THERMOBOT | Autonomous robotic system for thermo-graphic detection of cracks
01-01-2012
-31-12-2014
01-01-2012
-31-12-2014
01-12-2012
-30-11-2015
15-01-2013
-14-07-2016
01-09-2012
-31-08-2015
Des-MOLD imply the development of a Geometry module : software to simplify the design of geometry to a set of primitives. It allows the system to compare designs.
Des-MOLD is an intelligent knowledge-based system which presents the use of different Artificial Intelligence techniques to develop a decision support system for designers of plastic parts. Our approach is based on computational argumentation (ARG) and case-based reasoning (CBR) to offer both a recommendation about the design and the reasoning process followed in order to select that solution. Given the geometry of the part, type of material, mould’s material and defects to be avoid, the system combines a knowledge-based system (KBS) based on past experiences with designers social debates for providing a set of recommendations, enabling to update the knowledge database by reusing and adapting solutions from previous designs.
Our approach is based on computational argumentation (ARG) and case-based reasoning (CBR) to offer both a recommendation about the design and the reasoning process followed in order to select that solution. Given the geometry of the part, type of material, mould’s material and defects to be avoid, the system combines a knowledge-based system (KBS) based on past experiences with designers social debates for providing a set of recommendations, enabling to update the knowledge database by reusing and adapting solutions from previous designs
01-10-2012
-30-09-2015
01-10-2012
-30-09-2015
01-10-2012
-30-09-2015
01-09-2013
-31-08-2016
01-07-2013
-30-06-2016
Demonstrator 1 - RDSS Validation of Life Cycle Cost (LCC) analysis integrated with Reliability and Maintainability (R&M) simulation and Repair Decision Support System Tools/methods applies to evaluate the MTBF, MTTR and LCC of machines identified among end-users
02-09-2013
-01-09-2017
01-09-2013
-31-08-2016
01-10-2013
-30-09-2017
01-09-2013
-28-02-2017
01-10-2013
-30-09-2016
01-10-2013
-30-09-2017
Development of holistic simulation platform for factories integrating the production, energy and environmental aspects.
01-09-2013
-29-02-2016
01-09-2013
-31-08-2017
01-11-2013
-30-04-2017
01-10-2013
-30-09-2016
01-10-2013
-30-09-2016
01-07-2013
-30-06-2016
01-09-2013
-30-11-2016
Digital factory model from 3D laser scanning combined with Virtual Reality models
01-01-2014
-31-12-2017
01-09-2013
-31-08-2016
01-01-2015
-31-12-2017
01-01-2015
-30-06-2018
01-01-2015
-31-12-2017
FALCON aims to provide methodologies and approaches for representation of design knowledge on the one hand and additionally for forecasting and simulation mechanism. The representation of design knowledge will be based on existing standards and the developments dedicated to the Rule Interchange Format, which has been developed within the FP7 LinkedDesign project. Furthermore, FALCON supports the optimization of Forecasting and Simulation mechanism. By using real-life data gathered from Product Embedded Information Devices, sensors or from social media (blogs, twitter, facebook etc.) throughout the whole lifecycle optimized results are expected in order to find the best solutions for new generation product-services.
The FALCON Open Virtual Platform aims to support different domains dedicated to the whole lifecycle of products. In order to achieve this goal the Virtual Open Platform will include an ontology enabling different domains to exploit the FALCON VOP. Dedicated to the field of new product design the Rule Interchange Format will be further developed in order to represent design knowledge in a neutral format. This way also general valid knowledge (such as Moment of Inertia etc.) can be re-used in different contexts of product design.
01-01-2015
-31-12-2017
01-12-2014
-30-11-2018
http://thermobot.eu/wp-content/uploads/2011/09/20130409_UNIPD_Crack_detection_HES-13.dochttp://thermobot.eu/wp-content/uploads/2011/09/20130409_UNIPD_Crack_detection_HES-13.doc