Towards Risk-aware Scheduling of Enterprise Architecture Roadmaps
Christophe Ponsard, Fabian Germeau and Gustavo Ospina
CETIC Research Centre, Charleroi, Belgium
Keywords: Enterprise Architecture, Risk Management, Meta-modelling, Optimisation.
Abstract:
Enterprises need to keep their organisation aligned with their business objectives. Enterprise Architecture
provides a way to identify the current and target states as well as defining the evolution roadmap taking the
form of a complex project portfolio. Conducting changes requires to deal with the occurrence of several risks
at the project level which can affect strategic decisions. This paper investigates how to optimally deal with
such risks in the global scheduling process. We start by identifying and structuring risks and projects concepts
based on a domain model. We then identify a set of risks and related management scenarios. Experiments
in risk control are carried out using two local search optimisation tools able to consider risk information
in addition with inter-project and resource dependencies. We show the feasibility of efficiently anticipating
risks and even dynamically adapting the scheduling. A dedicated focus is set on specific characteristics of IT
projects.
1 INTRODUCTION
Enterprise Architecture (EA) is discipline for proac-
tively and holistically leading enterprise responses
to disruptive forces by identifying and analysing the
execution of change toward desired business vision
and outcomes (Gartner, 2014). EA supports a set of
well-defined practices for conducting enterprise anal-
ysis, design, planning, and implementation, using a
comprehensive approach at all times, for the success-
ful development and execution of strategy (FEAPO,
2013). EA can also be viewed as a knowledge hub
integrating and sharing information on various struc-
tures across the enterprise and the business transfor-
mation value chain, as depicted in Figure 1.
Figure 1: Enterprise architecture as knowledge hub.
The execution of change is carried out through a
set of projects. Each project is a temporary endeav-
our undertaken to create a unique product, service, or
result (PMI, 2008). A key role of EA is thus to de-
fine and manage a global roadmap of related projects
to conduct the required change for keeping the enter-
prise aligned with its business objectives. Managing
such a project portfolio is not an easy task for many
reasons:
• the need to ensure the business continuity of the
enterprise while transforming it.
• usually complex dependencies between projects
reflecting the current state of its organisation and
IT infrastructure (including technical debt).
• priority constraints for reaching specific mile-
stones in due time.
• limited internal resource/budget to staff projects.
Projects can face many problems that can cause
failures, delays or budget overruns. Project Manage-
ment (PM) is especially recognised as severe in the IT
sector where about half of the projects are challenged
and 20% still fail (Standish Group, 2015). Project risk
management is a well-defined discipline with stan-
dards or frameworks like PRINCE2(Murray, 2009),
PMBOK(PMI, 2008) and ISO31000(ISO, 2009) are
available.
Managing risks at the portfolio level is more com-
plex. Enterprise Architecture provides a set of com-
plementary viewpoints: business view (strategy, gov-
ernance, organisation, and key business processes),
696
Ponsard, C., Germeau, F. and Ospina, G.
Towards Risk-aware Scheduling of Enterprise Architecture Roadmaps.
DOI: 10.5220/0007799806960702
In Proceedings of the 21st International Conference on Enterprise Information Systems (ICEIS 2019), pages 696-702
ISBN: 978-989-758-372-8
Copyright
c
2019 by SCITEPRESS – Science and Technology Publications, Lda. All rights reser ved
data view (logical and physical data assets), applica-
tion view (IT component and their interrelationships),
and technical view (hardware, software, and network
infrastructure). From those viewpoints, a risk ap-
proach can be carried out so that risks can be iden-
tified and addressed. Some risks can be directly man-
aged, e.g. to address the challenge of the digital trans-
formation more IT experts might be needed which
is done through the hiring/training process. Other
risks will be addressed by the specific project, which
means that the risks landscape is itself evolving across
projects, e.g. an obsolete component needs to be re-
placed but in the meanwhile other projects may need
to deal with performance or reliability issues of that
component.
Risk and risk-related activities like capability and
project management is part of the global EA vision
as depicted in Figure 1. Some EA frameworks also
provide direct support and guidance to capture risks
in specific EA viewpoints. The Open Group Archi-
tecture Framework (TOGAF) has a dedicated chapter
for risk management, including risk classification, ini-
tial/residual assessment, and monitoring (The Open
Group, 2009). ArchiMate does not support risk as
first class concept but provides language customisa-
tion mechanisms allowing one to capture specialised
concepts (The Open Group, 2017). A risk mapping
is given as informative example and more elaborated
mappings are also available (Jonkers, 2014).
Taking decision on how to best anticipate and
manage risks when they materialise is quite diffi-
cult in the context of enterprise architecture given the
complexity of the associated roadmap. Enterprises,
especially smaller ones, usually use only simple and
short-term strategies with reduced tool support. The
purpose of this paper is to explore a better method-
ological and tool support to cope with this problem.
This work goes beyond EA which is not about the
timing but only on the sequence to progress from an
as-is to a to-be situation. Hence, more information
is required about available resources and budget to
drive the planning. In order to maximise the chance
to reach the to-be state within resource constraints, the
planning need to take all relevant risks into account,
especially those inferred from the EA model and the
resources capabilities. Our paper takes the following
approach:
• capture relevant information for carrying out a
risk-aware roadmap execution, i.e. both risk and
project information. We propose a domain model
combining these dimensions. This provides the
reference scheme for reasoning and later integrat-
ing tool support.
• identify a series of risks potentially impacting
roadmap execution and defining some measures
to address them.
• perform experiments about practical tool support
that can be applied to deal with risks by adapting
scheduling tools.
Our research is still in an early phase. We focus
here on the meta-model and do not claim to be ex-
haustive about the studied risks scenarios. Our tech-
nological assessment is mainly oriented to technical
feasibility in order to manage risk-based constraints.
The paper structure reflects our approach. Section
2 reviews some existing meta-models for project and
risk management. Section 3 proposes a unified do-
main model over those aspects. Section 4 discusses
some risks scenarios while Section 5 shows some re-
sults using scheduling tools. Finally, Section 6 con-
cludes and presents our next steps.
2 OVERVIEW OF EXISTING
PROJECT META-MODELS
Different domain models or meta-models have been
defined in the literature, mainly from two sources:
Project Management and Enterprise Architecture
frameworks. They have slightly different scopes al-
though the global structure is quite similar: they con-
sider portfolio/program that gather projects and go in
the details of projects at different levels of granularity.
Figure 2: Partial projet meta-model from PMBOK.
As expected, PM frameworks focus more on the
project concept and provide details in terms of op-
erational concepts like task/activities, resources in-
volved and products/deliverables. As example, Figure
2 shows the meta-model proposed by PMBOK (PMI,
2008). Other meta-models quite similar in nature
have been proposed by other frameworks like RUP
and OPEN. An attempt to define a common global
meta-model is described in (Martins and da Silva,
2005). However, they tend to become unnecessarily
complex and are mainly useful for interoperability.
Towards Risk-aware Scheduling of Enterprise Architecture Roadmaps
697
Another characteristic of those meta-models is that
they do not make explicit reference to risks although
they capture risk factors.
Figure 3: Project concepts of the ArchiMate meta-model.
EA frameworks target a broader perspective mak-
ing links with goals, business services, infrastructure
and have a more abstract notion of project. As shown
in Figure 3, ArchiMate use the notion of “Imple-
mentation Events” to describe the transition between
successive states named “Plateau” (The Open Group,
2017). However, some frameworks like Alfabet (Soft-
wareAG, 2015) do have an explicit concept of project.
All EA frameworks include some form of risk man-
agement. Surprisingly, the risk concept itself is sel-
dom explicitly present in the framework meta-model.
The ArchiMate 3.0 specification states risks as an im-
portant EA aspect but does not cover them. TOGAF
requires a specific meta-model extension to deal with
risks(The Open Group, 2009).
3 PROPOSED UNIFIED DOMAIN
MODEL
The previous section has highlighted the need to be
able to characterise projects in relation with risks in
order to cover classical risks (typically by addressing
the quality/cost/delay equation) but also to be able to
cope with the introduction of domain specific risks.
In order to provide a strong rationale when build-
ing our meta-model and making also sure it would
enable to express risks in a quantitative way, we
applied the obstacle refinement technique borrowed
from Goal Oriented Requirements Engineering(van
Lamsweerde, 2009). The starting point is a set of key
project goals which are challenged by risks (modelled
as obstacles) that are refined down to the point to be
measurable on model elements. At this point, miti-
gation strategies can also be deployed, but our focus
here is more on identifying key model elements that
needs to be captured. We shortly highlight the pro-
cess in structured text on the delay goal, i.e. the risk
of project overrun:
,→ project deadline unrealisable → pro ject.deadline
(attribute in meta-model)
,→ reduced margins between tasks
,→ some tasks could to be late
,→ unreliable estimate of task duration
→ task. plannedDuration
,→ required resource unavailable
→ resource.availability
,→ task plannedResource vs actualResource
,→ possible unavailability rate of resource
,→ etc.
The resulting meta-model is shown in Figure 4.
Projects are structured steps at different abstraction
levels: portfolio, phase and tasks. Those can be used
at the required level of granularity. Each step has a
planned time interval for its completion and will even-
tually be completed in an actual time interval. Each
step targets the production of some deliverable that
is the concrete achievement of some operational goal
which is aligned with strategic goals of the organisa-
tion. It also requires a set of resources of some type
(e.g. monetary, time of material type) to guarantee its
completion at some cost of which an actual set will be
devoted. Risks can affect steps at various levels and
obstruct the related goal. They are characterised by
both their likelihood and impact. Impacts categories
are defined and can be populated with generic risk
types (resource unavailability) and more domain spe-
cific ones like production machine breakdown. Risks
Figure 4: Resulting meta-model.
ICEIS 2019 - 21st International Conference on Enterprise Information Systems
698
can be refined into sub-risks and specific mitigation
actions can address them in order to restore the re-
lated goal. Like risks, different categories of mitiga-
tion actions can be foreseen and evolved based both
on generic or domain specific strategies. In the pro-
cess, costs can be considered, including for deploying
some risk mitigation to guide its selection.
4 IDENTIFICATION OF RISK
SCENARIOS AND RELATED
MEASURES
This section reviews a few risks that can arise in the
execution of a complex project portfolio and identifies
some measures that can be used to address them. We
especially identify measures that can be automatically
explored by a scheduling process. As usual, the two
risk factors requiring to be analysed are likelihood and
impact.
4.1 Inherent Risk of an Specific Task
A task considered alone independently of its links
with other tasks or the required resources can be more
or be less risky given its nature and the enterprise con-
text. Information provided by different viewpoints
can directly help in estimating the risks, mainly at the
impact level: are they bound to a strategic goal of the
company? Do they impact many processes, applica-
tions or technologies? Are there alternative paths to
reach the same result?
Reducing risks can be done in designing the
roadmap itself to provide some backup solution or al-
ternatives. A typical classification of risks will ad-
dress the following dimensions:
• scope risks: new requirements, strategic change.
• scheduling risks: related to estimation, inter-
nal/external dependencies.
• resource risks: capability and availability.
• technology risks: related to hardware and soft-
ware availability, reliability, security issues.
• environment risks, e.g. regulation, government,
market, suppliers’ issues.
• management risks: related to organisation com-
plexity, available skills, bureaucracy.
Scheduling and resource risks directly affect the
planning and will be detailed in the rest of the sec-
tion. Other risks need to be managed at the organisa-
tion level. The residual risks should be considered in
terms of possible delays or failures w.r.t. other tasks,
depending on the correct achievement of this task.
4.2 Portfolio Structure Risks
A few risks can be inferred from the project portfo-
lio structure. Our meta-model can capture those de-
pendencies at different levels. At least project level
dependencies need to be analysed and of course the
related critical path to meet the target deadline should
be identified. Specific constraints on project start time
might also be imposed due to external constraints (de-
pendency on external project/resource/technology) or
financial issues (e.g. yearly budget approval).
Dependency impact of a task can be quantified
based on indicators related to its presence on the criti-
cal path and on the number of downstream dependen-
cies. A riskier task should be scheduled in priority
to enable better recovery in case of delay. However,
the global duration of each project and effort splitting
across project should also be kept under control.
4.3 Resource Related Risks
A resource level characteristics (not all reflected in
Figure 4) is the level of reliability of the resource and
characterise the risk likelihood. For a process/ma-
chine, it is the mean time between failures (MTBF).
For people, it can be related to the level of expertise
w.r.t the task or some evaluation of their competency.
The global capacity should also be taken into account,
e.g. if a risky task needs to be reinforced, some re-
sources should be available or another less important
project should accept to be delayed. It is also possi-
ble to explore different alternatives to reach the same
result by different combinations of task durations and
intensity of allocations. However, the functional de-
pendency can be complex, as discussed in the next
point.
4.4 Domain Specific Risks (IT projects)
In many fields of project management and especially
in the IT domain, it is well-known that adding man-
power to a task will not result in a proportional
speedup and is even totally ineffective at some point
in the project, i.e. “adding human resources to a late
software project makes it later” (Brooks, 1978). This
means that adding more resource in this case is not an
option. Such known impact needs to be modelled ad-
equately to rule out the generation of such schedules.
For a risky project, it is better to have secured the right
level of resource and to have some safety margins.
Towards Risk-aware Scheduling of Enterprise Architecture Roadmaps
699
5 RISK SCHEDULING
EXPERIMENTS
5.1 Tooling Used
In order to carry out risk scheduling experiments, two
Open Source tools where investigated. Both are based
on local search techniques which is the recommended
approach to deal with complex scheduling problems,
although it does not provide guarantee to find an op-
timal solution. These tools are:
• OptaPlanner, a lightweight, embeddable, planning
engine written in Java (Smet, 2006). It solves
constraint satisfaction problems with construction
heuristics and meta-heuristic algorithms. It pro-
vides support for scheduling with resources and
modes which can be enhanced to deal with risks.
• OscaR is Scala toolkit for solving Operations Re-
search problems with two main engines: Con-
straint Programming (CP) and Constraint-Based
Local Search (CBLS) (OscaR, 2012). The sec-
ond engine can efficiently solve complex schedul-
ing problems through incremental evaluation
of neighbourhood search(Van Hentenryck and
Michel, 2005). OscaR also provides a high level
description language for models and search proce-
dures but has limited built-in support for schedul-
ing.
The tooling was used in development mode and
was also integrated inside Redmine, a complete web-
based Open Source PM environment (Lang, 2006)
which supports bug/task management and contains a
basic Gantt viewer. It also provides a REST API for
easing scheduler integration.
5.2 Scenario#1 - Independent Tasks
with Increasing Risk Level
This simple scenario just considers a simple portfo-
lio of 5 tasks without any dependency but relying on
a single resource. It applies a penalty that is propor-
tional to the risk level and start date of the tasks. This
can be stated in OscaR.CBLS using the following ob-
jective function:
val a ctR i s k = Array . tabul a t e ( size )
( i = > { pb . s ta r t T im e s ( i ) * penal t y *i })
val globa l R is k : O b j ec t i v e = Sum ( a c t R isk )
Figure 5 shows the results where the tasks are exe-
cuted in reverse order so that riskier tasks are executed
sooner.
Figure 5: Scenario of independent tasks with increasing
risk.
5.3 Scenario#2 - Starting Risky Tasks
Earlier
In the three next scenarios, we will consider a port-
folio composed of 5 instances of a similar project
structure depicted in Figure 6. Task#1 is a blocker
for 3 subsequent tasks. At resource level, task#1 and
task#2 both need resource R#1 while task#2, task#3
and task#4 require resource R#2. Globally, only one
instance of R#1 and three instances of R#2 are avail-
able to make the problem a bit constrained. This ex-
ample contains enough complexity while still easy to
depict and to explain using readable Gantt diagrams.
Figure 6: Simple project structure.
Figure 7 shows the result achieved by OptaPlanner
with an objective function rewarding for early start of
critical task#1 in all projects. The best possible re-
sult could be achieved with all projects intertwining
to start this task. At the performance level, only basic
search operators (insert/retract/swap) were used and
reaching this optimal solution required about 30 sec-
onds search time in verbose mode. It could probably
be improved with a smarter way to select neighbour-
hood candidates.
Figure 7: Scheduling to cope with risky tasks early.
ICEIS 2019 - 21st International Conference on Enterprise Information Systems
700
5.4 Scenario#3 - Limit Scattering
While controlling the risk of critical tasks, the previ-
ous roadmap schedule has the drawback of running
many projects in parallel. This results in a longer
project duration, which is a known risk because of
resource switching overhead and also having projects
on hold for quite a while, e.g. project #3 in Figure 7.
A strategy to cope with this is to minimise
project duration by using a score that rewards shorter
projects. It can be expressed as follows using Op-
taPlanner (in a inefficient non-incremental evaluation
mode). Note that the notion of soft score is for
minimisation, while resource allocation is strictly en-
forced through hard constraints.
so f t 0 Sc o r e =0;
for( Projec t p : pr o j E n d Da t e M a p . k e y Set ()){
int ed = pr o j En d Da t e M a p . get ( p );
int sd = pr o j S t a r t D a t e Ma p . get ( p );
so f t 0 Sc o r e += ( sd - ed );
}
Figure 8 shows the result easily found by Opta-
Planner. The global duration is the same as in the pre-
vious scenario. Of course, achieving compact sched-
ules means starting some projects later and is thus not
compatible with the previous scenario: in this case,
the latest project is started after 90 time units rather
than 40 before.
Figure 8: Scheduling to minimise project duration risks.
5.5 Scenario#4 - Redmine Integration
In this scenario, we connected the OscaR-based
scheduler with a Redmine application (Lang, 2006).
The REST API was used to retrieve the whole project
and risk information matching our risk meta-model
described in Section 3. For risk support, a dedicated
plugin was used. The results are shown in a schedul-
ing page featuring two Gantt diagrams, respectively
before and after optimisation as depicted in Figure 9.
A view of resource load over time is also available
from a separate tab. The platform is available online
in read only mode without registration need at this
URL: http://prima-q.cetic.be.
Figure 9 shows the Gantt of a two-year project in-
volving mainly six people (actually the project sup-
porting this research). The optimisation reveals that
some tasks could have been started earlier and that
progress could have been achieved with more tasks in
parallel. However, this does not totally reflect all task
constraints and resource availabilities. This means
that the result of the optimisation should be analysed
carefully to make sure it relies on accurate data and to
include some margins for the unforeseen.
6 CONCLUSION AND NEXT
STEPS
In this paper, we have presented our approach to cap-
ture and model risks within the scope of an enter-
prise architecture roadmap and with the goal to per-
form risk-aware scheduling. We proposed a reference
meta-model inspired from both the project and risk
literature. Looking at different risks arising in enter-
prise operation, we identified a few of them directly
impacting the scheduling, as well as measures to ad-
dress them. Finally, we had some practical experi-
ments with mature open source optimisation tools.
Our results so far are encouraging as we were
successful in deploying our risk management strate-
gies. Although our experiments are still of reduced
size, the tooling showed the ability to scale, especially
the OscaR tool which was also integrated with a pre-
operational Redmine environment. In this respect, the
developed meta-model proved useful to develop the
required integration layer. We believe it can help oth-
ers to map all relevant concepts into their own frame-
work and tooling.
Going beyond this feasibility step, the next steps
of our research are to investigate:
• more elaborated classifications of risks impacting
the scheduling of the roadmap.
• the use of alternatives in project roadmaps and dif-
ferent possible implementations of tasks (e.g. du-
ration vs intensity).
• more thoroughly the literature, especially related
to Project Portfolio Management, System of Sys-
tems (Gillespie et al., 2017) and considering spe-
cific SME needs (Marcelino-S
´
adaba et al., 2014).
• how to make our tooling adequate for use by
SMEs for the kind of EA projects they have to
manage, in the line with our earlier work in this
Towards Risk-aware Scheduling of Enterprise Architecture Roadmaps
701
Figure 9: Redmine integration of the risk-aware scheduling.
area (Ponsard and Majchrowski, 2015).
ACKNOWLEDGEMENTS
This work was partly funded by the PRIMa-Q COR-
NET research project (nr.1610088) from the Walloon
Region of Belgium and the German Federation of In-
dustrial Research Associations (AiF). We thank our
User Committee, especially Respect-IT and LabNaf.
REFERENCES
Brooks, Jr., F. P. (1978). The Mythical Man-Month: Essays
on Softw. Addison-Wesley Longman Publishing Co.,
Inc., Boston, MA, USA, 1st edition.
FEAPO (2013). Common Perspectives on Enterprise Archi-
tecture. Federation of EA Professional Organizations,
Architecture and Governance Magazine. Issue 9.
Gartner (2014). Gartner it glossary - enterprise architecture.
https://www.gartner.com/it-glossary.
Gillespie, S. E. et al. (2017). System of systems architecture
feasibility analysis to support tradespace exploration.
In 12th System of Systems Engineering Conference,
SoSE 2017, Waikoloa, HI, USA, June 18-21.
ISO (2009). Risk management – principles and guidelines.
ISO 31000.
Jonkers, H. (2014). Enterprise architecture-based risk
assessment with archimate. https://bizzdesign.com/
blog.
Lang, J.-P. (2006). Redmine. http://www.redmine.org.
Marcelino-S
´
adaba, S. et al. (2014). Project risk manage-
ment methodology for small firms. Int. Journal of
Project Management, 32(2):327 – 340.
Martins, P. V. and da Silva, A. R. (2005). PIT-P2M: Projec-
tIT Process and Project Metamodel. In Proc. of OTM
Confederated Int. Conf. on the Move to Meaningful
Internet Systems. Springer-Verlag.
Murray, A. (2009). Managing successful projects with
PRINCE2. TSO, Norwich.
OscaR (2012). OscaR: Scala in OR. https://bitbucket.org/
oscarlib/oscar.
PMI (2008). A Guide to the Project Management Body
of Knowledge (PMBOK Guide), 4th Edition. Project
Management Institute.
Ponsard, C. and Majchrowski, A. (2015). Driving the adop-
tion of enterprise architecture inside small companies
- lessons learnt from a long term case study. In Proc.
of Int. Conf. on Enterprise Information Systems.
Smet, G. D. (2006). OptaPlanner Open Source Constraint
Solver. http://www.optaplanner.org.
SoftwareAG (2015). Alfabet, Enterprise Architecture Man-
agement. www2.softwareag.com/corporate/products/
aris alfabet/eam.
Standish Group (2015). CHAOS Report. http://www.
standishgroup.com.
The Open Group (2009). TOGAF - The Open Group Ar-
chitecture Framework V9.
The Open Group (2017). Archimate 3.0.1. http://pubs.
opengroup.org/architecture/archimate3-doc.
Van Hentenryck, P. and Michel, L. (2005). Constraint-
Based Local Search. The MIT Press.
van Lamsweerde, A. (2009). Requirements Engineering -
From System Goals to UML Models to Software Spec-
ifications. Wiley.
ICEIS 2019 - 21st International Conference on Enterprise Information Systems
702
