Systems Reliability Growth Modeling and Analysis

1. Systems Reliability, Supportability and Availability Analysis Systems Reliability Growth Modeling and Analysis

2. Reliability Development Test Definitions MIL-STD-785 Definition A series of tests conducted to disclose deficiencies and to verify that corrective actions will prevent recurrence in the perational inventory (also known as TAAF testing) Definition - Narrow View A reliability development test (RDT) is a dedicated and specifically designed and conducted test under usage and maintenance environments that the equipment is expected to experience during its service life

3. Reliability Development Test Definitions - continued Definition - General View A reliability development test is any test where results are designed to improve equipment reliability

4. Reliability Growth Test Objective and Purpose Objective - identify reliability problems early in the development phase and incorporate corrective action to preclude recurrence during service usage Purpose - improve the reliability of production equipment by identifying and correcting deficiencies in the design, selection of parts, and manufacturing processes

5. Test, Analyze and Fix (TAAF) A technique for reliability development and growth that requires that a series of tests be conducted, problems identified and analyzed, and corrective actions be taken. TAAF and other reliability growth techniques require a closed loop feedback and corrective action system and follow a common problem solving process: 1. Detect failures 2. Feed back problems to designer 3. Analyze and redesign to correct problem 4. Incorporate redesign into system 5. Verify fix by operating system

6. The TAAF Process Test analyze and fix (TAAF) is a philosophy that can be applied to any test - Data for all failures/problems should be used for TAAF - This approach decreases the likelihood of major problems in service Data from each failure/problem from every test conducted on an item should be analyzed for corrective action, positive fix and verification of the fix

7. TAAF Benefits TAAF provides the means to accelerate design and reliability maturity through the corrective actions taken for design performance/reliability problems identified. TAAF provides advanced information related to how the design will work in the field during the early years of deployment.

8. Selection Criteria for RDT Major contributor to system (end-item) failure rate New development or application High unit cost Experience indicates need for improvement

9. Reliability Test Length Fixed length - 400 to 10,000 hours (chamber hours) various tests over past 10 years mostly avionics and electronics - Easy to price - Avoids numbers game of when to stop testing Truncated - Stop testing when corrective action rate reaches a specified level - Difficult to price - Analysis of data becomes more important

10. Reliability Growth Management Planning the reliability growth necessary to meet program objectives as a function of program schedule Planning of tasks and program resources necessary to achieve the planned growth - Reliability test data - Failure analysis - Corrective action Assessment and forecast of reliability growth relative to plan - Provides early warning of program reliability problem

11. Reliability Growth Reliability growth is the positive improvement of system reliability through the systematic and permanent removal of the reasons for failure Reliability improvements can be achieved through testing to identify deficiencies and/or weaknesses, followed by positive actions to correct them. Test, analyze, and fix (TAAF) is one process for achieving reliability growth.

12. Reliability Growth - continued Growth curves are management tools; they show the manager where the system reliability is now and where is must go Air Force Regulation 800-18, Air Force reliability and maintainability program, requires the use of reliability growth curves to track improvements to achieve reliability requirements

13. Reliability Growth Curves Decision makers can use reliability growth curves to assess the need to reallocate resources or change schedules to achieve R&M requirements

14. DOD Policy on Reliability Growth and Testing DOD 5000.40 requires that a period of testing be scheduled with each intermediate milestone for purposes of finding design and manufacturing defects AFR 800-18 is intended to implement the requirements of DOD 5000.40 and implies reliability growth by such statements as ‘terms are expressed in mature system values along with interim thresholds’

15. DOD Policy on Reliability Growth and Testing MIL-STD-785 states that a properly balanced reliability program will emphasize ESS and RD/GT. It also notes that RD/GT must not include accept/reject criteria because the contractors interest in passing a test would be in conflict with the purpose of doing a RD/GT MIL-HDBK-781

16. Reliability Growth Models

17. Reliability Growth Model Types Engineering Statistical models models Deterministic Models Poisson Process Time Series models Endless-Burn-In AMSAA/Duane ARIMA Cox-Lewis Modified Duane

18. The Duane Model In 1964 J.T Duane, with General Electric Company, published a paper in the IEEE Transactions on Aerospace (Vol. 2, No. 2, April 1964) titled “Learning Curve Approach to Reliability Monitoring.” Duane formulated a mathematical relationship for forecasting and monitoring reliability improvement as a function of cumulative time. The model was based on concluding, from analysis of data, that a straight line provided a reasonably good fit to cumulative MTBF vs. cumulative time when plotted on a log-log scale.

19. Reliability Growth Analysis To meet reliability goals, a technique must be used to track reliability and signal when corrective action should be taken J.T. Duane (1964) noticed that in many cases this relationship followed a straight line on a log-log plot

20. Jet Engine Control System Reliability - Growth

21. The Duane Model The Duane Model can be formulated in two different, but mathematically equivalent, ways: MTBF as a Function of time and failure rate as a function of time. In terms of MTBF, the Duane Model is: where MTBFc(t) is the cumulative MTBF at cumulative time t, t is cumulative time, and  and  are parameters of the model.

22. The Duane Model The parameter  is the reliability improvement, or growth, rate and  is cumulative MTBF at t=1 hour. Notice that the graph of the Duane Model on log-log scale is a straight line since log MTBF(t) = log k +  log t which is of the form y = a + bx

23. The Duane Model Since where rc=the cumulative number of failures in time t,

24. The Duane Model Then But Since

25. The Duane Model The instantaneous MTBF as a function of cumulative test time is obtained mathematically from MTBFC(t) and is given by where MTBFi(t) is the instantaneous MTBF at time t and is interpreted as the equipment MTBF if reliability development testing was terminated after a cumulative amount of testing time, t.

26. 1000 Instantaneous MTBF 100 Cumulative 10 1000 10 100 10000 Cumulative Test Hours MTBF Growth Curves

27. The Duane Model The Duane Model may also be formulated in terms of equipment failure rate as a function of cumulative test time as follows: and where C(t) is the cumulative failure rate after test time t k* is the initial failure rate and k*=1/k, α is the failure rate growth (decrease rate) i(t) is the instantaneous failure rate at time t

28. The Duane Model Initial MTBF, k at t=1, at the beginning of RDT depends on a number of factors: • Type of equipment (electronics, structure, etc.) • Complexity of the design and equipment operation • Technology maturity Growth rate, α, depends on: • Management FRACAS and TAAF implementation. • TAAF cycle time • Complexity of equipment • Technology maturity

29. Failure Rate and MTBF

30. AMSAA/Duane Model - plotted with group data

31. AMSAA/Duane Model - plotting the data and solving for  and 

32. AMSAA/Duane Model - plotting by MTBF