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1. Graph Partitioning Technique to Identify Physically Integrated Design Concepts

   https://doi.org/10.1115/DETC2018-85646  

   Gopalakrishnan, Praveen Kumare; Kain, Helen; Jahanbekam, Sogol; Behdad, Sara (August 2018, 23rd Design for Manufacturing and the Life Cycle Conference)

   This study proposes a graph partitioning method to facilitate the idea of physical integration proposed in Axiomatic Design. According to the physical integration concept, the design features should be integrated into a single physical part or a few parts with the aim of reducing the information content, given that the independence of functional requirements is still satisfied. However, no specific method is suggested in the literature for determining the optimal degree of physical integration of a design artifact. This is particularly important with the current advancement in Additive Manufacturing technologies. Since additive manufacturing allows physical elements to be integrated, new methods are needed to help designers evaluate the impact of the physical integration on the design success. The objective of this paper is to develop a framework for determining the best way that functional requirements can be assigned to different parts of a product. 

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2. Graph Partitioning Technique to Identify Physically Integrated Design Concepts

   Gopalakrishnan, Praveen Kumare; Kein, Helen; Jahanbekam, Sogol; Behdad, Sara (August 2018, Proceedings of the ASME 2018 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference IDETC/CIE 2018 August 26-29, 2018, Quebec, Canada)

   This study proposes a graph partitioning method to facilitate the idea of physical integration proposed in Axiomatic Design. According to the physical integration concept, the design features should be integrated into a single physical part or a few parts with the aim of reducing the information content, given that the independence of functional requirements is still satisfied. However, no specific method is suggested in the literature for determining the optimal degree of physical integration of a design artifact. This is particularly important with the current advancement in Additive Manufacturing technologies. Since additive manufacturing allows physical elements to be integrated, new methods are needed to help designers evaluate the impact of the physical integration on the design success. The objective of this paper is to develop a framework for determining the best way that functional requirements can be assigned to different parts of a product. 

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3. Sensor technologies for quality control in engineered tissue manufacturing

   https://doi.org/10.1088/1758-5090/ac94a1  

   McCorry, Mary Clare; Reardon, Kenneth F.; Black, Marcie; Williams, Chrysanthi; Babakhanova, Greta; Halpern, Jeffrey M.; Sarkar, Sumona; Swami, Nathan S.; Mirica, Katherine A.; Boermeester, Sarah; et al (October 2022, Biofabrication)

   Abstract The use of engineered cells, tissues, and organs has the opportunity to change the way injuries and diseases are treated. Commercialization of these groundbreaking technologies has been limited in part by the complex and costly nature of their manufacture. Process-related variability and even small changes in the manufacturing process of a living product will impact its quality. Without real-time integrated detection, the magnitude and mechanism of that impact are largely unknown. Real-time and non-destructive sensor technologies are key for in-process insight and ensuring a consistent product throughout commercial scale-up and/or scale-out. The application of a measurement technology into a manufacturing process requires cell and tissue developers to understand the best way to apply a sensor to their process, and for sensor manufacturers to understand the design requirements and end-user needs. Furthermore, sensors to monitor component cells’ health and phenotype need to be compatible with novel integrated and automated manufacturing equipment. This review summarizes commercially relevant sensor technologies that can detect meaningful quality attributes during the manufacturing of regenerative medicine products, the gaps within each technology, and sensor considerations for manufacturing. 

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4. Recent advances in design optimization and additive manufacturing of composites: from enhanced mechanical properties to innovative functionalities

   https://doi.org/10.1038/s44334-025-00040-1  

   Yu, Kai; Dunn, Martin_L; Jerry_Qi, H.; Maute, Kurt (June 2025, npj Advanced Manufacturing)

   Abstract This review highlights recent progress in additive manufacturing (AM) techniques for polymer composites reinforced with nanoparticles, short fibers, and continuous fibers. It also explores the integration of functional resins and fibers to enable advanced capabilities such as shape morphing, enhanced electrical and thermal conductivity, and self-healing behavior. Building on these advances, the review examines computational design strategies that optimize material distribution and fiber orientation. Representative approaches range from density-based methods to emerging level-set topology optimization frameworks, with objectives evolving from improving mechanical performance to addressing complex multi-physics functional requirements. The review also identifies emerging opportunities, including the need for technological innovations to further improve mechanical properties and enable adaptable multifunctionality. Further advances in theoretical modeling and integrated design-printing workflows are also discussed. By synthesizing these developments, this review aims to foster interdisciplinary collaborations and accelerate innovation in AM-enabled composite materials across a wide range of applications. 

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5. A functional modeling approach for quality assurance in metal additive manufacturing

   https://doi.org/10.1108/RPJ-12-2018-0312  

   Seo, Gijeong; Ahsan, Md. RU; Lee, Yousub; Shin, Jong-Ho; Park, Hyungjun; Kim, Duck Bong (January 2021, Rapid Prototyping Journal)

   null (Ed.)

   Purpose Due to the complexity of and variations in additive manufacturing (AM) processes, there is a level of uncertainty that creates critical issues in quality assurance (QA), which must be addressed by time-consuming and cost-intensive tasks. This deteriorates the process repeatability, reliability and part reproducibility. So far, many AM efforts have been performed in an isolated and scattered way over several decades. In this paper, a systematically integrated holistic view is proposed to achieve QA for AM. Design/methodology/approach A systematically integrated view is presented to ensure the predefined part properties before/during/after the AM process. It consists of four stages, namely, QA plan, prospective validation, concurrent validation and retrospective validation. As a foundation for QA planning, a functional workflow and the required information flows are proposed by using functional design models: Icam DEFinition for Function Modeling. Findings The functional design model of the QA plan provides the systematically integrated view that can be the basis for inspection of AM processes for the repeatability and qualification of AM parts for reproducibility. Research limitations/implications A powder bed fusion process was used to validate the feasibility of this QA plan. Feasibility was demonstrated under many assumptions; real validation is not included in this study. Social implications This study provides an innovative and transformative methodology that can lead to greater productivity and improved quality of AM parts across industries. Furthermore, the QA guidelines and functional design models provide the foundation for the development of a QA architecture and management system. Originality/value This systematically integrated view and the corresponding QA plan can pose fundamental questions to the AM community and initiate new research efforts in the in-situ digital inspection of AM processes and parts. 

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