839 resources related to Concurrent Engineering
- Topics related to Concurrent Engineering
- IEEE Organizations related to Concurrent Engineering
- Conferences related to Concurrent Engineering
- Periodicals related to Concurrent Engineering
- Most published Xplore authors for Concurrent Engineering
No organizations are currently tagged "Concurrent Engineering"
The IEEE/ACM Automated Software Engineering (ASE) Conference series is the premier research forum for automated software engineering. Each year, it brings together researchers and practitioners from academia and industry to discuss foundations, techniques and tools for automating the analysis, design, implementation, testing, and maintenance of large software systems.
All topics related to engineering and technology management, including applicable analytical methods and economical/social/human issues to be considered in making engineering decisions.
RAST 2019 aims providing a forum for the presentation and reviw of recentdevelopments in the space technologies, especially in the Space for the Sustainable Development Goals.
Collaboration technologies and applications to the design of processes, products, systems, and services in industries and societies. Application domains include aerospace, automotive, manufacturing, construction, logistics, transportation, power and energy, healthcare, infrastructure, administration, social networks, and entertainment.
The international IEEE Aerospace Conference is organized to promote interdisciplinaryunderstanding of aerospace systems, their underlying science, and technology
No periodicals are currently tagged "Concurrent Engineering"
IEE Colloquium on Current Developments in Concurrent Engineering - Methodologies and Tools, 1994
IEE Colloquium on Concurrent Engineering, 1993
IEE Colloquium on Issues of Co-Operative Working in Concurrent Engineering, 1994
IEEE Technical Applications Conference and Workshops. Northcon/95. Conference Record, 1995
The more complex a development effort, the more difficult it is to reduce or control the project's schedule and cost. The use of concurrent engineering in the development cycle only exacerbates the problem by increasing the number of departments and people involved at any point in the development effort. Breakdowns in the process can have devastating effects on the project ...
Proceedings Frontiers in Education 1995 25th Annual Conference. Engineering Education for the 21st Century, 1995
Summary form only given. Today's competitive need to develop high quality products has redefined the development role of engineering technologists. Today, engineers and engineering technologists assume much broader responsibilities. Responsibility for achieving specific technical performance requirements is now coupled with achieving requirements for project management, concurrent engineering, interdisciplinary problem solving, and teamwork. In effect, a technologist assumes two development roles; ...
The Era of AI Hardware - 2018 IEEE Industry Summit on the Future of Computing
EMBC 2011-Symposium on BME Education-PT II
2014 Medal in Power Engineering
Lionel Briand on Software Engineering
EMBC 2011-Keynote Lecture-Engineering Drug Dosing in Dynamic Biological Systems - David J. Balaban
EMBC 2011-Symposium on BME Education-PT I
Enjoy the Ride: An Engineers Plan to Make Engineering Hip
IMS 2015: Luca Pierantoni - A New Challenge in Computational Engineering
Engineering Workforce of the 21st Century: ISTAS 2019 Keynote by Babak D. Beheshti
EMBC 2011-Workshop-Nanobiomaterials-Rohin K. Iyer
IMS 2012 Special Sessions: Globalization of Engineering Education and Research: Opportunities and Challenges - Alan Cheville
IMS 2012 Special Sessions: Globalization of Engineering Education and Research: Opportunities and Challenges - Sigrid Berka
IMS 2012 Special Sessions: A Retrospective of Field Theory in Microwave Engineering - David M. Pozar
IMS 2012 Special Sessions: Globalization of Engineering Education and Research: Opportunities and Challenges - John M. Grandin
I Change the World: Jessica's Inspiration
Engineering For Social Good
Career Reflections - Candy Robinson at IEEE WIE Forum USA East 2017
IMS 2012 Special Sessions: A Retrospective of Field Theory in Microwave Engineering - Magdalena Salazar Palma
IMS 2012 Special Sessions: Globalization of Engineering Education and Research: Opportunities and Challenges - Ron Hira
The more complex a development effort, the more difficult it is to reduce or control the project's schedule and cost. The use of concurrent engineering in the development cycle only exacerbates the problem by increasing the number of departments and people involved at any point in the development effort. Breakdowns in the process can have devastating effects on the project schedule and double or even triple the development cost. Here, the author describes how these project elements can be effectively controlled using proven project management techniques. A number of companies involved in complex development efforts have been able to greatly reduce both development time and cost by applying these techniques.
Summary form only given. Today's competitive need to develop high quality products has redefined the development role of engineering technologists. Today, engineers and engineering technologists assume much broader responsibilities. Responsibility for achieving specific technical performance requirements is now coupled with achieving requirements for project management, concurrent engineering, interdisciplinary problem solving, and teamwork. In effect, a technologist assumes two development roles; project designer and project manager. The New Jersey Institute of Technology (NJIT) Engineering Technology (ET) department has implemented a senior project course which is responsive to the changing role of engineering technologists. Specifically, the senior project course for NJIT's Electrical Engineering Technology (EET) program emphasizes two aspects of project development: project design; and the development process associated with design and implementation.
After a number of decades of relative obscurity behind furious advancements in IC packaging technology, a review of recent advances in power device packaging is presented. General trends in relevant electrical and mechanical characteristics are reviewed. Then, the presentation covers in more detail, examples of how advances in both semiconductor content and advanced package design and materials have co-enabled the significant advances in power device capability during the last half decade. Extrapolating the same trends in representative areas to the remainder of the decade serves to highlight where further improvements in materials and techniques can drive continued enhancements in usability, efficiency, reliability, and overall cost of power semiconductor solutions. In addition to the forward looking trends it is important to recognize that the methods for concurrent engineering of these solutions (both the semiconductor content and high performance package capability) are becoming more increasingly dependent on rigorous use of proven multiphysics/FEA tools and techniques. In most cases this insures adequate program definition and timely program completion. In some cases the use of these tools by the teams involved lead directly to unanticipated and insightful solutions to problems which had previously remained intractable. Examples are described with illustrations and commentary.
This paper will discuss the need to achieve a multi-disciplinary team working environment as a prerequisite for facilitating a CE strategy. It wilt highlight the management initiatives in order to overcome the difficulties of implementation. The paper will also examine the role of enabling processes and techniques such as Computer Aided Design, Computer Aided Engineering and formal methods such as Design for Manufacture and Assembly to achieve reduced product development cycles, whilst improving the quality of products. Implementation plans and pitfalls will be highlighted and the challenges that the organisation faces in implementing a CE strategy will be examined. In conclusion, this paper will highlight recommendations from experience gained by companies who have implemented CE.
Fifteen academic and industry leaders share their views on current and future computer and related technology. They discuss Europe 1992 and its impact on information technology, 25 years of MITI and its influence on computing research in Japan, concurrent engineering, the scientific data decade, information systems, superconductivity and computing technology, semiconductor technology at middle age, past and future computer networks, testing and design verification of electronic components, operating systems in the year 2000, data parallel computing, computer-aided software prototyping, and object-oriented software technology.<>
A design method based on a template uses decomposition, combination, replacement and merging of the template for agility and variation of a model in global and local design. The authors have researched the fields of mechanical CAD and engineering CAD systems. Based on these works a concept of a cooperative template is presented in order to control and manage design tasks on the Net. It can inherit components that have been designed and give a nimble response for new projects if template technology is introduced into the public area of cooperative design. The paper discusses the work process of the template, its elements based on a cooperative mechanism and combines lock and semaphore functions and expands TDL (Template Design Language) using a cooperating primitive. Users are allowed to compete for design elements in the framework of visualization. Some technical problems concerning XML and JSP+Java Servlet are also discussed.
No standards are currently tagged "Concurrent Engineering"