Impact of quality attributes and the tradeoffs among competing quality attributes that provide the basis for design decisions. This discipline corresponds to the Section 2.3.4 in the SWEBOK.
In the Scenario Building phase, environment features, constraints and characteristics are defined. Furthermore, the robot's task is defined. This includes the specification of customer acceptance tests to be performed in the specified and potentially generalized environment.
| Key | Title | Authors | Year | Formalism |
|---|---|---|---|---|
| kunze2011towards | Towards semantic robot description languages | Kunze, Lars and Roehm, Tobias and Beetz, Michael | 2011 | OWL |
| Ciccozzi2016Adopting | Adopting MDE for Specifying and Executing Civilian Missions of Mobile Multi-Robot Systems | Federico Ciccozzi and Davide Di Ruscio and Ivano Malavolta and Patrizio Pelliccione | 2016 | |
| gritzner2018synthesizing | Synthesizing Executable PLC Code for Robots from Scenario-Based GR(1) Specifications | Gritzner, Daniel and Greenyer, Joel | 2018 |
In the Functional Design phase, hardware requirements and top-level functionalities are derived based on the scenario definition. Furthermore, top-level functionalities are decomposed and dependencies among them are identified. Also an initial functional design stating which functionalities interact with each other is developed.
| Key | Title | Authors | Year | Formalism |
|---|---|---|---|---|
| dittes2011intelligent | Intelligent system architectures-comparison by translation | Dittes, Benjamin and Goerick, Christian | 2011 | |
| dittes2011language | A language for formal design of embedded intelligence research systems | Dittes, Benjamin and Goerick, Christian | 2011 | other |
| Ciccozzi2016Adopting | Adopting MDE for Specifying and Executing Civilian Missions of Mobile Multi-Robot Systems | Federico Ciccozzi and Davide Di Ruscio and Ivano Malavolta and Patrizio Pelliccione | 2016 | |
| gritzner2018synthesizing | Synthesizing Executable PLC Code for Robots from Scenario-Based GR(1) Specifications | Gritzner, Daniel and Greenyer, Joel | 2018 |
In the Platform Building phase, the robot hardware is determined. This includes the selection and potential configuration of robot's sensors and actuators meeting the requirements defined in the functional design phase.
| Key | Title | Authors | Year | Formalism |
|---|---|---|---|---|
| bordignon2011generalized | Generalized programming of modular robots through kinematic configurations | Bordignon, Mirko and Stoy, Kasper and Schultz, Ulrik Pagh | 2011 | |
| ringert2015language | Language and code generator composition for model-driven engineering of robotics component \& connector systems | Ringert, Jan Oliver and Alexander, Roth and Bernhard, Rumpe and Andreas, Wortmann | 2015 | |
| gritzner2018synthesizing | Synthesizing Executable PLC Code for Robots from Scenario-Based GR(1) Specifications | Gritzner, Daniel and Greenyer, Joel | 2018 |
In the Capability Building phase, basic and composite components are constructed up to the application-level and constraints for their deployment are specified. This also includes the specification and eventually generation of additional knowledge required for component execution such as knowledge bases and training data.
| Key | Title | Authors | Year | Formalism |
|---|---|---|---|---|
| bordignon2011generalized | Generalized programming of modular robots through kinematic configurations | Bordignon, Mirko and Stoy, Kasper and Schultz, Ulrik Pagh | 2011 | |
| burbidge2009grammatical | Grammatical evolution of a robot controller | Burbidge, Robert and Walker, Joanne H and Wilson, Myra S | 2009 | (E)BNF |
| dittes2011intelligent | Intelligent system architectures-comparison by translation | Dittes, Benjamin and Goerick, Christian | 2011 | |
| dittes2011language | A language for formal design of embedded intelligence research systems | Dittes, Benjamin and Goerick, Christian | 2011 | other |
| kunze2011towards | Towards semantic robot description languages | Kunze, Lars and Roehm, Tobias and Beetz, Michael | 2011 | OWL |
| ringert2015language | Language and code generator composition for model-driven engineering of robotics component \& connector systems | Ringert, Jan Oliver and Alexander, Roth and Bernhard, Rumpe and Andreas, Wortmann | 2015 | |
| gritzner2018synthesizing | Synthesizing Executable PLC Code for Robots from Scenario-Based GR(1) Specifications | Gritzner, Daniel and Greenyer, Joel | 2018 |
In the System Deployment phase, top-level component(s) are packaged into a complete application system which defines a mapping of components and composites to computational units. Furthermore, features and procedures for system launch management are developed.
| Key | Title | Authors | Year | Formalism |
|---|---|---|---|---|
| ringert2015language | Language and code generator composition for model-driven engineering of robotics component \& connector systems | Ringert, Jan Oliver and Alexander, Roth and Bernhard, Rumpe and Andreas, Wortmann | 2015 |
In the Product Maintenance phase, the robot application is operated and maintained. This includes eventually the analysis of log files and the tuning of system parameters.
| Key | Title | Authors | Year | Formalism |
|---|---|---|---|---|
| Ciccozzi2016Adopting | Adopting MDE for Specifying and Executing Civilian Missions of Mobile Multi-Robot Systems | Federico Ciccozzi and Davide Di Ruscio and Ivano Malavolta and Patrizio Pelliccione | 2016 |
An important DSL is missing? Here is how to contribute! When using content of the Robotics DSL Zoo or referring to it, pleace consider citing our survey paper:
@article{nordmann2016survey,
author = {Nordmann, Arne and Hochgeschwender, Nico and Wigand, Dennis Leroy and Wrede, Sebastian},
journal = {Journal of Software Engineering in Robotics (JOSER)},
number = {1},
pages = {75--99},
title = {{A Survey on Domain-Specific Modeling and Languages in Robotics}},
volume = {7},
year = {2016},
}