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Not to be confused with Sigma 6.
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This article needs additional citations for verification. Please help improve this article by adding reliable references. Unsourced material may be challenged and removed. (December 2007) |
The often-used six sigma symbol.
Six Sigma is a set of practices originally developed by Motorola to systematically improve processes by eliminating defects.Motorola University - What is Six Sigma?. Retrieved on 29 January, 2006. A defect is defined as nonconformity of a product or service to its specifications.
While the particulars of the methodology were originally formulated by Bill Smith at Motorola in 1986,The Inventors of Six Sigma. Retrieved on 29 January, 2006. Six Sigma was heavily inspired by six preceding decades of quality improvement methodologies such as quality control, TQM, and Zero Defects. Like its predecessors, Six Sigma asserts the following:
The term "Six Sigma" refers to the ability of highly capable processes to produce output within specification. In particular, processes that operate with six sigma quality produce at defect levels below 3.4 defects per (one) million opportunities (DPMO).Motorola University Six Sigma Dictionary. Retrieved on 29 January, 2006. Six Sigma\'s implicit goal is to improve all processes to that level of quality or better.
Six Sigma is a registered service mark and trademark of Motorola, Inc.Motorola Inc. - Motorola University. Retrieved on 29 January, 2006. Motorola has reported over US$17 billion in savingsAbout Motorola University. Retrieved on 29 January, 2006. from Six Sigma as of 2006.
In addition to Motorola, companies that adopted Six Sigma methodologies early on and continue to practice them today include Honeywell International (previously known as Allied Signal) and General Electric (introduced by Jack Welch).
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Six Sigma has two key methodologies:Joseph A. De Feo & William W Barnard. JURAN Institute\'s Six Sigma Breakthrough and Beyond - Quality Performance Breakthrough Methods, Tata McGraw-Hill Publishing Company Limited, 2005. ISBN 0-07-059881-9 DMAIC and DMADV, both inspired by W. Edwards Deming\'s Plan-Do-Check-Act Cycle: DMAIC is used to improve an existing business process, and DMADV is used to create new product or process designs for predictable, defect-free performance.
Basic methodology consists of the following five steps:
Basic methodology consists of the following five steps:
Some people have used DMAICR (Realize). Others contend that focusing on the financial gains realized through Six Sigma is counter-productive and that said financial gains are simply byproducts of a good process improvement.
Six Sigma as applied to product and process design has spawned an alphabet soup of alternatives to DMADV. Notable examples include:
| Methodology | Proponent |
|---|---|
| CDOC (Conceptualize, Design, Optimize, Control) | SBTI |
| DCCDI (Define, Customer Concept, Design and Implement) | Geoff Tennant |
| DCDOV* (Define, Concept, Design, Optimize, Verify) *derived from SBTI CDOC roadmap*Stated in Acknowledgments - C.M. Creveling, J.L. Slutsky, and D. Antis, Jr. Design for Six Sigma: In Technology and Product Development, Prentice Hall, 2003. ISBN 0-13-0092231 | Uniworld |
| D-IDOV-M (Define, Identify, Design, Optimize, Verify, Monitor) | |
| DMADOV (Define, Measure, Analyze, Design, Optimize and Verify) | General Electric |
| DMAI2C (Define, Measure, Analyze, Improve, Implement,Control) | Cintas Corp., National Australia Group Europe |
| DMEDI (Define, Measure, Explore, Develop and Implement) | PricewaterhouseCoopers |
| IDOV (Identify, Design, Optimize and Validate) | |
| I2DOV (Invent, Innovate, Develop, Optimize, Validate) | |
| MEDIC (Map & Measure, Explore & Evaluate, Define & Describe, Implement & Improve, Control & Conform) | Philips |
| VCPCIA (Visualize, Commit, Prioritize, Characterize, Improve, Achieve) | Raytheon |
The core of the Six Sigma methodology is a data-driven, systematic approach to problem solving, with a focus on customer impact. Statistical tools and analysis are often useful in the process. However, it is a mistake to view the core of the Six Sigma methodology as statistics; an acceptable Six Sigma project can be started with only rudimentary statistical tools.
Still, some professional statisticians criticize Six Sigma because practitioners have highly varied levels of understanding of the statistics involved.
Six Sigma as a problem-solving approach has traditionally been used in fields such as business, engineering, and production processes.
One of the key innovations of Six Sigma is the professionalizing of quality management functions. Prior to Six Sigma, Quality Management in practice was largely relegated to the production floor and to statisticians in a separate quality department. Six Sigma borrows martial arts ranking terminology to define a hierarchy (and career path) that cuts across all business functions and a promotion path straight into the executive suite.
Six Sigma identifies several key roles for its successful implementation.Mikel Harry & Richard Schroeder. Six Sigma, Random House, Inc, 2000. ISBN 0-385-49437-8
In many recent programs, Green Belts and Black Belts are empowered to initiate, expand, and lead projects in their area of responsibility. The roles as defined above, therefore, conform to the older Mikel Harry/Richard Schroeder model, which is not universally accepted.
Bill Smith did not really "invent" Six Sigma in the 1980s; rather, he applied methodologies that had been available since the 1920s developed by luminaries like Shewhart, Deming, Juran, Ishikawa, Ohno, Shingo, Taguchi and Shainin. All tools used in Six Sigma programs are actually a subset of the Quality Engineering discipline and can be considered a part of the ASQ Certified Quality Engineer body of knowledge. The goal of Six Sigma, then, is to use the old tools in concert, for a greater effect than a sum-of-parts approach.
The use of "Black Belts" as itinerant change agents is controversial as it has created a cottage industry of training and certification. This relieves management of accountability for change; pre-Six Sigma implementations, exemplified by the Toyota Production System and Japan\'s industrial ascension, simply used the technical talent at hand – Design, Manufacturing and Quality Engineers, Toolmakers, Maintenance and Production workers – to optimize the processes.
The expansion of the various "Belts" to include "Green Belt", "Master Black Belt" and "Gold Belt" is commonly seen as a parallel to the various "Belt Factories" that exist in martial arts.
Sigma (the lower-case Greek letter σ) is used to represent standard deviation (a measure of variation) of a population (lower-case \'s\' is an estimate, based on a sample). The term "six sigma process" comes from the notion that if one has six standard deviations between the mean of a process and the nearest specification limit, there will be practically no items that fail to meet the specifications. This is based on the calculation method employed in a Process Capability Study, often used by quality professionals. The term "Six Sigma" has its roots in this tool.
In a Capability Study, the number of standard deviations between the process mean and the nearest specification limit is given in sigma units. As process standard deviation goes up, or the mean of the process moves away from the center of the tolerance, the Process Capability sigma number goes down, because fewer standard deviations will then fit between the mean and the nearest specification limit (see Cpk Index).
Experience has shown that in the long term, processes usually do not perform as well as they do in the short. As a result, the number of sigmas that will fit between the process mean and the nearest specification limit is likely to drop over time, compared to an initial short-term study. To account for this real-life increase in process variation over time, an empirically-based 1.5 sigma shift is introduced into the calculation.Harry, Mikel (1988). The Nature of six sigma quality. Rolling Meadows, IL: Motorola University Press, p. 25. ISBN 9781569460092. According to this idea, a process that fits six sigmas between the process mean and the nearest specification limit in a short-term study will in the long term only fit 4.5 sigmas – either because the process mean is likely to move over time, or because the long-term standard deviation of the process is likely to be greater than that observed in the short term, or both.Tennant, Geoff (2001). SIX SIGMA: SPC and TQM in Manufacturing and Services. Gower Publishing, Ltd., p. 25. ISBN 0566083744.
Hence the widely accepted definition of a six sigma process is one that produces 3.4 defective parts per million opportunities (DPMO).Tonner, Craig; Patra, Pradeep (2003-09-03). Six Sigma (English). Retrieved on 2006-11-26. This is based on the fact that a process that is normally distributed will have 3.4 parts per million beyond a point that is 4.5 standard deviations above or below the mean (one-sided Capability Study). So the 3.4 DPMO of a "Six Sigma" process in fact corresponds to 4.5 sigmas, namely 6 sigmas minus the 1.5 sigma shift introduced to account for long-term variation. This is designed to prevent overestimation of real-life process capability.
Noted Quality expert Joseph Juran has criticized Six Sigma as "a basic version of quality improvement", stating that "[t]here is nothing new there."Scott Paton (2002-08). Juran: A Lifetime of Quality. Quality Digest. Retrieved on 2007-07-01.
A Fortune article stated that "of 58 large companies that have announced Six Sigma programs, 91 percent have trailed the S&P 500 since." The statement is attributed to "an analysis by Charles Holland of consulting firm Qualpro (which espouses a competing quality-improvement process)."Betsy Morris (2006-07-11). Old rule: be lean and mean. Fortune. Retrieved on 2006-11-26. The gist of the article is that Six Sigma is effective at what it is intended to do, but that it is "narrowly designed to fix an existing process" and does not help in "coming up with new products or disruptive technologies." Many of these claims have been argued as being in error or ill-informed. KAREN RICHARDSON (2007-01-07). The \'Six Sigma\' Factor for Home Depot. Wall Street Journal Online. Retrieved on 2007-10-15. Joe Ficalora & Joe Costello. Wall Street Journal SBTI Rebuttal. Sigma Breakthrough Technologies, Inc.. Retrieved on 2007-10-15.
A Business Week article says that James McNerney\'s introduction of Six Sigma at 3M may have had the effect of stifling creativity. It cites two Wharton School professors who say that Six Sigma leads to incremental innovation at the expense of blue-sky work. Hindo, Brian (6). At 3M, a struggle between efficiency and creativity. Business Week. Retrieved on 2007-06-06.
While 3.4 defects per million might work well for certain products/processes, it might not be ideal for others. A pacemaker might need higher standards, for example, whereas a direct mail advertising campaign might need lower ones. The basis and justification for choosing 6 as the number of standard deviations is not clearly explained.[citation needed]
Because of its arbitrary nature, the 1.5 sigma shift has been dismissed by Dr. Donald Wheeler as "goofy".Wheeler, Donald J., Phd, The Six Sigma Practitioner\'s Guide to Data Analysis, p. 307, http://www.spcpress.com
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