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EMIS 8340. Systems Engineering Tool—applying tools to engineering systems . Optimization: Design for ‘ilities. Mark E. Sampson. Design for… EMI/EMC Environment Disposal Human Factors, Usability, Training Safety Manufacturing/Produceability Reliability, Maintainability, Availability
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EMIS 8340 Systems Engineering Tool—applying tools to engineering systems Optimization: Design for ‘ilities Mark E. Sampson
Design for… • EMI/EMC • Environment • Disposal • Human Factors, Usability, Training • Safety • Manufacturing/Produceability • Reliability, Maintainability, Availability • Logistics/Supportability • Security • Testability • Liability • Politics • Irony • … $150/vehicleliability for disposal EU Auto Mfg’s are required to balance vehicle content by country. [SE Handbook 11] [Lacy 1992]
Design for EMI/EMC • Electro-Magnetic Interference (EMI)…unwanted interaction between electronic systems • Electro-Magnetic Compatibility (EMC)…ability for electronic systems to operate near each other without unwanted interactions • Nearly everything has electronics in it and you need to design for it. • …some examples from health care… • Baylor Medical Center Dallas is transmitting medical telemetry in the band 186-192 MHz with 0.01 watts power. • WFAA TV Dallas begins transmitting DTVsignals at the same frequencies with 316,000 watts power. • Baylor spends $200k for new medical equipment to remediate the problem. • In 2002, a patient was over-infused with epinephrine when a nearby cell phone was activated. [SE Handbook 11 ] [Lacy 1992] www.mohca.org
Design for Humans…Human Factors • Design for human interactions/limitations… • Reaction time: hear & respond: 150ms, see & respond: 200ms,… • Stimulus thresholds: Pressure on fingertips .05-.1.1erg (1 erg=1mg dropped 1cm) • Temperature: Skin temp:91.4’, 60’-105’ ok, < feels cold, > feels hot • Anthropometric measure…no such thing as an average person. Design for the 95th percentile person • Perceptions: “giving meaning to stimuli” “…can be thought as merging immediate & remote past applied to the present to make sense of it. An experienced perceiver can make sense of it, if it matches up” • Perceptions are real, and real in their consequences… • Three-Mile Island… Jack and Jill went went up the hill to fetch a a pail of milk FINISHED FILES ARE THE RE-SULT OF YEARS OF SCIENTIF-IC STUDY COMBINED WITH THE EXPERIENCE OF MANY YEARS “dealing with an unprecedented problem, nothing in their experience enabled them to make sense of what was happening…the result was a series of missteps, misdiagnosis, changing a minor incident into one costing ~$2 billion dollars.” Cows drink… [Bailey 1982]
Design for Reliability/safety... • Designing products for Murphy—”anything that can go wrong will go wrong” • You can’t manufacture in reliability…you design it in. Reliability needs to be considered from the start. • “A large safety factor does not necessarily translate into a reliable product. Instead it often leads to an overdesigned product with reliability problems” • --Failure Analysis Beats Murphy’s Law • Mechanical Engineering, Sept. 1993 • To design for reliability, you need to understand possible failure modes. Several important tools can help: • Fault Trees • FMEA’s (Failure Modes Effects Analysis) • Root Cause Analysis • Fish Bones • Sneak Circuit Analysis [SE Handbook 11 ] [Lacy 1992] www.fmeainfocentre.com
Design for Reliability...continued • FMEA’s… a “simple” 10 step process • Capture product functions • Capture product block diagram to identify potential physical interfaces • Identify potential failure modes (corrosion, electrical short, torque fatigue,…) • What is the effect of the failure (injury, stop-operating, degraded performance, noise, odor,…) • Rank the severity (1-no impact up to 10-serious,injury) • How likely is the failure to occur (1-not likely up to 10-inevitable) • Identify controls that prevent or detectors that warn • Determine the probability of detection • Compute the RPN for each RPN = (Severity) x (Probability) x (Detection) • Action high RNP failure modes • …lots of tools out there to use for this…many of them free, excel-addins, access DB’s, etc. Warning: Peel fruit from cellophane before eating www.fmeainfocentre.com
Design for Reliability...continued • Fault Trees • Fishbone diagrams • Root cause analysis • Petri Nets • Identify all possible contributors to the fault. • Identify all possible impacting issues to those contributors • …keep going • Many tools that can help… • Relex • Aralia • Blocksim • … Clapham railway accident 1988
Design for Maintainability... • What is the maintenance concept for the product? • Compatible with your maintenance organization • Robust to technology changes…Example: TV maintenance over last 20 yrs…In house troubleshooting/replace tubes or take to shop, replace circuit boards, …buy a new TV. • Based on concept of operations… • Delivered in levels • Cars: 1 level-dealers • Copy machines: customer location • Military: 3-4 levels: • Field • Intermediate • Depot • Contractor • …which will dictate your logistics supportrequirements. Sony Trinitron can handle 32g shock loading [Lacy 1992]
Design for Manufacturing…What is Six Sigma? • Six Sigma is essentially a reactive quality improvement strategy that uses statistical methods to remove defects and optimize processes • Statistical sampling of resultproduces a Normal distribution • Goal is to reduce number of samples outside the limit/goal. • Six-Sigma goal is 6 standarddeviations from the mean
Isn’t Three Sigma Level (99.7% Yield) Good Enough for Quality? • Virtually no modern computer would function. • 10,800,000 healthcare claims would be mishandled each year. • 18,900 US Saving bonds would be lost every month. • 54,000 checks would be lost each night by a single bank. • 4,050 invoices would be sent out incorrectly each month by a modest-sized telecommunications company. • 540,000 erroneous call details would be recorded each day from a regional telecommunications company. • 270 million erroneous credit card transactions would be recorded each year in the United States.
Cost of Quality [GE 1998 Annual Report]
6 DFSS 5 Diminishing Returns with Process Improvement Sigma Level 4 Improve Quality via Process Improvement 3 Time The 4-Sigma Wall… • There are only so many defects you can squeeze out of development process before reaching the point of diminishing returns where the fix is more expensive the problem • …what’s called the 4-sigma wall and what DFSS is about • DFSS is a proactive,defect avoidanceapproach to design
1000 DFSS Relative Cost to Make a Change 100 Six Sigma 10 Concept 1 Design Development Production DFSS Window of Opportunity Everyone knows you can’t test in quality—you need to address it from the beginning. DFSS is after addressing product quality goals from the start. “Design in” quality early when costs are low
Murphy’s Law 39: “Toast always falls butter-side down” • Oxford University, Murphy Center of Excellence, Toast Study enlisted 10,000 students to perform sampling • …of 1,000,000 pieces of toast, 623,000 land on the floor butter side down <1 sigma-level process 62.3% of Toast Falls butter-side down
A Six-Sigma approach for dealing with toast… • Using a Define, Measure, Analyze, Improve, Control approach… • We would focus on the results--How to improve the probability of toast landing butter side up: • Raise table height (3 m) • Embedded Gyroscopes • Smaller pieces of toast • Strapping toast to the back of a cat • Spring loaded plates
A DFSS approach for dealing with toast… • Using a Identify opportunity, Define requirements, Develop concept, Optimize design, Verify it, • We would focus on the product-How to avoid toast sliding off the plate/table • Outlaw toast • Fences on plates • Toasters on/in the table • Sticky toast (Velcro?)
Design for Manufacturing...cont. • Lean manufacturing…all about removing waste… • Overproduction: to produce more than demanded or produce it before it is needed. It is visible as storage of material. • Inventory or Work In Process (WIP): is material between operations due to large lot production or processes with long cycle times; • Transportation • Processing waste: asking why a specific processing step is needed and why a specific product is produced. All unnecessary processing steps should be eliminated; • Motion: of the workers, machines, and transport • Waiting: for a machine to process should be eliminated. • Making defective products: is pure waste. “No greater waste than doing something efficiently that shouldn’t be done at all.” [isixsigma institute, advancedmanufacturing.com]