The embedded systems segment is presently undergoing a disruptive innovation process. Different kinds of systems are connected to each other and systems of systems are formed. Boundaries of application domains are alleviated and ad-hoc connections and interoperability play an increasing role. In the present situation formerly closed systems are forced to be opened up. Traditional single-core processors used as computing resources are running out of business. Multi-core and Many-core processors become available whose exploitation for critical and real-time applications is presently happening unsatisfactorily slow, inefficient and expensive. Summarizing, this means their use in certified or qualified environments is challenging. The objective of the EMC2 project is to foster this change of embedded systems through an innovative and sustainable service-oriented architecture approach for mixed criticality applications in dynamic and changeable real-time environments. It is making the big step from basic research to industrial applications. The Artemis Innovation Pilot Project (AIPP) appears to be the best suited vehicle to provide this quantum leap. The EMC2 project builds on the results of previous Artemis, European and National projects and provides the paradigm shift to a new and sustainable system architecture which is suitable to handle open dynamic systems. The following challenges will be addressed and solutions developed to overcome: Dynamic Adaptability in Open Systems Utilization of expensive system features only as Service-on-Demand in order to reduce the overall system cost. Handling of mixed criticality applications under real-time conditions Scalability and utmost flexibility Full scale deployment and management of integrated tool chains, through the entire life cycle This embedded system approach will force the breakthrough and deployment of Multi-Core technology in almost all application domains where real-time and mixed-criticality are an issue such as Aerospace, Automotive, Railway, Shipping, Medical, Industrial factory automation and therefore strengthen the competitiveness of the European Embedded System industry

Description in Czech
V projektu jsou řešeny věstavěné multijádrové systémy pro aplikace se smíšenými bezpečnostními požadavky na kritičnost v dynamických a rychle se měnících prostředích.

Keywords
embedded systems, real-time environments

7H14011

English

Václavek Pavel, prof. Ing., Ph.D. - principal person responsible
Husár Adam, Ing., Ph.D. - fellow researcher
Jurzykowski Michal, Ing. - fellow researcher
Řezníček Ivo, Ing., Ph.D. - fellow researcher
Smrž Pavel, doc. RNDr., Ph.D. - fellow researcher

Central European Institute of Technology BUT
- responsible department (3.3.2014 - not assigned)
Computer Graphics Research Group
- internal (3.3.2014 - 31.3.2017)
Department of Computer Graphics and Multimedia
- co-beneficiary (3.3.2014 - 31.3.2017)
Central European Institute of Technology BUT
- beneficiary (3.3.2014 - 31.3.2017)

MUSIL, M.; MUSIL, P.; JURÁNEK, R.; ZEMČÍK, P.: WaldBoost Detector; HW detektor objektů ve videu. Místnost Q201, Fakulta informačních technologií VUT v Brně, Božetěchova 2, 612 66 Brno. URL: https://www.fit.vut.cz/research/product/540/. (software)
Detail

NOSKO, S.; MUSIL, M.; MUSIL, P.: Bilateral filter IP core; Bilateralni filtr pro HDR tone mapping (IP jádro). Místnost Q201, Fakulta informačních technologií VUT v Brně, Božetěchova 2, 612 66 Brno. URL: https://www.fit.vut.cz/research/product/539/. (software)
Detail

MUSIL, M.; NOSKO, S.: HDR deghoster SW; Software pro pořizování a deghosting HDR snímků. Místnost Q201, Fakulta informačních technologií VUT v Brně, Božetěchova 2, 612 66 Brno. URL: https://www.fit.vut.cz/research/product/536/. (software)
Detail

NOSKO, S.; MUSIL, M.; MUSIL, P.; ZEMČÍK, P. True HDR camera with bilateral filter based tone mapping. In SCCG '17: Spring Conference on Computer Graphics 2017. Mikulov: Association for Computing Machinery, 2017. p. 1-9. ISBN: 978-1-4503-5107-2.
Detail

NOSKO, S.; MUSIL, M.; MUSIL, P.: ZynqHDRVideoCam; Funkční vzorek kamery pro snímání a tónování HDR videa. Místnost Q201, Fakulta informačních technologií VUT v Brně, Božetěchova 2, 612 66 Brno. URL: https://www.fit.vut.cz/research/product/520/. (funkční vzorek)
Detail

ZEMČÍK, P.; MUSIL, P.; MUSIL, M. High Dynamic Range Video. In High Dynamic Range Video, 1st Edition. London: Elsevier Science, 2016. p. 145-154. ISBN: 978-0-12-809477-8.
Detail

MUSIL, P.; MUSIL, M.; ZEMČÍK, P.; JURÁNEK, R.: DetectorCore; VHDL Detector IP Core. http://www.fit.vutbr.cz/units/UPGM/prod/index.php?id=484¬itle=1. URL: http://www.fit.vutbr.cz/units/UPGM/prod/index.php?id=484¬itle=1. (funkční vzorek)
Detail

ZEMČÍK, P.; JURÁNEK, R.: LBPTRAINING; LBP Detector Training for Matlab. http://www.fit.vutbr.cz/~ijuranek/prods.php?id=477¬itle=1. URL: http://www.fit.vutbr.cz/~ijuranek/prods.php?id=477¬itle=1. (software)
Detail

HUSÁR, A.; BURGET, R.; ČEKAN, O.; PODIVÍNSKÝ, J.; HRUŠKA, T.: MODELROVEX2015; Model procesoru roVEX a jeho překladač. Software je dostupné na Fakultě informačních technologií Vysokého učení technického v Brně, Božetěchova 2, 612 66 Brno, www.fit.vutbr.cz. URL: https://www.fit.vut.cz/research/product/435/. (software)
Detail

Responsibility: Václavek Pavel, prof. Ing., Ph.D.