Projects that have been completed....

SPONSORED PROJECT LIST

Effective October, 1998

Proposal No. Name Title

Oct. 98-01              Susan L. Albin                        Control of the Startup Period in Batch Processing

Oct. 98-02              Ronald G. Askin                      Reliability Modeling for Aging Under Multimodel Stress Levels

Oct. 98-03              David W. Coit                         Repairable Systems Reliability: Planning and Assessment Tools

Oct. 98-04              E.A. Elsayed                            A General Reliability Model for  Jian Zhao Accelerated Life Testing:
                                                                                  Statistics-Physics Relationship And Experimentation

Oct 98-05              J. Bert Keats                            Process Monitoring and Control: Douglas C. Montgomery  Low PPM Rates

Oct. 98-06              Douglas C. Montgomery       Statistical Methodology for  J. Bert Keats  Characterization, Control and
                                                                                   Optimization of Industrial Processes

Oct. 98-07              Douglas C. Montgomery       Determining Quality Protection  J. Bert Keats When a Sequence of Samples or
                                                                                   Units are Inspected

Oct. 98-08              George Runger                         IC Manufacturing Process Douglas C. Montgomery  Control

Oct. 98-09              Hoang Pham                             A General Reliability Model for Combined Hardware and Software Systems

DESCRIPTION OF PROJECTS

PROJECT NO.: Oct. 98-01

PROJECT NAME: Control of the Startup Period in Batch Processing
PROJECT MANAGER: Susan L. Albin

DESCRIPTION: The startup periods of batch processes often consist of numerous cycles of setting process variables, sampling product, off-line testing, and process adjustment involving dozens of correlated process and product variables. Our previous work identified a startup-monitoring methodology, based on projection to latent structures, to determine whether a configuration of process variables observed during startup is equivalent to regular production and, if not, which variables need adjustment. Here we develop a startup-control algorithm that recommends the specific new levels for process settings. The significant success of the monitoring methodology when applied to company data strongly suggests the potential value of the proposed combined monitoring and control algorithm.

PROJECT NO.: Oct. 98-02

PROJECT NAME: Reliability Modeling for Aging Under Multimodel Stress Levels
PROJECT MANAGER: Ronald G. Askin

DESCRIPTION: Products are normally designed for use at specific stress levels. However, many products endure multiple levels of stress during intermittent periods of use, transportation, and storage. Failure mechanisms may differ for a new product as compared to a product that has aged. Corrosion or seal permeability problems may affect electromechanical components over time, for instance. The same is true if the usage environment changes due to force, vibration, temperature, etc. This project develops and tests a set of models to predict the effects of materials aging on component and systems reliability when products are subjected to varying stresses over time. We begin with the case of discrete usage modes and later consider the case of random dynamic stress.

PROJECT NO.: Oct. 98-03

PROJECT NAME: Repairable Systems Reliability: Planning and Assessment Tools
PROJECT MANAGER: David W. Coit

DESCRIPTION: This project involves the development and automation of planning and assessment tools for repairable system reliability with non-constant rate of occurrence of failure. The distribution of failure times is often non-stationary for many products during (1) development testing where there is reliability growth, and (2) extended field usage where there is deterioration. The problem is further compounded because a system is designed with many subsystems and components, each with potentially different failure patterns. This project involves the study and characterization of different reliability figures of merit and planning methods. The project also explicitly considers reliability estimation uncertainty.

PROJECT NO.: Oct. 98-04

PROJECT NAME: A General Reliability Model for Accelerated Life Testing:
Statistics-Physics Relationship and Experimentation

PROJECT MANAGER: E.A. Elsayed and Jian Zhao

DESCRIPTION: The first phase of this project dealt with the development of a general reliability model for accelerated life testing.
The developed model was shown to encompass accelerated failure times (AFT) and proportional hazards (PH) models. The preliminary results also show that the predicted reliability is more accurate than reliability predicted using other models. There are two drawbacks of the model: (1) the parameters of the model are obtained using statistical methods and there are no clear relationships with the characteristics of the device (component), and (2) the reliability prediction at normal operating conditions assumes constant values for such conditions. We investigate the relationship between the statistical parameters of the model and the physical characteristics of devices with common features through ALT and analysis. We also generalize the model by incorporating the normal operating conditions as random variables.

PROJECT NO.: Oct. 98-05

PROJECT NAME: Process Monitoring and Control: Low PPM Rates
PROJECT MANAGER: J. Bert Keats and Douglas C. Montgomery

DESCRIPTION: Many companies have set Parts per Million (PPM) or Parts per Million Opportunities (PPMO) goals in their quest for continuous improvement. Yet, they have no means for assessing low defect levels and determining when improvements have been made. At low PPM levels, sampling is of no benefit, since the sample size necessary to observe a single defect would be prohibitively large. 100 percent inspection is usually not possible and error rates can exceed the PPM level. Thus, there is need for a scheme which can perform the monitoring process without sampling or 100 percent inspection. The use of the Time-Between-Events (TBE) CUSUM is proposed for this project. It has been demonstrated to work well using theory and computer simulations. This proposal suggests examining implementation using a member company.

PROJECT NO.: Oct. 98-06

PROJECT NAME: Statistical Methodology for Characterization, Control and Optimization of Industrial Processes
PROJECT MANAGER: Douglas C. Montgomery and J. Bert Keats

DESCRIPTION: A logical framework for the development and improvement of industrial processes is the three-phase approach identified as characterization, control, and optimization. Characterization is the process of discovering the specific variables responsible for the variability in the system. Control refers to process stability, and optimization refers to manipulating the most important process variables to obtain the best set of operating conditions for the system. There are three specific research tasks addressed in this project. Two are direct outgrowths of projects performed last year. All research tasks support characterization, control, and optimization of processes.

PROJECT NO.: Oct. 98-07

PROJECT NAME: Determining Quality Protection When a Sequence of Samples or Units are Inspected
PROJECT MANAGER: Douglas C. Montgomery and J. Bert Keats

DESCRIPTION: Many manufacturers produce items that go through a series of processing steps. Following each step, the items are tested or inspected for certain quality characteristics. This testing may be done by automatically testing or measuring one or more characteristic on every unit produced. Alternatively, at each stage only a fraction of the units produced may be tested, where the units tested are selected according to some sampling procedure. This project investigates the performance of multiple sequential inspection and testing systems. Specifically, it is of interest to study the operating characteristics of these systems so that their performance in terms of accepting defective units and rejecting good units may be determined.

PROJECT NO.: Oct. 98-08

PROJECT NAME: IC Manufacturing Process Control
PROJECT MANAGER: George Runger and Douglas C. Montgomery

DESCRIPTION: IC runs generate data with at least two important characteristics: (1) there are numerous independent, or recipe, variables measured that can be used for predictions, and (2) measurements are taken at a number of sites on each wafer and from a number of wafers at different locations in a furnace. An effective algorithm for process control for this type of data is proposed. The strategy includes some linkage between tools and process steps in a hierarchical control strategy. Simple run means and standard deviations do not capture all of the available information in the data, nor do they adjust for the recipe variables.

PROJECT NO.: Oct. 98-09

PROJECT NAME: A General Reliability Model for Combined Hardware and Softwar E Systems
PROJECT MANAGER: Hoang Pham

DESCRIPTION: Many software reliability models have been proposed to determine whether the target software is ready to be released. However, their usefulness in practice is limited by uncertainties in the underlying models. A drawback of current efforts, such as software reliability modeling, is that they treat software as an independent entity (e.g., ignore hardware platforms) and focus on the number of residual faults in software. While this may be the case for some software, it is clearly not the case for software in embedded applications such as VLSI, transmission controller, electronic control module, which is significantly affected by the environment (e.g., hardware) in which it runs. Given that software runs on a hardware platform and is a component of the overall system, interactions between hardware and software must be taken into account, and the reliability of software must be judged by its contribution to overall system reliability.

Top