@phdthesis{Hernandez-2013a,
	Abstract = {Technical systems are becoming more complex, they incorporate more advanced func- tionalities, they are more integrated with other systems and they are deployed in less controlled environments. All this supposes a more demanding and uncertain scenario for control systems, which are also required to be more autonomous and dependable. Autonomous adaptivity is a current challenge for extant control technologies. The ASys research project proposes to address it by moving the responsibility for adaptiv- ity from the engineers at design time to the system at run-time.
This thesis has intended to advance in the formulation and technical reification of ASys principles of model-based self-cognition and having systems self-handle at run-time for robust autonomy. For that it has focused on the biologically inspired capability of self-awareness, and explored the possibilities to embed it into the very architecture of control systems.
Besides self-awareness, other themes related to the envisioned solution have been explored: functional modeling, software modeling, patterns technology, components technology, fault tolerance. The state of the art in fields relevant for the issues of self- awareness and adaptivity has been analysed: cognitive architectures, fault-tolerant control, and software architectural reflection and autonomic computing. The extant and evolving ASys Theoretical Framework for cognitive autonomous systems has been adapted to provide a basement for this selfhood-centred analysis and to con- ceptually support the subsequent development of our solution.
The thesis proposes a general design solution for building self-aware autonomous systems. Its central idea is the integration of a metacontroller in the control archi- tecture of the autonomous system, capable of perceiving the functional state of the control system and reconfiguring it if necessary at run-time.
This metacontrol solution has been formalised into four design patterns: i) the Metacontrol Pattern, which defines the integration of a metacontrol subsystem, con- trolling the domain control system through an interface provided by its implemen- tation component platform, ii) the Epistemic Control Loop pattern, which defines a model-based cognitive control loop that can be applied to the design of such a meta- controller, iii) the Deep Model Reflection pattern proposes a solution to produce the online executable model used by the metacontroller by model-to-model transforma- tion from the engineering model, and, finally, iv) the Functional Metacontrol pattern,
v
which proposes to structure the metacontroller in two loops, one for controlling the configuration of components of the controller, and another one on top of the former, controlling the functions being realised by that configuration; this way the functional and structural concerns become decoupled.
A reference architecture and an associated metamodel are the core pieces of the architectural framework developed to reify this patterned solution. The metamodel has been developed for representing the structure and its relation to the functional requirements of any autonomous system. The architecture is a blueprint for building a metacontroller according to the patterns. This metacontroller can be integrated on top of any component-based control architecture. At the core of its operation lies a model of the control system that conforms to the metamodel.
An engineering process and accompanying assets have been constructed to com- plete and exploit the architectural framework. The engineering process defines the methodology to follow to develop the metacontrol subsystem from the functional model of the controller of the autonomous system. The assets include software li- braries that provide a domain and application-independent implementation of the meta- controller. They can be used in the implementation phase of the methodology.
Finally, the complete solution has been validated in the development of an au- tonomous mobile robot that incorporates an metacontroller. The functional self-awareness and adaptivity properties achieved thanks to the metacontrol system have been vali- dated in different scenarios. In these scenarios the robot was able to overcome failures
in the control system thanks to reconfigurations performed by the metacontroller.},
	Address = {Jos{\'e} Gutierrez Abascal 2, 28006 Madrid (SPAIN)},
	Author = {Carlos Hern{\'a}ndez},
	Date-Added = {2014-10-31 12:50:58 +0000},
	Date-Modified = {2014-10-31 12:55:07 +0000},
	Keywords = {cognitive architecture, consciousness, autonomous systems, general systems theory},
	Month = {October},
	Rating = {5},
	Read = {1},
	School = {Universidad Polit{\'e}cnica de Madrid, ETSII, Dpto. Autom{\'a}tica, Ing. Electr{\'o}nica e Inform{\'a}tica Industrial},
	Title = {Model-based Self-awareness Patterns for Autonomy},
	Year = {2013},
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For that it has focused on the biologically inspired capability of self-awareness, and explored the possibilities to embed it into the very architecture of control systems. Besides self-awareness, other themes related to the envisioned solution have been explored: functional modeling, software modeling, patterns technology, components technology, fault tolerance. The state of the art in fields relevant for the issues of self- awareness and adaptivity has been analysed: cognitive architectures, fault-tolerant control, and software architectural reflection and autonomic computing. The extant and evolving ASys Theoretical Framework for cognitive autonomous systems has been adapted to provide a basement for this selfhood-centred analysis and to con- ceptually support the subsequent development of our solution. The thesis proposes a general design solution for building self-aware autonomous systems. Its central idea is the integration of a metacontroller in the control archi- tecture of the autonomous system, capable of perceiving the functional state of the control system and reconfiguring it if necessary at run-time. This metacontrol solution has been formalised into four design patterns: i) the Metacontrol Pattern, which defines the integration of a metacontrol subsystem, con- trolling the domain control system through an interface provided by its implemen- tation component platform, ii) the Epistemic Control Loop pattern, which defines a model-based cognitive control loop that can be applied to the design of such a meta- controller, iii) the Deep Model Reflection pattern proposes a solution to produce the online executable model used by the metacontroller by model-to-model transforma- tion from the engineering model, and, finally, iv) the Functional Metacontrol pattern, v which proposes to structure the metacontroller in two loops, one for controlling the configuration of components of the controller, and another one on top of the former, controlling the functions being realised by that configuration; this way the functional and structural concerns become decoupled. A reference architecture and an associated metamodel are the core pieces of the architectural framework developed to reify this patterned solution. The metamodel has been developed for representing the structure and its relation to the functional requirements of any autonomous system. The architecture is a blueprint for building a metacontroller according to the patterns. This metacontroller can be integrated on top of any component-based control architecture. At the core of its operation lies a model of the control system that conforms to the metamodel. An engineering process and accompanying assets have been constructed to com- plete and exploit the architectural framework. The engineering process defines the methodology to follow to develop the metacontrol subsystem from the functional model of the controller of the autonomous system. The assets include software li- braries that provide a domain and application-independent implementation of the meta- controller. They can be used in the implementation phase of the methodology. Finally, the complete solution has been validated in the development of an au- tonomous mobile robot that incorporates an metacontroller. The functional self-awareness and adaptivity properties achieved thanks to the metacontrol system have been vali- dated in different scenarios. In these scenarios the robot was able to overcome failures in the control system thanks to reconfigurations performed by the metacontroller.","address":"José Gutierrez Abascal 2, 28006 Madrid (SPAIN)","author":[{"firstnames":["Carlos"],"propositions":[],"lastnames":["Hernández"],"suffixes":[]}],"date-added":"2014-10-31 12:50:58 +0000","date-modified":"2014-10-31 12:55:07 +0000","keywords":"cognitive architecture, consciousness, autonomous systems, general systems theory","month":"October","rating":"5","read":"1","school":"Universidad Politécnica de Madrid, ETSII, Dpto. Automática, Ing. 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All this supposes a more demanding and uncertain scenario for control systems, which are also required to be more autonomous and dependable. Autonomous adaptivity is a current challenge for extant control technologies. The ASys research project proposes to address it by moving the responsibility for adaptiv- ity from the engineers at design time to the system at run-time.\nThis thesis has intended to advance in the formulation and technical reification of ASys principles of model-based self-cognition and having systems self-handle at run-time for robust autonomy. For that it has focused on the biologically inspired capability of self-awareness, and explored the possibilities to embed it into the very architecture of control systems.\nBesides self-awareness, other themes related to the envisioned solution have been explored: functional modeling, software modeling, patterns technology, components technology, fault tolerance. The state of the art in fields relevant for the issues of self- awareness and adaptivity has been analysed: cognitive architectures, fault-tolerant control, and software architectural reflection and autonomic computing. The extant and evolving ASys Theoretical Framework for cognitive autonomous systems has been adapted to provide a basement for this selfhood-centred analysis and to con- ceptually support the subsequent development of our solution.\nThe thesis proposes a general design solution for building self-aware autonomous systems. Its central idea is the integration of a metacontroller in the control archi- tecture of the autonomous system, capable of perceiving the functional state of the control system and reconfiguring it if necessary at run-time.\nThis metacontrol solution has been formalised into four design patterns: i) the Metacontrol Pattern, which defines the integration of a metacontrol subsystem, con- trolling the domain control system through an interface provided by its implemen- tation component platform, ii) the Epistemic Control Loop pattern, which defines a model-based cognitive control loop that can be applied to the design of such a meta- controller, iii) the Deep Model Reflection pattern proposes a solution to produce the online executable model used by the metacontroller by model-to-model transforma- tion from the engineering model, and, finally, iv) the Functional Metacontrol pattern,\nv\nwhich proposes to structure the metacontroller in two loops, one for controlling the configuration of components of the controller, and another one on top of the former, controlling the functions being realised by that configuration; this way the functional and structural concerns become decoupled.\nA reference architecture and an associated metamodel are the core pieces of the architectural framework developed to reify this patterned solution. The metamodel has been developed for representing the structure and its relation to the functional requirements of any autonomous system. The architecture is a blueprint for building a metacontroller according to the patterns. This metacontroller can be integrated on top of any component-based control architecture. At the core of its operation lies a model of the control system that conforms to the metamodel.\nAn engineering process and accompanying assets have been constructed to com- plete and exploit the architectural framework. The engineering process defines the methodology to follow to develop the metacontrol subsystem from the functional model of the controller of the autonomous system. The assets include software li- braries that provide a domain and application-independent implementation of the meta- controller. They can be used in the implementation phase of the methodology.\nFinally, the complete solution has been validated in the development of an au- tonomous mobile robot that incorporates an metacontroller. The functional self-awareness and adaptivity properties achieved thanks to the metacontrol system have been vali- dated in different scenarios. In these scenarios the robot was able to overcome failures\nin the control system thanks to reconfigurations performed by the metacontroller.},\n\tAddress = {Jos{\\'e} Gutierrez Abascal 2, 28006 Madrid (SPAIN)},\n\tAuthor = {Carlos Hern{\\'a}ndez},\n\tDate-Added = {2014-10-31 12:50:58 +0000},\n\tDate-Modified = {2014-10-31 12:55:07 +0000},\n\tKeywords = {cognitive architecture, consciousness, autonomous systems, general systems theory},\n\tMonth = {October},\n\tRating = {5},\n\tRead = {1},\n\tSchool = {Universidad Polit{\\'e}cnica de Madrid, ETSII, Dpto. Autom{\\'a}tica, Ing. 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