside of specification.
• 06:08 As you progress up the series of bell-shaped curves,
• 06:11 we finally get to Six Sigma.
• 06:12 In this case, the curve easily fits in between the customer specification limits.
• 06:18 When a process is operating at the Six Sigma level,
• 06:22 the process should virtually never create an output that is out of specification.
• 06:28 The Process Sigma, then, is a way for process managers and business managers
• 06:32 to manage the quality of business processes and predict performance.
• 06:37 Again, the key is to eliminate variability and to get the width of that bell-shaped
• 06:42 curve of data to be much smaller than the allowable specification limits.
• 06:46 So now we've set the stage for taking the best of both Lean and Six Sigma and
• 06:51 combining them to make a truly outstanding process improvement methodology.

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