Developing BP-driven web application through the use of MDE techniques

Model driven engineering (MDE) is a suitable approach for performing the construction of software systems (in particular in the Web application domain). There are different types of Web applications depending on their purpose (i.e., document-centric, interactive, transactional, workflow/business process-based, collaborative, etc). This work focusses on business process-based Web applications in order to be able to understand business processes in a broad sense, from the lightweight business processes already addressed by existing proposals to long-running asynchronous processes. This work presents a MDE method for the construction of systems of this type. The method has been designed in two steps following the MDE principles. In the first step, the system is represented by means of models in a technology-independent manner. These models capture the different aspects of Web-based systems (these aspects refer to behaviour, structure, navigation, and presentation issues). In the second step, the model transformations (both model-to- model and model-to-text) are applied in order to obtain the final system in terms of a specific technology. In addition, a set ofEclipse-based tools has been developed to provide automation in the application of the proposed method in order to validate the proposal.Torres Bosch, MV.; Giner Blasco, P.; Pelechano Ferragud, V. (2012). Developing BP-driven web application through the use of MDE techniques. Software and Systems Modeling. 11(4):609-631. doi:10.1007/s10270-010-0177-5S609631114Andrews, T., Curbera, F., Dholakia, H., Goland, Y., Klein, J., Leymann, F., Liu, K., Roller, D., Smith, D., Thatte, S., Trickovic, I., Weerawarana, S.: Business process execution language for Web services version 1.1 (May 2003)Barna, P., Frasincar, F., Houben, G.J.: A workow-driven design of Web information systems. In: Wolber, D., Calder, N., Brooks, C., Ginige, A. (eds.) ICWE, ACM, pp. 321–328Bakshi, K., Karger, D.R.: Semantic Web applications. In: Proceedings of the ISWC 2005 Workshop on End User Semantic Web Interaction (November 2005)Brambilla M., Ceri S., Fraternali P., Manolescu I.: Process modeling in Web applications. ACM Trans. Softw. Eng. Methodol. 15(4), 360–409 (2006)Brambilla, M., Preciado, J.C., Trigueros, M.L., Sánchez-Figueroa F.: Business process-based conceptual design of rich internet applications. In: ICWE, pp. 155–161 (2008)Brambilla, M., Butti, S., Fraternali, P.: Webratio bpm: a tool for designing and deploying business processes on the Web. In: ICWE, pp. 415–429 (2010)Business process modeling notation (BPMN). OMG final adopted specification. dtc/06-02-01 (February 2006)Ceri, S., Fraternali, P., Bongio, A.: Web modeling language (Webml): a modeling language for designing Web sites. In: Proceedings of the 9th international World Wide Web conference on Computer networks : the international journal of computer and telecommunications networking, Amsterdam, The Netherlands, pp. 137–157. North-Holland Publishing Co., The Netherlands (2000)Davis J.: Open Source SOA. Manning Publications Co, Greenwich (2009)Distante, D.: Reengineering legacy applications and Web transactions: an extended version of the UWA transaction design model. Ph.D. thesis, University of Lecce, Italy (2004)Distante D., Rossi G., Canfora G., Tilley S.R.: A comprehensive design model for integrating business processes in Web applications. Int. J. Web Eng. Technol. 3(1), 43–72 (2007)Duhl, J.: Rich internet applications. Technical report, IDC (November 2003)Fons, J.: OOWS: A model driven method for the development of web applications. Ph.D. thesis, Universidad Politécnica de Valencia (2008)Fons, J., Pelechano, V., Pastor, O., Valderas, P., Torres, V.: Applying the OOWS model-driven approach for developing web applications. The internet movie database case study. In: Web Engineering: Modelling and Implementing Web Applications. Human–Computer Interaction Series, pp. 65–108. Springer, London (2008)Fowler, M.: Inversion of control containers and the dependency injection pattern. http://martinfowler.com/articles/injection.html (January 2004)Gershenfeld N., Krikorian R., Cohen D.: The internet of things. Sci Am 291(4), 76–81 (2004)Giner P., Cetina C., Fons J., Pelechano V.: Developing mobile business processes for the internet of things. IEEE Pervasive Comput. 9, 18–26 (2010)Gómez J., Cachero C., Pastor O.: Extending a conceptual modelling approach to Web application design. In: Wangler, B., Bergman, L. (eds) CAiSE. Lecture Notes in Computer Science, vol. 1789, pp. 79–93. Springer, London (2000)Goth G.: The task-based interface: not your father’s desktop. IEEE Software 26(6), 88–91 (2009)Holmes, T., Tran, H., Zdun, U., Dustdar, S.: Modeling human aspects of business processes—a view-based, model-driven approach. In: ECMDA-FA, pp. 246–261 (2008)Kappel, G., Pröll, B., Reich, S., Retschitzegger, W. (eds): Web Engineering—The Discipline of Systematic Development of Web Applications. Wiley, England (2006)Koch, N.: Software Engineering for Adaptive Hypermedia Systems: Reference Model, Modeling Techniques and Development Process. Ph.D. thesis, Ludwig-Maximilians-University Munich, Germany (2001)Koch N., Kraus A., Cachero C., Meliá S.: Integration of business processes in Web application models. J. Web Eng. 3(1), 22–49 (2004)Limbourg, Q., Vanderdonckt, J.: Usixml: a user interface description language supporting multiple levels of independence. In: ICWE Workshops, pp. 325–338 (2004)Linaje M., Preciado J.C., Sánchez-Figueroa F.: Engineering rich internet application user interfaces over legacy Web models. IEEE Internet Comput. 11(6), 53–59 (2007)Link, S., Hoyer, P., Schuster, T., Abeck, S.: Model-driven development of human tasks for workflows. In: ICSEA ‘08: Proceedings of the 2008 third international conference on software engineering advances, Washington, DC, USA, pp. 329–335. IEEE Computer Society, Washington, DC (2008)Marcos, E., Cáceres, P., Castro, V. D.: An approach for navigation model construction from the use cases model. In: CAiSE Forum. Held in conjunction with the 16th Conference On Advanced Information Systems Engineering (June 2004)Pietschmann, S., Voigt, M., Meissner, K.: Adaptive rich user interfaces for human interaction in business processes. In: Proceedings of the 10th International Conference on Web Information Systems Engineering (WISE 2009), WISE, pp. 351–364. Springer LNCS (October 2009)Schwabe D., Rossi G.: An object oriented approach to Web-based applications design. Theor. Pract. Object Syst. 4(4), 207–225 (1998)Schmid H.A., Rossi G.: Modeling and designing processes in e-commerce applications. IEEE Internet Comput. 8(1), 19–27 (2004)Schwinger W., Retschitzegger W., Schauerhuber A., Kappel G., Wimmer M., Pröll B., Cachero C., Casteleyn S., Troyer O.D., Fraternali P., Garrigós I., Garzotto F., Ginige A., Houben G.J., Koch N., Moreno N., Pastor O., Paolini P., Pelechano V., Rossi G., Schwabe D., Tisi M., Vallecillo A., van der Sluijs K., Zhang G.: A survey on Web modeling approaches for ubiquitous Web applications. IJWIS 4(3), 234–305 (2008)Sousa K.S., Mendona H., Vanderdonckt J.: A model-driven approach to align business processes with user interfaces. J. UCS 14(19), 3236–3249 (2008)Sukaviriya, N., Sinha, V., Ramachandra, T., Mani, S.: Model-driven approach for managing human interface design life cycle. In: MoDELS, pp. 226–240 (2007)Tedre M.: What should be automated?. Interactions 15(5), 47–49 (2008)Torres, V., Giner, P., Bonet, B., Pelechano, V.: Adapting BPMN to Public Administration. In: Proceedings BPMN 2010 Springer’s Lecture Notes in Business Information Processing (LNBIP). Postdam, Germany (to appear)Troyer, O.D., Casteleyn, S.: Modeling complex processes for Web applications using wsdm. In: Proceedings of the Third International Workshop on Web-Oriented Software Technologies (held in conjunction with ICWE2003), IWWOST2003 (2003

The Modelery: a model-based software development repository

Purpose – This paper aims to present the Modelery, a platform for collaborative repository to support model-based software development. The Modelery is a Web platform, composed both by a Web page and Web services for interoperability. Design/methodology/approach – By performing a study in the existing platforms, it was possible to achieve a set of issues to tackle. The issues enabled the possibility to define a set of requirements that allowed the authors to design a new platform, and to perform a model-driven software development process, which started from the requirements until reaching the final software solution. Findings – With this work, it was possible to perform a survey on the currently available artifacts repositories, categorize them and identify their shortcomings. This was essential to define the set of requirements for a new platform to overcome the identified issues. This process leads to a platform able to improve the currently available solutions, and validated in the scientific community. In this paper, the authors also explore the applications of the repository. First, they use the Modelery to replace an older model’s repository. Second, they have enabled the communication between other tools and the Modelery via Web services. Originality/value – This work presents a new Web repository for software artifacts aimed at supporting researchers and software developers. The presented platform is an improvement over other platforms on the integration of artifacts repository, social functionalities and scientific publications integration. The authors conclude this paper by comparing the achieved platform in terms of functionalities, against the other analyzed platforms

Specifications and Development of Interoperability Solution dedicated to Multiple Expertise Collaboration in a Design Framework

This paper describes the specifications of an interoperability platform based on the PPO (Product Process Organization) model developed by the French community IPPOP in the context of collaborative and innovative design. By using PPO model as a reference, this work aims to connect together heterogonous tools used by experts easing data and information exchanges. After underlining the growing needs of collaborative design process, this paper focuses on interoperability concept by describing current solutions and their limits. Then a solution based on the flexibility of the PPO model adapted to the philosophy of interoperability is proposed. To illustrate these concepts, several examples are more particularly described (robustness analysis, CAD and Product Lifecycle Management systems connections)

Ontology-based collaborative framework for disaster recovery scenarios

This paper aims at designing of adaptive framework for supporting collaborative work of different actors in public safety and disaster recovery missions. In such scenarios, firemen and robots interact to each other to reach a common goal; firemen team is equipped with smart devices and robots team is supplied with communication technologies, and should carry on specific tasks. Here, reliable connection is mandatory to ensure the interaction between actors. But wireless access network and communication resources are vulnerable in the event of a sudden unexpected change in the environment. Also, the continuous change in the mission requirements such as inclusion/exclusion of new actor, changing the actor's priority and the limitations of smart devices need to be monitored. To perform dynamically in such case, the presented framework is based on a generic multi-level modeling approach that ensures adaptation handled by semantic modeling. Automated self-configuration is driven by rule-based reconfiguration policies through ontology

Mobile support in CSCW applications and groupware development frameworks

Computer Supported Cooperative Work (CSCW) is an established subset of the field of Human Computer Interaction that deals with the how people use computing technology to enhance group interaction and collaboration. Mobile CSCW has emerged as a result of the progression from personal desktop computing to the mobile device platforms that are ubiquitous today. CSCW aims to not only connect people and facilitate communication through using computers; it aims to provide conceptual models coupled with technology to manage, mediate, and assist collaborative processes. Mobile CSCW research looks to fulfil these aims through the adoption of mobile technology and consideration for the mobile user. Facilitating collaboration using mobile devices brings new challenges. Some of these challenges are inherent to the nature of the device hardware, while others focus on the understanding of how to engineer software to maximize effectiveness for the end-users. This paper reviews seminal and state-of-the-art cooperative software applications and development frameworks, and their support for mobile devices