Model-driven Service Engineering Towards the Manufacturing
Liquid-sensing Enterprise
Carlos Agostinho
1
, Michele Sesana
2
, Ricardo Jardim-Gonçalves
1,3
and Sergio Gusmeroli
2
1
Centre of Technology and Systems, CTS, Uninova, 2829-516 Caparica, Portugal
2
TXT e-solutions, 20126 Milan, Italy
3
Department of Electrical Engineering, Faculty of Science and Technology, NOVA University of Lisbon,
2829-516 Caparica, Portugal
Keywords: MDA, MDSEA, Enterprise Interoperability, Sensing Enterprise, Liquid Enterprise, Business Process.
Abstract: Information and communication technology (ICT) has facilitated the introduction of mass customisation
capabilities into the traditional Enterprise, especially in the domain of manufacturing. Currently individual
end-customers are allowed to design and order a product that is uniquely tailored to their preferences.
Servitization and product-based services have been gaining momentum to support the integration of
products and services with customers. This has enabled companies to maintain a competitive advantage in
contemporary markets. However, such capabilities demand more efficient processes, information systems to
enable resources optimization, maximized collaborations along the value chains, and interoperable
information flows. The FInES Research Roadmap 2025 identifies both Sensing Enterprise and Liquid
Enterprise as two Qualities of Being that are strategic for any future enterprise. In fact, the enterprise needs
to become self-aware not only in terms of their networked ecosystem but also in face of their inner sub-
systems and devices. This paper develops the concept of the liquid-sensing enterprise, exploring how
modelling and model-driven development can support the transition and services implementation.
1 INTRODUCTION
There are clear signs that Western countries, and
Europe in particular, cannot proceed practicing
‘business as usual’. It is required a change of
paradigm to maintain (and improve) the current
standard of life (FInES Research Roadmap Task
Force, 2012). In fact, the traditional view on
manufacturing industry has always been associated
with the physical transformation of materials and
assembly of components to produce products. As a
consequence, production processes, production
machinery and the software to control such systems
had been the focus so far. This represents an
immense opportunity for Future Internet (FI)
technologies (including IoT) to make an impact.
Nevertheless, in some cases, products are
already morphing into services and products
themselves are becoming platforms for services,
leading to the creation of highly personalized
markets to be exploited, which in turn demand
restructuring value chains and changing the
relationship with the customer. The companies
mastering this scenario will excel, while enterprises
anchored in traditional manufacturing values will
suffer with more virulence the competition of BRIC
countries (Baines et al., 2009).
Relying closely on the IoT, the new Web-based
service economy will merge the digital and physical
worlds opening up a multitude of niches and value
propositions. Hence, we are in the verge of a digital
transformation that needs to take place. Westerman
et al. (2011) claim that industries are using digital
advances such as analytics, social media and smart
mbedded devices to improve their use of traditional
technologies such as ERP, as well as to perfect
customer relationships, internal processes, and value
propositions. Indeed, enterprises are individually
starting digital transformation addressing key areas
of their enterprises, namely customer experience,
operational processes and business models.
The Sensing Enterprise and Liquid Enterprise
concepts envisioned in the FInES 2025 roadmap can
complete that digital transformation, delivering to
manufacturing industries across the various sectors
the required enablers to connect and use FI
technologies, customizing them to address customer
608
Agostinho C., Sesana M., Jardim-Gonçalves R. and Gusmeroli S..
Model-driven Service Engineering Towards the Manufacturing Liquid-sensing Enterprise.
DOI: 10.5220/0005406606080617
In Proceedings of the 3rd International Conference on Model-Driven Engineering and Software Development (MDE4SI-2015), pages 608-617
ISBN: 978-989-758-083-3
Copyright
c
2015 SCITEPRESS (Science and Technology Publications, Lda.)
experience, operational processes and business
models. New envisaged services are based upon the
convergence of networks, embedded computing,
control, content, and sensor feedback. Although
smart business systems can be described as an
evolution of the IoT, the evolution of traditional
enterprises into digital liquid or sensing enterprises
represents a fundamental change in the business
models that such enterprises will support and will be
able to implement.
In this context, a model driven approach can be
particularly valuable to support the formalization of
the liquid-sensing enterprise based on the fact it uses
enterprise models acknowledged by professionals
and standard institutions. An approach such as the
Model-driven Service Engineering Architecture
(MDSEA) is a perfect candidate to help in the
system re-engineering (Ducq et al., 2012). It can
support the enterprise processes modelling towards
the new sensing and liquid services design and
implementation. In section 2, this paper introduces
the liquid-sensing enterprise (LSE) concept in the
scope of OSMOSE research project (www.osmose-
project.eu). Then the authors analyse how the
MDSEA architecture can be applied to the LSE
(section 3), and section 4 presents the advancements
on LSE modelling. Finally an example is included in
section 5 and 6 concludes.
2 LIQUID-SENSING
ENTERPRISE (LSE)
An enterprise is a complex artefact. ISO 15704
defines it as a set of one or more organisations
sharing a specific mission, goals and objectives to
offer a product or a service (ISO TC184/SC5, 2000).
Its unique anatomy is composed of very different
passive tangible and intangible elements, and active
systems such as the Human or the artificial ICT
components. However, with the evolution of
business models and the growing of complexity, one
must face the idea that humans should (will) no
longer have a complete control over all the
operations acting on the produced artefacts, gaining
themselves a certain level of autonomy and
awareness. This is naturally true also for enterprises,
which need appropriate mechanisms to keep their
systems stable and optimized.
Following this vision, also shared by the 2025
roadmap for Future Internet Enterprise Systems
(FInES Research Roadmap Task Force, 2012),
today’s traditional engineering disciplines do not
appear adequate. Systematic methods, based on
advanced modelling techniques and model-driven
development, are required to correctly address the
activities carried out at the different phases of the
operational dimension. For instance, Business
Process Modelling and Management (Ko et al.,
2009) need to be complemented by the autonomic
capacity to react to unexpected events (e.g. through
Complex Event Processing (Michelson, 2006)).
In this context, both Sensing Enterprise and
Liquid Enterprise as two Qualities of Being that are
strategic for any future enterprise. The Liquid
Enterprise refers to the blurring of the enterprise
boundaries, where it is not easy to distinguish the
‘inside’ and the ‘outside’, the employees and the
partners, the competitors and the collaborators. It is
an enterprise having fuzzy boundaries, in terms of
human resources, markets, products and processes.
The Sensing Enterprise is a complementary
concept that emerges with the evolution of the
Internet of Things (IoT). It follows the need to
decentralise intelligence, moving to a scenario
where the enterprise is seen as a smart complex
entity capable of sensing and reacting to (business)
stimuli. The idea is to bring to organizations the
tremendous possibilities offered by the cyber worlds,
when objects, equipment’s, and technological
infrastructures will exhibit advanced networking and
processing capabilities, actively cooperating to form
a sort of 'nervous system' (Arthur, 2011).
Santucci et al. (2012) expect that the confluence
of both concepts enable the shift from the “walled
manufacture” to “liquid manufacture”, and
contribute to the vision of the Future Enterprise.
2.1 OSMOSE: IoT-enabled Metaphor
from Physics
The European Research Cluster on the Internet of
Things (IERC) recognizes that ICT development is
generating more and more things/objects embedded
with sensors, which are gaining the ability to
communicate with each other. This is renovating the
real physical world into an augmented information
and knowledge system. Hence, IoT is enabling
objects in our environment to become active
systems, sharing information with many
stakeholders, and gaining the skills for recognizing
events in their surroundings, to which they are acting
and reacting autonomously (IERC, 2011). Each IoT
object system has therefore a physical presence in
the Real World (RW), a model in the Digital World
(DW) specifying predefined pattern or behaviour,
and an image in the Virtual World (VW) to project
Model-drivenServiceEngineeringTowardstheManufacturingLiquid-sensingEnterprise
609
hypothetical what-if scenarios ruled by some laws
and policies (e.g. simulating the performance of a
production plant given some dynamic inputs).
In this context, the following metaphor can be
used to explain the OSMOSE concept, i.e. the
implementation of the liquid-sensing enterprise by
interconnecting Real, Digital and Virtual Worlds in
the same way as a semi-permeable membrane
permits the flow of liquid particles through itself:
Let us imagine the LSE as a pot internally
subdivided into three sectors by means of three
membranes delimiting the Real-Digital-Virtual
sectors. A blue liquid is poured into the bottom
sector (RW), a red liquid into the middle sector
(DW) and a green liquid into the top sector (VW). If
the membranes are semi-permeable, then following
the rules of osmosis the liquid particles could pass
and influence the neighbouring world, so that in
reality the blue RW also would have a red-green
shadow ambassador of the DW/VW, and similarly
for the other Worlds (Figure 1). An entity (person,
sensor network, an intelligent object) in the blue RW
should have control of their shadow images in the
red DW and in the green VW, keeping them
consistent and passing them just the needed
information under pre-defined but flexible privacy
and security policies (Spirito et al., 2014).
Figure 1: OSMOSE Metaphor.
2.2 Osmosis Processes
In the OSMOSE system, we assume that events
could be generated in any of the three worlds of a
LSE and that they should be propagated to the other
two worlds by interaction and negotiation of the
respective stakeholders. A chain reaction of events
could also be generated from a set of six processes
(osmosis processes):
• Virtualization - the Actor-Avatar process
which allows to provide data for simulation
of hypothetical RW situations;
• Augmentation – annotates RW objects with
VW data, allowing projections to be
superimposed to the RW and providing the
user with unprecedented experience of
mixing smart physical and virtual objects;
• Digitalization – supports modelling and
representation of RW data in a computer-
tractable form, providing the basis for
integration of Event Driven Architectures
(EDA) with service orientation;
• Actuation - the Agent-Actor osmosis process
that is able to plan and implement highly
distributed decision-making;
• Simulation – the Agent-Avatar process that is
able to run hypothetical scenarios fed by DW
models, knowledge and rules.
• Enrichment - extends the computational and
experiential capabilities of the DW with
annotations and projections coming from
simulations and hypothetical scenarios.
Figure 2: OSMOSE LSE Framework.
A triangular diagram (Figure 2) is used to
pictorially represent these processes. As explored
along this paper, the use of different IoT/ICT
technologies such as the EDA and MDSEA is
required for managing the osmosis processes.
Traditionally, representing and implementing the
interactions between the three worlds is achieved by
means of interoperable models and tools.
Nevertheless, there should be some automatic, real-
time but context-based mechanism for consistency
keeping and reconciliation of the shadow images.
Thus, regular interoperability techniques for
exchanging information should be substituted by a
integrated intelligent entities visible through the
gates of each World (as in the 1994 Stargate movie
teleportation device - imdb.com/title/tt0111282/).
Virtual
World
popula on
Digital
World
popula on
Real
World
popula on
Fuzzy
Boundaries
Sensing
Devices
OSMOSE
Virtual
World
popula on
Digital
World
popula on
Real
World
popula on
Digital World
Real Physical World Virtual Cyber World
Virtualization
Augmentation
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2.3 Event-Driven Architectures (EDA)
An event indicates a significant change in the state
of the universe (Chandy et al., 2007). Sensor data,
network signals, or application processing
information, are examples of simple events, while a
complex event is an aggregation of related events
(simple or complex). Papadopoulos et al. (2010)
describes the importance of complex event
representation and semantic enrichment for
managing and reviewing emergency incident logs. In
that example and others alike, extensive manual
effort is necessary to identify critical information,
such as person names and locations, in order to align
and merge the incoming log entries to make them
suitable for managerial decisions.
Generally, IoT applications are characterized by
producing a high volume of fine-grained data, which
is emitted by sensors. Therefore they must deal with
continuously arriving event streams. (Luckham,
2001) Due to the high volume of events and their
complex dependencies, no predefined workflow can
be specified, and as opposed to traditional DEBS
(Distributed Event- Based Systems) IoT creates a
highly dynamic application environment. Also,
current software architectures such as service-
oriented architectures (SOA) do not target event-
based systems, because they are based on a process-
oriented control flow, which is not appropriate for
event-driven systems. In recent years, EDA has been
proposed as a new architectural paradigm for event-
based applications (Michelson, 2006). The main idea
lies in the processing of events as the central
architectural concept, i.e. to use complex event
processing (CEP) as the process model for event-
driven decision support. Event streams generated by
sensors contain a large volume of different events,
which must be transformed, classified, aggregated
and evaluated to initiate appropriate actions.
The Esper (http://esper.codehaus.org) CEP
engine supports events in XML, Java -objects and
simple attribute value pairs. There are also many
CEP vendors such as Tibco, Coral8/Aleri,
StreamBase or Progress Apama providing tool suites
including a development environment and a CEP
engine. Most of the described systems use different
SQL-like or XML based complex event pattern
definitions, which makes it more difficult to
understand and read them. Neither of them provide
the knowledge support for event/process/service
model-driven integration, capable of satisfying the
integration of the entities in each of the three
OSMOSE worlds.
3 MODEL-DRIVEN SERVICE
ENGINEERING
Embracing the servitization integrated view on
product-service systems and extended products,
services concern physical products and objects as
well as the associated technology, people and
knowledge (Chesbrough & Spohrer, 2006). In fact,
to deploy an enterprise service, especially in
manufacturing, it will be necessary to involve
several partners and manage knowledge crossing
different boundaries of the enterprise (Zdravkovic et
al., 2013), much alike the LSE.
OMG’s model-driven architecture (MDA) and
model-driven interoperability (MDI) are amongst the
pioneer and most prominent technologies for model-
based enterprise development and integration (Chen
et al., 2008). MDI is more detailed and targeting
interoperability. Other approaches exist in the
domain of service (e.g. SOMF (Arsanjani, 2004))
but they are all still dedicated to ICT and not
manufacturing services. Therefore, to better define,
implement, and support the service life cycle, it is
necessary to separate the user point of view from
technical and from the physical means to realize it.
Figure 3: MDSEA (Ducq et al., 2014).
Therefore, the MDSEA architecture was first
presented by Ducq, Chen, et al. (2012) to model and
guide the transformation continuum from the
business requirements of the service system (BSM
level) into detailed specifications of components that
must be implemented to support the servitization
process (TSM level) was proposed. It follow the
MDA/MDI principles (Agostinho et al., 2014), and
as illustrated in
Figure 3
, combines that with the
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manufacturing servitization needs, supporting
modelling of three types of components (IT,
Organization/Human and Physical Means).
In order to operationalize service engineering
using MDSEA, it is necessary to follow a precise
method, which begins at the strategic level of
companies that want to evolve towards service-
oriented business methods. The approach implies
that the different models, obtained via model
transformation from the upper-level ones, should use
dedicated service modelling languages that represent
the system with the appropriate level of description.
GRAI Integrated Modelling and BPMN 2.0 (OMG,
2011) have been considered as a reference. The
MDSEA architecture provided the building blocks
for service system development in the scope of an
ecosystem of collaborating enterprises, providing:
The capability to transform a business specific
model into a functional one that can then be
perfected by a system architect detailing the
ICT, Human and Physical components;
The capability to transform a functional model
into a technology specific one envisaging the
generation of concrete services.
3.1 Discussion on Service System
Design at the LSE
Being a new paradigm for the enterprise, the LSE
also requires, as in servitization, modelling to
support the formalization of knowledge and
facilitate the interoperability with partners. Also, one
can consider that the design of services is inherent to
the manufacturing LSE. This will be addressed in
more detail in the next section, but both MDSEA
and LSE need to specify enterprise business
processes, identify resources, while relating those
with services. Hence, the LSE design could benefit
from the methodology behind MDSEA in order to
accelerate the transition of the traditional enterprise
to the “internet-friendly” and context-aware
organization envisaged in OSMOSE. The major
question resides on the fact whether the LSE concept
and MDSEA strategy are compatible.
The similarity with the strategy for the
separation of concerns behind the LSE real and
digital worlds is evident. For instance, there is the
clear notion that objects on the MDSEA’s “Physical
Means” domain need to have a shadow image on the
“IT” to enable the full design of the service system.
The “Organization and Human” domain is somehow
spread along both RW and DW with the person and
enterprise system belonging to the RW, but with
their associated knowledge and structure available at
the DW. The VW is not directly apparent in this
structure, but for example, methods for simulation of
business processes can be derived directly from
TIM’s IT models (Bazoun et al., 2014).
Hence, even though the initial objectives where
different, one can hypothesise that the MDSEA can
be applied to support the modelling of the
manufacturing liquid-sensing enterprise. The role
and complexity behind the enterprise ecosystem that
collaborates to co-create the manufacturing services
is taken by the 3 worlds in the OSMOSE framework,
which need to be integrated. MDSEA might need to
be extended to cover aspect such as events and event
processing, but it can support the generation of
liquid-sensing services implementing the 6 osmosis
processes for each enterprise instance. Thus, even if
not all LSE concepts are covered by the current
version of the MDSEA, it serves to accelerate and
guide the LSE modelling and implementation.
4 OSMOSIS PROCESSES FOR A
MODEL-DRIVEN LSE
As introduced in section 2.2, the osmosis processes
are a special type of process used to moderate the
information exchange among the real, digital, and
virtual worlds. We distinguish six osmosis processes
that, when instantiated will enable to seamlessly
integrate the LSE, connecting events across the 3
worlds, triggering services to provide the enterprise
full knowledge about its inner systems, and create
awareness concerning the interactions with the
business partners.
The OSMOSE LSE objectives and the
implementation of the semi-permeable membrane
require modelling at the various levels of the
enterprise (business, platform, implementation).
Indeed, constructs such as the ones of Resource,
Service, Event, or Enterprise Process need to be
specified at a certain point of the model-driven
continuum. Together, these constructs enable the
creation of a distributed knowledge architecture able
to manage the integration of the 3 worlds. Figure 4
depicts the relation among the modelling constructs
relevant to an Osmosis Process, in the scope of
business process modelling. The figure makes clear
that these special processes extend the enterprise
processes running in the different worlds, to
moderate the flow between them, crossing the
membrane. They can be associated to certain
Services (through Activity), which in turn can trigger
Events as well as act upon enterprise’s Resources.
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Resources are tangible elements of the
Organization. They can assume the form of machine
or Human systems when they exhibit certain
behaviour or functionality, but can also be products
or parts. However, all of them can have shadow
images in each of the OSMOSE worlds. A Human,
for example, is an Actor in the RW, and can have a
shadow Avatar in the VW, or Agent in the DW.
Services, Events, and Processes are different in the
sense that they can exist in any of the worlds but are
only associated to a single world instance.
Figure 4: Modelling Constructs: relation with business
process modelling.
The Service construct does not consider only
software services. As addressed along the paper, the
manufacturing enterprise can also specify certain
services such as product measurement service
provided by a certain machine, or a pilot training
service for the flight simulator etc. This way,
Resources may provide Services, which in turn, act
upon Resources. Finally, Events are closely related
with Services. Together they define a chain of
Event-Service action-reaction along the 3 Worlds
(Events executing Services and Services triggering
Events). An Event can be defined as a significant
change in state (modification event), a notification
of abnormal situation (alarm event), or any other
informative occurrence about a certain Resource.
4.1 Representation of Real, Digital and
Virtual Worlds
The Real, Digital and Virtual worlds are represented
as a set of enterprise processes and sub-processes,
with their internal tasks and events generated. Every
actor (system or person) is seen as a process and
every action is generating a set of events, which can
either refer to usual process oriented operations (e.g.
start, end or terminate) or be originated during
activities execution by actors of the world; for
example from IoT system, one can get the value of
the room temperature or the average of humidity
during the day; from a software it is possible to
extract usage of the memory or a software exception.
Figure 5 shows a simple abstract process that is
originating a set of events during the execution.
Figure 5: Real, Digital and Virtual Worlds representation.
4.2 Events Typology
We do not commit to a complete event description
(i.e. a specific event definition language) but rather
assume that the events that are passed between
processes provide meta-information, which allows
the process to retrieve all data that is relevant for
handling it. The meta-information defines an
envelope used to send post and receive events to and
from the CEP. The information in the envelope
allows the receiver to find all details needed for
dealing with the event. The following schema
provides technical representation details of a
possible envelope:
<domain> Automotive Manufacturing </domain>
<worldID> Real World </worldID>
<eventType> Critical Error </eventType>
<timeStamp> Time </timeStamp>
<eventResourceURI> URI </eventResourceURI>
<dataURI> URI </dataURI>
In order to uniform events coming from different
worlds, a taxonomy of events is adopted. The first
level of the taxonomy is derived from the events
available in the business process domain and defined
in BPMN2.0 (OMG, 2011). The taxonomy needs, of
course, to be extended in order to cover RW, DW
and VW requirements to recognize and manipulate
events. For example a signal is a non-interrupting
event in the process chain that can be extended in
order to monitor the temperature level in a certain
instant of time as temperatureSignal. Taxonomy is
also extended in order to cover membrane needs; for
example Danger Event extends Error Event.
Osmosis
Process
Event
Service
Enterprise
Process
has
calls
Resource
applies
provides
triggers
executes
hasSub
triggers
Organiza on
applies
hasSub
executes
Osmosis
World
moderatesFlowBetween
has
ac ons
Ac vity
has
has
provides
actsUpon
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4.3 Osmosis Meta-templates
Similarly to what has been provided for MDSEA,
also the main LSE constructs are firstly modelled at
meta-level following a template to gather data. Due
to space constraints, only the templates for Osmosis
Process and Service are presented (Table 1 and
Table 2). They extend the original MDSEA
templates available at Doumeingts et al. (2012).
Table 1: Osmosis Process Template.
Header
Identifier [Identifier of the process instance]
Name [Name of the process instance]
Type [Virtualization; Augmentation;
Actuation; Digitalization; Enrichment;
Simulation]
Body
Objective [Description of the process instance]
Causing Events [List of events that caused the
triggering of the osmosis process (e.g.
temperature higher than 100ºC)]
Related
Resources
[List of system and other resources
that are addressed by the process
pre/post-actions (e.g. simulator)]
Mode of
Operation
[Description of how far the process is
automated]
Functionality [Short textual description of the
activities composing the process]
Representation [Graphical representation of sub-
functions (e.g. BPMN)]
Table 2: Service Template.
Header
Identifier [Identifier of the service instance]
Name [Designation of the service instance]
Type [Software service; manufacturing
service; support service; etc.]
Body
Description [Short description of this instance]
Functionality [Short textual description]
Constraint [Short textual description]
Mode of
Operation
[How far the service is automated]
Access [Specify how, where and when is a
service made available]
Consumption [Specify what is expected where and
when by different parties participating
in service]
Business Value [Short textual description (if any)]
Performance
Indicators
[List of PI’s (if any)]
4.4 Modelling Osmosis Processes and
the LSE Membrane
After gathering meta-information for LSE
constructs, it is time to detail them using the selected
representation format. At the TIM level, BPMN 2.0
is a natural selection, but modelling should begin at
higher level (e.g. using Extended Actrigram * or
GRAI GRID) in the case new enterprise services are
to be deployed (natural case of MDSEA). In the
case it is only supporting the transition towards an
LSE (focus of the paper), then only the services
assisting the osmosis processes are new, and TIM is
an acceptable starting point. Nevertheless it is
important to note that the use of an enterprise or
software architect is recommended.
The membrane process is implemented as
illustrated in Figure 6; it acts as a listener component
that, at the time events are received, checks their
context and nature (type of the event as discussed
before) and decides whether an event is “osmiotic”
or not. If it is the case, then corresponding osmosis
process(es) is/are started. Otherwise, the system can
decide to do nothing or to start an intra-world
enterprise process needed to manage the event in the
scope of the world that originated it. In the osmiotic
case, a call to an intra-world process can happen
aside the osmosis process; for example to react to a
serious error in the real world the machine is stopped
launching a RW process (intra-world) and the
virtualization is started in parallel (inter-world).
4.5 Model-driven Generation of LSE
Services
Having all the models recreated at the TIM level
(Figure 6 extended with all details), one will already
have specified the enterprise behaviour in a platform
independent level. Hence, MDSEA enables the
generation, though top-down model transformations,
of the osmosis services necessary to have all the
information integrated and accessible through the
gates of the different worlds (with different views
targeted for different actors). Agostinho et al.
(2014), in his paper about MDSEA model
transformations, goes into more detail how the
information is generated with the detail necessary to
reach an actual software service.
5 VIRTUALIZATION CASE IN
MANUFACTURING
The overall reason to have VW is to allow users to
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Figure 6: Membrane Monitoring of OSMOSIS events.
investigate hypothetical situations. In many cases
these situations are investigated with the help of
simulations that use models, which are linked to RW
entities. The purpose of virtualization is, on the one
hand to create virtual artefacts that represent or at
least correspond to RW entities, and to provide the
data, which allows re-creating virtual situations that
are close to situations actually occurring in the real
world. Important concepts for virtualization are
therefore physical entities, measurement of physical
entities, and (3D) models derived from RW entities.
Depending on whether the model of the VW
already exists and does not need to be changed at the
level of modelling, the process might run completely
automated or completely manual, where manual
does not means that is not computer supported with
adequate modelling tools. In cases where no (or only
a partial) model is available and a new model needs
to be created, the process of virtualization needs to
be executed by human experts. For example, it is
possible to provide accurate 2D or 3D scans but
without further modelling effort only the pure data
can be visualized. Automated checks and processing
might be done on this data. However, checks and
processing needs to be predefined together, and with
this the process of virtualization.
With respect to virtualization, the LSE aims at
generic virtualization processes that can be flexibly
instantiated for different situations. In many cases
this might basically mean that the data the process is
acting upon is coming from different RW entities.
5.1 RW Events
Real world events monitored by the membrane are
correlated to (non–exhaustive list):
• HW execution system (danger, error, warning,
advancement info, config. settings debug);
• SW execution system (running, error, warning);
• Structural measurement (strengthens measured,
surface, 3D scan);
• Position (GPS positioning, logistic position);
• Environment (temperature, humidity,
brightness, policy)
• Availability (broken/available/updated).
Some of the events are the starting point for both
virtualisation and digitalisation processes while
others are correlated to just one of the osmosis
process.
5.2 Example
This section reports the Activities and Services that
need to be executed and/or generated to support the
virtualization process following certain events. “HW
Danger” and also “HW Warning” are exemplified.
For each process, the generic set of steps is detailed
in the following form. Services, events or processes
that need to be generated are indicated.
HW Exec DANGER Event Subsequent Steps:
1. Block the system (internal process)
2. Activate notification (alarm event) to the
environment (human and/or things)
3. Activate safety procedure (internal process)
4. Collect data about environment (GPS
positioning and tracing of objects people,
information about positioning of object,
settings of machineries) (service)
5. Save data (service)
6. Prepare session for the virtual recreation of
the situation (process)
7. Inform target system in VW (service).
HW Exec WARNING Event Subsequent
Steps:
1. Activate notification (alarm event) to the
environment (human and/or things)
2. Collect data about execution (service)
3. Save data (service)
4. Prepare session for the virtual recreation of
the situation (process)
5. Inform target system in VW (service).
Model-drivenServiceEngineeringTowardstheManufacturingLiquid-sensingEnterprise
615
The above sequences can be applied in multiple
situations. The first one could be illustrated with a
simple situation taken from a manufacturing shop
floor environment, i.e., “after an accident/incident,
a what-if simulation of the manufacturing
environment can be done in order to understand
how the situation has been generated; verify if it has
been well managed and better organize shop floor
workplace and machineries configuration for the
future”. We could illustrate the second with a
warning in a production line. For instance “an over
threshold temperature of some components can be
acceptable allowing the system to continue working
(so remaining a warning without becoming an error)
if the system is used with some constraints like, for
example keeping a lower speed during execution.
The constraints will be determined during what-if
simulations and fed back to the system by
augmentation process”.
6 CONCLUDING REMARKS
The paper analysed the needs behind industry’s
digital transformation and how it can be capitalized
by implementing the sensing and liquid enterprise
concepts proposed by the FInES 2025 roadmap. The
paper presented the status quo of the modelling and
design of the OSMOSE liquid-sensing enterprise
vision, as well as the realisation on the osmosis
process and connected events and services.
The general modelling approach towards LSE
osmosis processes realisation has been provided and
MDSEA has been proposed. Due to the proximity of
some of the inner construct behind manufacturing
servitization design and LSE design, the model
driven approach could be adapted to facilitate the
transition between the traditional enterprise and the
future LSE. The realisation of the activities, events
handling, monitoring, recognition of osmosis, and
the reaction by osmosis processes, is currently
modelled at the MDSEA TIM level. Model
transformations are applied to semi-automatically
derive technology specific models and accommodate
the specific needs of every enterprise and reach an
actual software service that supports the LSE
osmosis.
Implementing the OSMOSE digital
transformation will provide companies the digital
capabilities to capitalize on the FI and IoT,
improving customer experience, operational process,
business models. Next steps target the osmosis
processes deployment into real pilots and further
study on how to integration CEP middleware with
the generated services is needed. Also governance
models need to be studied for a proper realization of
the LSE at the BSM level. Based on the feedback
received, the final version of the modelling approach
will be produced.
ACKNOWLEDGEMENTS
Authors would like to acknowledge the European
funded Projects MSEE (FP7 284860) and OSMOSE
(FP7 610905) that supported the development of
various ideas, concepts and use case presented.
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