The C2AC Roadmap for Modeling and Simulation: Context, Composition, Automation, and Communication

Standardizing context representation in the simulation community can be achieved through the development and adoption of common documentation guidelines and provenance standards. By establishing clear reporting guidelines for simulation studies, researchers can ensure that essential context information, such as research questions, assumptions, data sources, and simulation experiments, is consistently documented. This standardization can help in promoting transparency, reproducibility, and the effective communication of simulation results. In addition to reporting guidelines, leveraging provenance standards, such as PROV-DM, can provide a structured framework for capturing the process-oriented view of context in simulation studies. Provenance information can help in tracking the evolution of simulation artifacts, understanding the relationships between different components, and ensuring that context information is maintained and accessible over time. By incorporating provenance standards into simulation practices, researchers can establish a common language and methodology for representing and managing context information effectively.

Maintaining and evolving context information in simulation studies pose several challenges, including the need for comprehensive documentation, the management of evolving simulation artifacts, and the integration of informal context into formal representations. To address these challenges, researchers can implement tools and methods that facilitate the collection, storage, and retrieval of context information in a structured and accessible manner. One approach is to utilize workflow systems that capture the provenance of simulation activities and artifacts, providing a detailed record of the simulation study's evolution. By integrating workflow systems with provenance standards, researchers can track changes, variations, and dependencies within the simulation process, enabling better management and maintenance of context information. Furthermore, the development of feature description languages and model transformation techniques can help in managing variability and evolution in simulation artifacts. By formalizing the representation of context information and incorporating mechanisms for version control and abstraction, researchers can address the challenges of maintaining and evolving context information in simulation studies effectively.

Provenance information can be leveraged to automate simulation experiments effectively by providing insights into the relationships between different simulation artifacts, activities, and outcomes. By analyzing the provenance data, researchers can identify patterns, dependencies, and best practices in conducting simulation experiments, which can inform the automation process. One way to automate simulation experiments using provenance information is to develop intelligent systems that can recommend experiment designs, parameter settings, and analysis techniques based on historical data and provenance records. By leveraging machine learning algorithms and data mining techniques, researchers can extract valuable insights from provenance information and use them to guide the automation of simulation experiments. Additionally, integrating provenance information with workflow systems can enable the automatic generation of simulation experiment pipelines, where each step is informed by the provenance data from previous activities. This approach can streamline the process of setting up, executing, and analyzing simulation experiments, ultimately improving efficiency and reproducibility in simulation studies.