entities, including hierarchical ones, represented at
database level, ensures generality and applicability in
various cases. Pattern matching rules and canonical
representatives are used in the cloud database.
We reveal the advantages of applying the
algebraic equivalence algorithm and of applying
canonical representatives’ properties in solving
pattern matching problems and designing data
interchange services.
The data interchange model we present provides
important practical advantages for increasing
organizational competitiveness, with a significant
societal impact on institutional and entities’
cooperation, efficient information access and
management for various stakeholders. A relevant
advantage of the solution is its flexibility and
efficiency in information exchange (only relevant
data is exchanged), with minimal resources involved
and significant security benefits.
Future work is related to further development and
implementation of the above described techniques.
REFERENCES
Andreica, A, Stuparu, D, and Miu, C. (2012). Applying
Mathematical Models in Software Design, 2012 IEEE
8th International Conference on Intelligent Computer
Communication and Processing, Cluj-Napoca,
Romania, Proceedings of ICCP 2012, IEEE, Ed: Ioan
Alfred Letia, p.87-90
Olmedilla, D., Saito, N., and Simon, B. eds. (2006).
“Educational Technology & Society”, Special Issue on
Interoperability of Educational Systems, vol 9
Andreica, A, Stuparu, D, and Miu, C., (2010). “Design
Techniques in Processing Hierarchical Structures at
Database Level”, Proceedings of Iadis Information
Systems 2010, Porto, 18-20 March 2010 , IADIS
Press, Ed: M Nunes, P Isaias, P Powell, p. 483-488
Ziemann, J. (2010). “Architecture of Interoperable
Information Systems - An Enterprise Model-Based for
Describing and Enacting Collaborative Business
Processes”, Logos Verlag, Berlin
Andreica, A, Covaci, F. and Küng, J. (2015). A Generic
Model for Cloud Data Interchange, Proceedings of
14h RoEduNet International Conference - IEEE,
Craiova, 24-26 September 2015, IEEE Computer
Society, p. 138-142
Adams, S, Hardas, D, Iossein, A. and Kaiman,. C. (2002)
BizTalk Unleashed. Indianapolis, Indiana: Sams
Publishing. p. 966
XML standard, http://www.w3.org/TR/xml11/#charsets ,
retreived Nov 2015
Rosetta – Rosettanet Overview: Clusters, Segments, and
PIPs (ver 02.13.00), 2011, retrieved December 2015
http://www.rosettanet.org/TheStandards/RosettaNetSt
andards/PIPOverview/tabid/3482/Default.aspx
OASIS – OASIS ebXML Messaging Services Version 3.0:
Part 1, Core Features, 2007. http://docs.oasis-
open.org/ebxml-msg/ebms/v3.0/core/ebms_core-3.0-
spec.pdf, retreived Dec 2015
Stumme, G., Wille, R. (2000). „Begriffliche
Wissensverarbeitung / Conceptual Knowledge
Processing“, Springer Verlag,
OpenIoT - Open Internet of Things architecture
https://github.com/OpenIotOrg/openiot/wiki/OpenIoT-
Architecture , retreived Dec 2015
Buchberger B. and Loos, R. (1982) Algebraic
Simplification, Computing, Suppl. 4, Springer Verlag,
p.11-43
Andreica, A (2016) Applying Equivalence Algorithms in
Solving Pattern Matching Problems. Case Study for
Expert System Design, Proceedings of International
Conference on Theory and Practice in Modern
Computing- TPMC, July 1-4, 2016, Portugal
Andreica, A, Stuparu, D. and Mantu, I. (2005). “Symbolic
Modelling of Database Representations”, International
Symposium on Symbolic and Numeric Algorithms for
Scientific Computing 2005, IEEE Press, p 59-62
Morris, E., Levine, L, Meyers, C., Place, P. and Plakosh.
D. (2004) “System of Systems Interoperability (SOSI):
Final Report”, Carnegie Mellon Univ., Software
Engineering Institute, http://www.sei.cmu.edu/reports/
04tr004.pdf , accessed May 2016
Weiss, G. E, (1999). “Multiagent Systems: A Modern
Approach to Distributed Artificial Intelligence”, MIT,
Faulkner, S, Kolp, M, Nguyen, Tai, Coyette, A, Do, T.
(2014). “Information Integration Architecture
Development: A Multi-Agent Approach”, retr Nov
2016
Wiederhold, G, (1992). “Mediators in the Architecture of
Future Information Systems”, IEEE Computer, 25:38-
49
Chawathe, S, Garcia-Molina, H, Hammer, J,.Ireland, K,
Papakonstatinou, Y, Ullman, J, Widom,. J, (1994).
“The TSIMMIS Project: Integration of Heterogeneous
Information Sources”, , retreived Jan 2015
http://ilpubs.stanford.edu:8090/66/1/1994-32.pdf
Designing Uniform Database Representations for Cloud Data Interchange Services
559