Integrated DEsign Automation Laboratory

Under the Decision-based Design (DBD) framework, engineering design is modeled as a decision-making process that seeks to maximize the value of a designed artifact under uncertainty and risk. At the core of this research area is the establishment of rigorous decision-making principles, and the study of the interrelationships between enterprise product planning and engineering product development. Currently, our research focuses on developing analytical approaches that bridge the gap between quantitative engineering design decisions and qualitative customer preferences through demand modeling.

• Network-based Customer Preference Modeling
• Multilevel Decision-based Design (DBD)

Our current work in demand modeling is focused on modeling the heterogeneity of customer preferences and the impact of social networks on customer choices. In the proposed Multidimensional Customer-Product Network (MCPN), customer-product interactions are viewed as a socio-technical system where separate entities of “customers” and “products” are simultaneously modeled, and multiple types of relations, such as consideration and purchase, product associations, and customer social connections are considered. Beyond the traditional descriptive analysis that examines the network structure characteristics, we employ the Exponential Random Graph Model (ERGM) as a unified statistical inference framework to interpret complex preference decisions. Our approach broadens the traditional utility-based logit models by considering the dependency among complex customer-product relations, the “irrationality” of customers induced by social influence, nested multi-choice decisions, and correlated attributes of customers and products. The methods developed will enhance industry’s resilience to changing markets through strategic product design. Our design framework allows designers to focus their engineering efforts on the most critical feature upgrades and quality improvements, considering not only the engineering requirements but also the business interests, customers’ desires, and market behavior.

DBD is a collaborative multidisciplinary design approach that employs a single value function (e.g., profit) from the enterprise’s perspective to maximize the expected utility of a designed artifact while also considering uncertainty and the decision maker’s risk attitude. The core of enterprise-driven design is the use of demand modeling to estimate the effect of design changes on a product’s market share, aggregated from individual customers’ choice probabilities, and consequently on the firm’s revenues. Our research in this area has progressed from the multinomial logit approach for a single product design, to the nested-logit approach for platform-based product family design, to the use of a Bayesian framework for supporting complex hierarchical systems design, and to use of choice modeling in usage and social context-based design. These approaches have been applied in various practical design problems in industry, such as the universal motor design, vehicle engine design, suspension systems design, and vehicle occupant package design. In addition, to manage the complexity of DBD, we developed a multilevel DBD framework where the product planning from the enterprise level identifies the optimal settings of engineering design attributes that serve as the targets to be optimized at the product level. Compared to the all-in-one single-objective DBD approach, the multilevel optimization approach is more representative of the hierarchical decision-making used in a typical industry design process.

• Cui, Y. Ahmed, F., Sha, Z., Wang, L., Fu, Y., Contractor, N., Chen, W., “A Weighted Statistical Network Modeling Approach to Product Competition Analysis”, Complexity vol. 2022, Article ID 9417869, 2022
• Xiao, Y., Cui, Y., Raut, N., Januar, J., Koskinen, J., Contractor, N., Chen, W., Sha, Z., “Information Retrieval and Survey Design for Two-Stage Customer Preference Modeling”, Proceedings of the Design Society 2, 811-820, 2022
• Ahmed, F., Cui, Y., Fu, Y., Chen, W., “Product Competition Prediction in Engineering Design using Graph Neural Networks”, ASME Open Journal of Engineering, accepted April 2022
• Ahmed, F., Cui, Y., Fu, Y., Chen, W. “A Graph Neural Network Approach for Product Relationship Prediction.”, Proceedings of the ASME 2021 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. Volume 3A: 47th Design Automation Conference (DAC). Virtual, Online. V03AT03A036. ASME. August 17–19, 2021.
• Bi., Y., Qiu, Y., Sha, Z., Wang, M., Fu, Y., Contractor, N., and Chen, W., “Modeling Multi-Year Customers’ Considerations and Choices in China’s Auto Market Using Two-State Bipartite Network Analysis”, Networks and Spatial Economics, March 2021, https://doi.org/10.1007/s11067-021-09526-9.
• Cui, Y., Ahmed, F., Sha, Z., Wang, L., Fu, Y., and Chen, W. “A Weighted Network Modeling Approach for Analyzing Product Competition”, Proceedings of the ASME 2020 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. Volume 11A: 46th Design Automation Conference (DAC). Virtual, Online. V11AT11A036. ASME. August 17–19, 2020.
• Sha, Z., Huang, Y., Fu, S., Wang, M., Fu, Y., Contractor, N., and Chen, W., “A Network-Based Approach to Modeling and Predicting Product Co-Consideration Relations”, Special issue on “Emerging Applications of Complex Networks”, Complexity, Article ID 2753638, 2018.
• Wang, M., Sha, Z., Huang, Y., Contractor, N., Fu, Y., and Chen, W., “Predicting Product Co-Consideration and Market Competitions for Technology-Driven Product Design: A Network-Based Approach”, Design Science, doi.org/10.1017/dsj.2018.4, published online April 2018.
• Bi, Y., Xie, J., Sha, Z., Wang, M., Fu, Y., and Chen, W., “Modeling Spatial Temporal Heterogeneity of Customer Preferences in Engineering Design”, ASME 2018 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference, DETC2018 -86245, August 26-29, Quebec City, Quebec, Canada.
• Sha, Z., Saeger, V., Wang, M., Fu, Y., and Chen, W., “Analyzing Customer Preference to Product Optional Features in Supporting Product Configuration”, SAE Technical Paper, 2017-01-17IDM-0051, Detroit, MI, April 4-6, 2017.
• Wang, M., Huang, Y., Contractor, N., Fu, Y., and Chen, W., “Modeling Customer Preferences using Multidimensional Network Analysis in Engineering Design”, Design Science, Vol2, e11, DOI: https://doi.org/10.1017/dsj.2016.11, 2016.
• Sha, Z., Wang, M., Huang, Y., Contractor, N., and Chen, W., “Modeling Product Co-Consideration Relations: A Comparative Study of Two Network Models”, ICED17: 21st International Conference on Engineering Design, August 21-25, Vancouver, Canada, 2017.
• Fu, J. S., Sha, Z., Huang, Y., Wang, M., Fu, Y., and Chen, W, “Modeling Customer Choice Preferences in Engineering Design using Bipartite Network Analysis”, IDETC2017-68099, Proceedings of the ASME 2017 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference, August 6-9, 2017, Cleveland, Ohio.
• Wang, M., Sha, Z., Huang, Y., Contractor, N., Fu, Y., and Chen, W., “Forecasting Technological Impacts on Customers’ Co-Consideration Behaviors: A Data-Driven Network Analysis Approach” , IDETC2016-60015, Proceedings of the ASME 2016 International Design Engineering Technical Conferences & Design Automation Conference, August 21-24, Charlotte, NC.
• Wang, M., Huang, Y., Contractor, N., Fu, Y., and Chen, W., “A Network Approach for Understanding and Analyzing Product Co-Consideration Relations in Engineering Design”, International Design Conference – Design 2016, Dubrovnik, Croatia, May 16-19, 2016.
• Wang, M., Chen, W., Fu, Y., and Yang, y., “Analyzing and Predicting Heterogeneous Customer Preferences in China’s Auto Market Using Choice Modeling and Network Analysis,” SAE Technical Paper 2015-01-0468, 2015
• Wang, M., Chen, W., Huang, Y., Contractor, N., and Fu. Y., “A Multidimensional Network Approach for Modeling Customer-product Relations in Engineering Design”, ASME 2015 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference, IDETC2015-46764, August 2-4, Boston, MA, 2015.
• Wang, M., and Chen, W., “A Data-Driven Network Analysis Approach to Predicting Customer Choice Sets for Choice Modeling in Engineering Design”, Journal of Mechanical Design, Special issue on User Needs and Preferences in Engineering Design, 137(7), 2015.
• Lin, H., Wang, M., G., Chen W., and Conzelmann, G., “Incorporating Social Impact On New Product Adoption In Choice Modeling: A Case Study In Green Vehicles”, Transportation D, 32, 421-434, 2014.
• Yannou, B., Yvars, P-A., Hoyle, C., and Chen, W., “Set-based Design by Simulation of Usage Scenario Coverage”, Journal of Engineering Design, DOI:10.1080/09544828.2013.780201.
• He, Lin, Hoyle, C., Chen, W., and Yannou, B., “Choice Modeling for Usage Context-Based Design”, ASME Journal of Mechanical Design, 134(3), March, 2012.
• He, Lin, Chen, W., and Guenter Conzelmann, “Impact of Vehicle Usage on Choice of Hybrid Electric Vehicles”, Transportation Research D, 17, 208-214, 2012.
• He, L., Chen, W., and Conzelmann, G., “On Usage Context of Hybrid Electric Vehicles in Choice Studies”, Proceedings of the ASME 2011 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference, DETC2011-48385, August 28- August 31, Washington, DC.
• Hoyle, C., Chen, W., Wang, N., and Koppelman, F., “Integrated Bayesian Hierarchical Choice Modeling to Capture Heterogeneous Preferences in Engineering System Design”, ASME Journal of Mechanical Design,  132(12), 121010 (11 pages), DOI: 10.1115/1.4002972, 2010.
• Hoyle, C., Chen, W., Wang, N., and Gomez-levi, G., “Understanding and Modeling Heterogeneity of Human Preferences for Engineering Design”, Journal of Engineering Design, DOI: 10.1080/09544821003604496.  First published online: 22 February 2010 (iFirst). 22(8), 583-601, 2011.
• He, L., Hoyle, C., and Chen, W., “Examination of Customer Satisfaction Surveys in Choice Modeling to Support Engineering Design”, Journal of Engineering Design, DOI: 10.1080/09544828.2010.505186, available online August 2010.
• Hoyle, C., Chen, W., Ankenman, B., Wang, N., “Optimal Experimental Design of Human Appraisals for Modeling Consumer Preferences in Engineering Design”, ASME Journal of Mechanical Design, 131(7), 071008 (9 pages), August 2009.
• Tucker, C.S., Hoyle, C., Kim, H.M., and Chen, W., “Comparative Study of Data-Intensive Demand Modeling Techniques in Relation to Product Design and Development”, Proceedings of the ASME 2009 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference , DETC 2009-87049, August 30-September 2, 2009, San Diego, CA.
• Yannou, B., Wang, J., Rianantsoa, N., Hoyle, C., Drayer, M., Chen, W., Alizon, F., Mathieu, J-P., “Usage Coverage Model for Choice Modeling: Principles and Taxonomy”, Proceedings of the ASME 2009 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference , DETC 2009-87534, August 30-September 2, 2009, San Diego, CA.
• Kumar, D., Hoyle, C., Chen, W., Wang, N., Gomez-Levi, G., and Koppelman, F., “A Hierarchical Choice Modelling Approach for Incorporating Customer Preferences in Vehicle Package Design,” International Journal of Product Development, 8(3), 228-251, 2009.
• Kumar, D, Chen, W ., and Simpson, T., “A Market-Driven Approach to the Design of Platform-based Product Families”, International Journal of Production Research , 47(1), 71-104 , 2009.
• Hoyle, C. and Chen, W. , “Product Attribute Function Deployment (PAFD) for Decision-Based Conceptual Design”,  IEEE Transactions on Engineering Management , 56(2), 271-284, 2009.
• Liu, H., Chen, W ., Scott, M. J., and Qureshi, K., “Determination of Ranged Set of Design Specifications by Incorporating Design Heterogeneity”,  Engineering Optimization , 40(11), 1011-1029, 2008.
• Kim, H., Chen, W., and Wiecek, M., Lagrangian Coordination for Enhancing the Convergence of Analytical Target Cascading, AIAA Journal, 44(10), 2197-2207, Oct 2006.
• Kim, H., Chen, W., and Papalambros, P., Target Exploration in Enterprise-Driven Hierarchical Multidisciplinary Design, AIAA Journal. 44(1), 67-77, 2006.
• Kumar, D., Chen, W., and Kim, H., Multilevel Optimization for Enterprise Driven Decision-Based Product Design , AIAA/ISSMO Multidisciplinary Analysis and Optimization Conference, Portsmouth, VA, September 6-8, 2006.
• Wassenaar, HJ, Chen, W., Cheng, J., and Sudjianto, A., Enhancing Discrete Choice Demand Modeling for Decision-Based Design , ASME Journal of Mechanical Design, 127(4), pp.514-523, 2005.
• Wassenaar, HJ, Chen, W., Cheng, J., and Sudjianto, A., An Integrated Latent Variable Choice Modeling Approach to Enhancing Product Demand Modeling , DETC2004-57487, 2004 ASME Design Theory and Methodology Conference, Salt Lake City, UT, September 28-October 2, 2004.
• Wassenaar, H. J. and Chen, W., An Approach to Decision Based Design with Discrete Choice Analysis for Demand Modeling, Journal of ASME Journal of Mechanical Design. 125 (3), 490-497, September 2003.
• Kim, H., Kumar, D., Chen, W., and Panos, P., 2004, Target Feasibility Achievement in Enterprise-Driven Hierarchical Multidisciplinary Design , AIAA-2004-4546, 10th AIAA/ISSMO Multidisciplinary Analysis and Optimization Conference, Aug. 30 – Sept. 1, 2004, Albany, NY.
• Chen, W., Lewis, K., and Schmidt, L., “Decision-Based Design: An Emerging Design Perspective?/A>, Engineering Valuation & Cost Analysis”, special edition on “Decision-Based Design: Status & Promise” 3(1/2), 57-66, 2000.