Enhanced Information Management in Inter-organisational Planning
for Critical Infrastructure Protection: Case and Framework
Christine Große
a
Department of Information Systems and Technology, Mid Sweden University, Holmgatan 10, Sundsvall, Sweden
Keywords: Information Management, Information Assessment, Analytical Framework, Inter-organisational Information
Sharing, Critical Infrastructure Protection, Multi-level Planning, Emergency Response Planning, S
TYREL
.
Abstract: This paper develops an analytical framework to assess information in planning for critical infrastructure
protection (CIP). Critical infrastructure concerns various societal functions that ensure the daily life,
endurance and progress of societies. Thus, CIP involves a considerable number of actors in a multi-level
planning that relies on inter-organisational information sharing. Based on a Swedish case of CIP, this study
aims to foster information assessment and management that bridge the inherent conflicts between information
sharing and information security in CIP. Analyses of the information alongside the Swedish S
TYREL
process
first exemplify crucial deficiencies in the inter-organisational, national emergency response planning and then
specify a set of dimensions and attributes as baseline for assessing information and information processing in
CIP. Four stages in the Swedish approach cause a filtering and altering of information that affect the quality
of decisions alongside the process and the emergency response plan that relies on them. By assessing the
information basis in this large-scale approach, the paper contributes evidence-based foundations for
information management in inter-organisational settings, such as the multi-level planning for CIP.
1 INTRODUCTION
Information is an essential prerequisite for planning
and decision-making. Alongside multi-level planning
processes for protecting vital societal functions and
the dependent society, the management of
information must maintain an adequate level of
information security during acquisition, storage,
processing, sharing, utilisation and archiving
(European Union, 2008; 2016a). The protection and
maintainance of infrastructure that is critical to
society’s functionality, survival and progression
(Cohen, 2010) involves sensitive information and a
considerable number of public and private actors in a
multi-level socio-technical system-of-systems
(Gheorghe et al., 2006). Critical infrastructure
protection (CIP) can thus be viewed as a common,
societal concern that is located between governmental
control and competitive market dynamics as well as
the private sphere of citizens (Große, 2020), which
includes inter-organisational collaboration and
information management. During the course of inter-
organisational planning for CIP, the quality of the
a
https://orcid.org/0000-0003-4869-5094
processed information is constantly influenced by
various requirements, such as the needs of involved
decision-makers, the demands of national and
international information security policies and the
expectations of the diverse actors who are concerned
with CIP and crisis management. Since CIP involves
secret information about sensitive systems and
protection measurements that a nation or business
applies, the presence of concrete proceedings in the
literature is very limited, such as a discussion of
Canada’s CIP (Quigley, 2013) and the Swedish
approach (Große and Olausson, 2019). Therefore, this
study aims to fill this gap and foster information
management that bridge inherent conflicts between
information sharing and information security in CIP.
Subsequent to the background and method
sections, Section 4 presents the Swedish case of
S
TYREL
and exemplifies crucial deficiencies in this
inter-organisational emergency response planning.
By analysing the information and information sharing
in the currently applied approach, Section 5 provides
an analytical framework to assess information in
planning for CIP. A conclusion completes the study.
Große, C.
Enhanced Information Management in Inter-organisational Planning for Critical Infrastructure Protection: Case and Framework.
DOI: 10.5220/0010186803190330
In Proceedings of the 7th International Conference on Information Systems Security and Privacy (ICISSP 2021), pages 319-330
ISBN: 978-989-758-491-6
Copyright
c
2021 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
319
2 BACKGROUND
2.1 Critical Infrastructure Protection
Modern societies increasingly depend on a variety of
resources, societal functions and fixed installations,
(inter-)organisational structures and agreements as
well as legal regulations. Critical infrastructure (CI)
concerns a subset of this socio-technical system-of-
system, namely, those elements that are critical to
society’s functionality, survival and progression
(Cohen, 2010). Thereby, the energy sector and the
power supply in particular appears central to this
complex system (Rinaldi et al., 2001). Thus, the
protection of such infrastructure has gained
significance for national security in many countries
and for research in this area (e.g. Birkmann et al.,
2016; BMI 2009; European Commission, 2004;
Große, 2020; MSB 2011), whereas information
security is a recurring concern. To protect CI and
maintain it during disturbances, such as electrical
power failures, national emergency response
planning relies on comprehensive information
processing. However, the sensitivity of information
about CI and the protection measurements that are
applied challenges inter-organisational co-operation
as well as empirical research in this area (Große et al.,
2019). Studies have more often focussed on the
operational level of infrastructure, such as the
reliability of power transmission (Alvehag and Söder,
2011; Münzberg et al., 2014) and power system
restoration (Barsali et al., 2008; Soman et al., 2015;
Tortos and Terzija, 2012). By applying a purely
technical perspective, such studies ignore not only
any societal effects of CI failures but also the
interdependencies with public risk and crisis
management. However, CIP concerns also the
preclusion of unauthorised access to (remote) control
systems and the prevention of unauthorised
disclosure, altering or loss of sensitive information
that is processed and shared.
2.2 Information Management –
Quality, Security and Preservation
Information is an essential prerequisite for planning
and decision-making. To fulfil its dedicated function
of assisting a decision-maker with a decision,
information must meet criteria regarding its quality
and security. In the context of CIP, such demands can
affect each other, which may lead to a paradox that
affects the result of a planning process. Information
quality is a significant property that is difficult to
define and largely depends on the processing of
information through an information system (Michnik
and Lo, 2009). In a study with data consumers, Wang
and Strong (1996) have captured 118 data quality
attributes, which they fused into 20 dimensions and
grouped into four higher-level categories. Even
though the spectrum of quality attributes remains
considerable (Arazy et al., 2017), studies on
information quality have successfully reduced the
number of categories and identified accuracy,
consistency, security, timeliness and completeness as
the most common characteristics (cf. Knight and
Burn, 2005). For the present study, the information
quality dimension adapts the common attributes of
intrinsic, contextual and representational information
quality, with a particular focus on accuracy,
objectivity, timeliness, completeness, format and
comprehensibility of information (see Table 1).
In view of the particular significance of
information security in the CIP context, attributes that
relate to security fit into the information security
dimension. Apart from quality attributes, such as
accessibility and reputation of the source (Wang
& Strong, 1996), the information security dimension
in this study includes concerns about the processing
of information by a system. Common properties of
information security are the availability, integrity and
confidentiality of information as well as the privacy
of individuals (Andress, 2014, 6–8; 95–99;
Independent Data Protection Authorities of the Bund
and the Länder, 2016; 2018). Such properties are
maintained, to a certain extent, during the processing
of information by an information system, whose
organisation consists of technical components, formal
rules and informal structures with certain information
paths. This system influences the quality and security
of the processed information (Große, 2016; Michnik
& Lo, 2009). In accordance with national and
international requirements for national and European
CIP (European Union, 2008; 2016a), an adequate
level of information security must be maintained
during information processing alongside a multi-level
planning process for protecting CI and the dependent
society (Große, 2018a).
A multi-level planning for CIP, such as the S
TYREL
approach in Sweden, depends on not only an adequate
level of information quality and security but also the
preservation of information. The present study
separates this dimension from the former two to
emphasise the importance of information
preservation for decision-making at subsequent levels
of the planning process. Thus, it mainly focuses on
the preservation of information, which may exceed
archival and technocratic approaches (cf. Quisbert et
al., 2009). Of particular relevance to operationalise
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320
the information preservation dimension are the
attributes of meaning, as recorded and transferred
through the entire process, and evidence of parallel
actions (ibid.). These attributes are noteworthy for
two reasons. First, they inform evidence-based and
rational decision-making through a multi-level and
multi-agency planning process (Bharosa et al., 2010).
Second, they support sufficient quality and
information security management, which is
obligatory for national agencies in Sweden (MSB,
2016) to enhance CIP, particularly in the energy and
transport sectors (European Union, 2008). Table 1
summarises the conceptual framework that this study
applies and briefly explains each attribute.
Table 1: Attributes of Information Quality, Security and
Preservation (adapted from: Knight & Burn, 2005; Wang
& Strong, 1996).
Dimension Attribute
Extent to which the
in
f
ormation is …
Information
Quality
Accuracy
correct, flawless and
certified to be free of
error.
Objectivity
unbiased, unprejudiced
and im
p
artial.
Timeliness /
Currenc
y
sufficiently up to date
for the task at hand.
Completeness
of sufficient breadth,
de
p
th and sco
p
e.
Format
well organised, concise
and consistently
represented.
Comprehensibility
easily understood, inter-
p
retable and readable.
Information
Security
Availability /
Access
accessible for
authorised persons at
the proper time, in the
right place and with the
correct degree of access
p
ermission.
Integrity /
Reputation
highly regarded in terms
of source or content,
verifiable, well
documented and free of
unauthorised alteration.
Confidentiality
protected from
disclosure by
unauthorised persons.
Privacy
limited to a purpose and
controllable during a
p
rocess.
Information
Preservation
Meaning
beneficial, undivided
and completely
transferred.
Evidence
well documented and
completely recorded
and transferred.
3 METHODICAL PROCEEDINGS
This study relies on data and evidence collected from
several sources, such as publicly available documents
regarding the case, interviews and a survey.
First, the document study examined Swedish
documentation of the case; this included handbooks
(EA, 2014), guidelines, legal regulations and various
reports, (e.g. CAB Blekinge, 2009; CAB Dalarna,
2009; CAB Stockholm 2012; EA, 2012; Veibäck et
al., 2013). This examination provided a further basis
for the interviews.
Second, interviews were conducted with 66
decision-makers who act on behalf of several actors
in this multi-level CIP planning. Table 2 details the
participant sample.
Table 2: Participation in the Study.
Number of
Interviewees
Affiliation
4 Count
Administrative Board
CAB
47 Munici
p
alit
y
15 Power Grid Operator (PGO)
The maority of informants participated in face-to-
face interviews within their particular working places.
The interviews were semi-structured in nature and
consisted of predetermined, open-ended questions,
which allowed for a similar structure in each
interview while still enabling participants to address
any particularly relevant issue with regard to inter-
organisational information sharing during the S
TYREL
planning. The interviews lasted for an average of one
hour, were recorded and transcribed.
Third, to broaden the view of particular issues, the
completing survey encompassed all 21 counties in the
first step and, in the second step, considered the 10
PGOs that stabilise the power grid during the initial
phase of a power shortage. The survey posed 34
questions about the respondents’ perceptions of the
proceedings of S
TYREL in general and the inter-
organisational co-operation and information
processing in particular. This proceeding enriched the
evidence from the document and interview studies
and facilitated a differentiated understanding of the
information management in the Swedish process.
The following section describes and analyses the
information acquisition, processing and sharing in
S
TYREL in detail. Four stages in the planning for CIP
cause a filtering and altering of information that affect
both the decisions in the process and the resulting
emergency response plan. These stages exemplify
crucial deficiencies in the inter-organisational,
national emergency response planning approach.
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321
4 THE SWEDISH STYREL CASE
4.1 Inter-organisational CIP Planning
In 1995, a governmental investigation had already
identified the power supply as a critical sector for
national security and development in Sweden and
discovered a change in threats as well as an increased
vulnerability of CI (SOU 1995:19). However, the
compilation of a ranking of power consumers to
prioritise during such events was not encouraged until
after the 2003 blackout in Sweden and Denmark,
which may have been the catalyst for the
development of the national S
TYREL planning
approach (Elkraft System, 2003; Larsson and Danell,
2006; Larsson and Ek, 2004; Svenska Kraftnät,
2003). Since 2004, the Swedish Energy Agency (EA)
has been responsible for the development of S
TYREL,
which is an acronym for ‘steering electricity to
prioritised power consumers’ (EA 2014).
The S
TYREL approach was developed between
2004 and 2011 and executed as a pilot in 2009 and in
full-scale in 2010/2011 and 2014/2015 (EA 2014).
The third iteration was scheduled to run between
2019 and 2021; however, it is adjourned for one year
due to the global SARS-CoV-2 pandemic (EA 2020).
The planning involves many actors from the
public and private spheres, including a large number
of national agencies and all CABs, municipalities and
PGOs (Große, 2017; 2018b). The first two rounds of
planning were executed over a period of more than
one year and applied a four-year interval. The next
planning process will run over a period of three years.
Table 3 presents an eight-point scale that the actors in
S
TYREL apply as the decision-making aid to identify
and prioritise CI in their part of the process.
Table 3: Classification Scheme of CI (MSB, 2010:10).
Class Score
Description of electricity consumers
that have/re
p
resent…
1 7
significant impact on life and health—
short-term
(
hours
)
2 6
significant impact on society's
functionality
short-term (hours)
3 5
significant impact on life and health—
lon
g
-term
(
da
y
s
)
4 4
significant impact on society's
functionalit
y
lon
g
-ter
m
(
da
y
s
)
5 3 si
g
nificant economic value
6 2
significant importance for the
environment
7 1
significant importance for social and
cultural values
8 0 Others
As the governmentally entrusted actor, the EA
starts the multi-level planning process. Subsequently,
the procedure and inter-organisational information
sharing are suggested as follows (EA 2014):
1. National agencies, which also include CABs to a
certain extent, identify and prioritise the CI that
each of them operates by applying an eight-digit
scale to classify CI (see Table 3).
A. Each agency sends one portion of ranked objects
to each CAB (up to 21 in total) whose regional
area of responsibility the CI object belongs.
2. Each CAB merges the received lists of prioritised
CI and divides them into portions that correspond
to each municipality’s area of responsibility.
B. Each CAB forwards these lists to each
municipality in their region.
3. Each municipality generates an inventory of local
CI and prioritises the objects in accordance with
the list in Table 3, which also involves the objects
that it receives from the CAB.
C. Each municipality sends a request for further
information about the prioritised CI to each
locally operating PGO.
4. Each PGO matches the CI objects to power grid
areas and power lines within the geographical
area in which each PGO operates the local grid.
D. Each PGO provides information about technical
feasibility of control to each municipality that has
sent a request.
5. Each municipality consequently merges the CI
objects into controllable power lines. The
spreadsheet in use performs an additive
aggregation of the objects’ ranking scores, which
yields a ranking list of the power lines. Each
municipality is encouraged to assess this list to
ensure that the order of power lines reflects the
desired position of the particular municipality.
E. Each municipality sends the latter list back to the
CAB of its region.
6. Each CAB then combines these lists from the
municipalities in its jurisdiction, resolves
conflicts between lines that cross municipal or
regional borders and finally determines the
ranking of power lines.
F. Each CAB sends the final document, which
contains the ranking of the local power lines in
the region, to the national PGO and dedicates
portions of it to each provider who operates the
local power grid in the region.
7. Each PGO plans for a manual load shedding
within its area of responsibility based on the
results of S
TYREL to protect power lines that
supply CI from early disconnection.
G. Each PGO sends its plan to the national PGO.
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4.2 Critical Information Deficiencies
The design of the information flows and processing
alongside the multi-level approach of S
TYREL exhibits
built-in deficiencies in the information basis
necessary for proper decision-making. Several
challenges, such as information scarcity in criticality
assessments, information withhold in sharing,
information loss when sharing and ad-hoc
information creation due to scarcity, confront the
interorganisational co-operation during S
TYREL.
Analyses of the process both the reference process
described in the official documentations and the
recent execution of the national process in 2014/2015
have revealed four critical stages in the process
wherein the deficiencies manifest.
1. Identification and prioritisation of CI objects
2. Aggregation (I) of CI objects into power
lines at the local level
3. Aggregation (II) of all local power lines to a
regional ranking at the regional level
4. Aggregation (III) of regional rankings of
local power lines and planning of manual
load shedding at the power grid level
The following subsections detail the effects of
information deficiencies with regard to the
dimensions of information quality, security and
preservation (see Table 1) in the Swedish approach of
CIP against power shortages.
4.2.1 Identification and Prioritisation of CI
The first critical stage covers the limits during the
identification of CI that issue information scarcity in
subsequent criticality assessments. The mentioned
actors act separately and focus on their portion of CI,
which promotes an overvaluation of the CI’s
criticality within the actor’s area of responsibility.
The interviews indicate that such overvaluation has
occurred at both national agencies and municipalities,
which has prompted recurring discussions on the
matter. The deficiencies in the information basis at
the national, regional and local levels accumulate
during the process steps 1 to 3 and manifest in the
information-sharing step C, as Section 4.1 describes.
The analysis reveals the following issues.
Information Quality
Underrepresentation of the private sector
Uncertain whether all CI is present
Criticality assessment relies on eight-point scale
Neglects interdependencies between CI/sectors
Long lists of CI objects
Information Security
Lack of rules regarding authorised access
hampers data collection
Uncertain how national assets are incorporated
Fear of disclosure limits integration in risk and
crisis management
Information Preservation
Uncertain whether national prioritisation of
local CI objects is preserved
Uncertain how national and regional CI objects
are considered in relation to local CI
Central management system is absent
4.2.2 Local Aggregation of CI
The second critical stage concerns the aggregation (I)
of CI objects into power lines at the local level. The
semi-automated aggregation during process step 5
uses an insufficient approach that relies on time-
consuming manual control and adjustments. When
sharing information during step E, CI information
loss is due to the transfer of information from the first
spreadsheet to the second one. This transfer affects
the granularity of information, which, according to
the handbook and the interviews, is motivated by
information security concerns as well as recurring
discussions of variations in municipalities’
interpretations of the priority list (see Table 3). The
closer investigation of the local aggregation discovers
the following concerns.
Information Quality
Overly trust in additive aggregation system
Hardly any reassessment of power lines
Overwhelming content
Non-prioritised power consumers are ignored
No common rules for addressing information
gaps
Information Security
Outdated hardware and software systems affect
compatibility and access
Spreadsheets do not prevent unintended
information altering or loss
Possibility that unrecognised copies exist
Information Preservation
Irretrievable removal of object information
Power lines are specified by score, the number
of objects in each priority class and a final
ranking number
Rare documentation of assessment and changes
Enhanced Information Management in Inter-organisational Planning for Critical Infrastructure Protection: Case and Framework
323
4.2.3 Regional Aggregation of CI
The third critical stage comprises the aggregation (II)
of all local power lines to a regional ranking at the
regional level during process step 6. According to the
information loss at the previous stage, CAB
interviewees expressed challenges in generating a
regional ranking of power lines from the rankings of
up to 49 municipalities. The concerns include manual
corrections and further resassessments that
necessitate ad-hoc information creation to mitigate
the problem of balancing CI’s importance between
municipalities and regional or national interests. For
example, high-priority CI (which may also be of
regional or national interest) can fall in the regional
ranking if there is a low number of other prioritised
CI on that line. Finally, any information on CI is
completely lost in the information-sharing step F
between CABs and PGOs. Particulary emerging
aspects are the following.
Information Quality
Reassessment of power-lines is impossible
Overwhelming amount of condensed
information that each CAB must process
No common rules for merging the rankings from
all municipalities into a county-wide ranking
Information Security
Variety of hardware and software systems affect
compatibility and access
Uncertain how national and regional CI is
represented in the final ranking
Little knowledge of the source of information
Unrecognised copies may exist
Information Preservation
Irretrievable removal of any assessment
information
Power lines are specified by their identifier and
ranking number
No documentation of assessment and changes
Exchange of experiences in informal networks
4.2.4 Cross-regional Aggregation of CI
The fourth critical stage marks the final aggregation
(III) of regional rankings of local power lines and
their inclusion in the subsequent planning of manual
load shedding at the power grid level. Step 7 of the
S
TYREL reference process does not stipulate any
approach for this collocation and leaves this decision
to the PGOs. In Sweden, there are four power grid
areas, 21 counties and 291 municipalities. In one
example, the participating PGOs was tasked with
information processing for 120 municipalities and 15
CABs. This PGO bewailed a lack of alternatives and
resources to both assess the criticality of the power
supply to these lines and update the power supply to
CI objects because of information scarcity. The
analysis of the information transition to the next-level
planning revealed the following deficiencies.
Information Quality
Reassessment of national, regional or local
requirements is impossible
No common rules for merging the rankings from
several counties to a power-area-wide ranking
No information on contiguous power grids
Information Security
Different requirements for information security
cause manual transfer at PGOs
Unexpected power line identifiers reveal
compromised integrity (between step D and F)
Altered information can cause inappropriate
decisions in emergencies
Information Preservation
Unclear if the final plan fulfils the goal
Few PGOs are capable to apply the plan
in 15 minutes after order from the national PGO
About one-third of PGOs did not complete
S
TYREL with the manual-load-shedding planning
Little documentation of proceedings
Inadequate tracing of changes in the power grid
S
TYREL applies decentralised processing that lacks a
common framework of information security
management and quality management. Because of
this insufficient system governance, the protection of
sensitive information as well as the ability to evaluate
the shared content rely on each actor’s commitment
and effort. The interviews reflect varying perceptions
of the significance of these concerns, which may
explain why a number of national agencies, such as
those concerned with health, post, telecommunication
and defence, refrain from participation. However,
such withholding of information affects the
completeness of information in the planning.
After this examination of the inter-organisational
information sharing alongside Swedish emergency
response planning for an event of a power shortage,
the following section revises the attributes of
information quality, security and preservation
provided in Table 1. Based on the evidence from the
Swedish case, this study discusses and revises each
attribute and suggests a framework for the assessment
of information and information processing for CIP.
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5 INFORMATION ASSESSMENT
FRAMEWORK
5.1 Information Dimensions and
Attributes in Swedish CIP
Since information is the process object in STYREL, the
levels of information quality at the various stages of
the planning influence the quality of the final product,
namely the emergency response plan.
Accuracy relates to the correctness of
information, such as the identification number of a CI
object or the corresponding power line identifier.
Accuracy has not always been high in S
TYREL,
according to the interviews. Moreover, due to the
long planning period in S
TYREL and continuous
changes in both the society and the power grid,
information which was correct at the point of creation
and processing could no longer or not fully reflect
societal circumstances once the emergency response
plan is finished or must be applied.
Objectivity targets the classification of CI, which
should be ascertainable independent of an individual
decision-maker. Analysis of the Swedish process
illustrates that various interpretations of the
classification scheme (see Table 3) have obstructed a
uniform assessment of CI. The aggregation of CI
objects into power lines and the ranking thereof use a
scoring system that promotes objectivity. However,
this additive approach does not necessarily reflect the
aggregated societal utility of CI objects on a power
line. Municipalities and CABs can therefore change
the ranking of power lines to achieve a stronger
balance between the local and regional ranking of
local power lines. These changes in turn can
undermine the objectivity of the aggregation (I)
approach. The absence of any recommended
aggregation method at the regional level (II) and at
larger PGOs (III) further weakens the objectivity of
this planning process.
Moreover, the interviews have indicated that the
second run of S
TYREL mainly used information from
the previous planning as the input information, which
may raise questions regarding the timeliness or
currency of information. According to interviews
with PGPs, the timely extent of the planning process
(including the stand-by periods between the process
iterations) in combination with grid development and
expansion, which have accelerated to meet
requirements of renewable electricity production, can
eventually challenge the usefulness of the produced
emergency plan when it must be applied.
Since the majority of CI is privately operated, the
completeness of the information basis appeared to be
a major problem in S
TYREL. Therefore, it is possible
that CI remains unknown as a result of limitations of
time, resource allocation and knowledge or the
absence of a common set of rules for the dimension
in the planning process. For instance, a large part of
society is underrepresented in S
TYREL; this includes
the private sector and civic society. Security concerns
have also prompted national authorities to limit their
participation in the planning. Moreover, S
TYREL
focuses on electricity-consuming CI objects at the
local level, such as buildings. This concentration
ignores supply chains and staffing, which can be
necessary for the function of an object. In turn, a local
object and its services can also be of vital importance
for other municipalities or regions, which the S
TYREL
approach overlooks.
Issues with the format and comprehensibility have
arisen in Swedish planning from the tools it uses,
namely spreadsheets and the classification scheme.
These tools require adequate experience to
understand and assess the information. The amount of
collected information has varied considerably,
particularly at the local level. Therefore,
municipalities and CABs have employed various
strategies to process the content, which include the
merging of national assets into the list of local CI.
Whereas the local level has information on local CI
and addresses the adequate identification of objects
and the assessment of each object’s criticality for the
local society, the regional level lacks object
information and thereby faces reduced
comprehensibility of information during the task of
creating a regional ranking of local power lines. Since
the process did not employ a centralised information
system, the proceeding further encountered technical
issues, such as the compatibility of hardware and
software systems, encryption and decryption
requirements, and the individual representation on the
screen. Interviewees reported that such issues drained
their energy, which implies that format and
comprehensibility, i.e. proper information
representation, have a significant effect on the quality
of both the processed information and the emergency
response in cases of power shortage.
Information security is another vital concern in
long-term, large-scale planning. This term
encompasses far more than prevention of the
disclosure of secrets.
Both the aforementioned tools and further
security concerns impeded the availability and access
to information in the Swedish process. First, in
2014/2015, interviewees reported technical issues
Enhanced Information Management in Inter-organisational Planning for Critical Infrastructure Protection: Case and Framework
325
due to out-dated software on computers which had no
Internet access and which were exclusively used for
information processing in S
TYREL. In view of this, it
is reasonable to question the availability of collected
information at a certain point of time for authorised
personnel. Second, since the S
TYREL process does not
clarify who is authorised to access which kind of
information, some actors withhold information,
which can generate a delay in the process and
incompleteness of information, for example.
The reputation of the source and information
integrity can support well-documented and verifiable
content in CIP planning. In the Swedish case, the
majority of interviewees received the classification of
CI assets from one national authority that was met
with strong rejection of its particular interpretation of
the classification scheme. This in turn affected the
reputation of the source and led to intended
information alteration. Since the recent process lacks
feedback loops and evaluation measures, these
changes are hardly traceable; thus, a national
authority cannot verify whether or to what extent the
process includes national assets. In addition, the
information processing in S
TYREL can further affect
information integrity. For example, the spreadsheets
it uses allow for changes – whether intended or not –
without recording. Thus, information may have
disappeared unnoticed or even by intention.
Since CIP planning concerns the security of a
society, the confidentiality of concrete CI assets and
objects is vital to maintain national security.
Although the S
TYREL process does not stipulate any
concrete measures to ensure authorised access, the
premise is to prevent information from disclosure.
The operational realisation rests on the responsibility
of each actor and on each CAB in particular due to its
double role in the process as a participant and a
regional co-ordinator (Große and Olausson, 2018).
Observations of the interviewee environment indicate
that such proceeding permits a wide spectrum of
approaches based on individual commitment and
knowledge of information security. Since the lack of
common rules, a controllable information-sharing
system, and authentication and authorisation
measurements in the S
TYREL approach can facilitate
information disclosure, the STYREL process removes
information at each stage which fundamentally
affects the information quality for subsequent
decision-making.
The information security attribute of privacy has
gained attention through the implementation of the
European regulation on data protection (European
Union, 2016b). The majority of CI is privately
operated, and businesses that not are legally obligated
to participate in CIP planning can withdraw their
participation and require the removal of processed
information. In S
TYREL, such removal appears to be
an easy task since the information on CI should be
stored only at the local level. Nevertheless, the
distributed approach of information sharing in S
TYREL
makes it almost impossible to assure this case. Local
copies may exist with several actors, and the
aforementioned copy-and-paste behaviour may cause
the re-emergence of information that should have
been removed.
The amount and content of information that is
processed through and alongside the Swedish process
both formally and informally requires particular
consideration of information preservation, as the
information that each process step creates and
processes acts as input for both subsequent process
steps and a later evaluation of the entire process.
On the one hand, the meaning of information
relates to the individual needs of a decision-maker,
both in terms of making sense of the information and
perceiving this information as beneficial for the task.
During the S
TYREL process, each stage successively
reduces the meaning of information by changing,
removing and dividing the content. The final ranking
at a PGO is a context-free list of numbers and power
line identifiers, which does not explain the
appearance of such ranking or which reasoning it
substantiates. Although the national PGO receives the
complete lists from all CABs, the information
contains no meaning for this provider at this stage of
the process (aggregation II), as the national operator
has no knowledge of individual power lines at the
regional or local level of the grid. This proceeding
constitutes an unnecessary information flow and,
thereby, a risk to information security.
On the other hand, information can provide
evidence of the process and the decisions and actions
it involves. However, some respondents remarked
that the spreadsheets have minimal space for
comments and explanation, and the S
TYREL approach
otherwise neither requires nor facilitates any
documentation. Few of the respondents reported that
they documented the proceeding during the S
TYREL
planning in some way, while the majority stated that
no other documentation or recording of changes exist.
Notably, some could not even identify the location of
the produced ranking. The absence of documentation
of proceedings by the actors not only elevates the
entrance level for new personnel but also precludes a
comparison and evaluation of local approaches as
well as the entire process.
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5.2 Requirements of the Information
Basis for CIP
As evidence from the STYREL process demonstrates,
information management for CIP has to consider
several aspects in creating and maintaining an
appropriate information basis for decision-making. In
the emerging domain of CIP, information quality
must compete with information security and
information preservation. The triangle of these three
dimensions warrants thorough consideration and
balance in accordance with the particular needs of a
community, society, nation or international co-
operation. However, the study also reveals a difficulty
in assessing individual, slightly structured approaches
that are parts of a whole, large-scale and long-term
national process. Particularly, comparisons of local
proceedings appeared hardly possible without
adequate documentation and criteria for assessment,
which in turn hindered an evaluation of consequences
of the proceedings for society’s safety. Moreover, no
similar cases have been documented in detail from
which to learn, and there is not much evidence from
larger blackouts or power shortages that could inform
information management and development, which
relates to such national planning of CIP measures.
This study emphasises several attributes of the
three dimensions of information quality, security and
preservation. These attributes are commonly used
(Arazy et al., 2017; Knight & Burn, 2005), so
evidence from the represented case highlights issues
that interconnect with these attributes. To enable
assessment of local, regional, national or international
approaches to information processing in CIP
planning, the results of this study can concretise these
attributes in the context of CIP (see Table 4).
Table 4: Attributes for Assessing Information and
Information Processing in CIP.
Dimension Attribute
Extend to which the
information is …
Information Quality
Accuracy
correct, flawless and certified
free of error at each step and
actor in the process.
Objectivity
unbiased, unprejudiced and
impartial regarding the
criticality classification of CI
assets for a de
p
endin
g
societ
y
.
Timeliness /
Currency
up to date and updatable at
each step, actor and certain
p
oint of time in the
p
rocess.
Completeness
of sufficient breath, depth and
scope to reflect the structure
of the societ
y
to be
p
rotected.
Representation
well-organised, concise and
consistent as well as inter-
p
retable and readable and
considerate of the human
abilit
y
to anal
y
se bi
g
data.
Information Security
Availability /
Access
accessible for authorised
p
ersons at the correct time,
in the right place and to the
appropriate extent of access
permission.
Integrity /
Reputation
highly regarded in terms of
source or content, verifiable
at each step and actor in both
directions of the process, and
well documented and free of
unauthorised alteration.
Confidentiality
p
revented from disclosure by
unauthorised persons
alongside the process,
b
etween process iterations
and within the entire infor-
mation
p
rocessin
g
s
y
stem.
Privacy
limited to CIP, controllable
during its life cycle and
removable on demand under
consideration of regulatory
conditions.
Information Preservation
Meaning
b
eneficial for the task,
valuable for sense-making at
each step and actor in the
p
rocess and comprehensive
when auditing proceedings,
structures and methods.
Evidence
well documented and
completely recorded at each
step and actor in the process
and at the meta-level for
evaluation and improvement
of the process and the
p
rocess develo
p
ment.
Employing a scale for each attribute to indicate
the level of fulfilment can facilitate a further
evaluation and comparison of particular proceedings,
such as those at the local or regional level in S
TYREL.
Thereby, such scale can reflect the maturity of each
attribute and improve the capability of the process to
produce the intended plan for CIP against power
shortages. The results of this study demonstrate that
the government initiated national efforts towards CIP,
while the private sector mainly operates targeted CI
assets yet are hardly included in CIP planning. Thus,
appropriate public-private co-operation seems
necessary to obtain mature planning processes for
local, regional, national and global CIP. In particular,
process development in the public sector could learn
from maturity models and process performance or
capability indicators that are common in business.
Enhanced Information Management in Inter-organisational Planning for Critical Infrastructure Protection: Case and Framework
327
6 CONCLUDING REMARKS
This study establishes an analytical framework that is
built upon three dimensions and 11 attributes to
assess information in inter-organisational planning
for CIP. To foster information assessment and
management that bridge the inherent conflicts
between information sharing and information
security in CIP, this paper demonstrates the decision-
making process in Swedish CIP for the case of a
power shortage. Since previous research has
emphasised that both the user and the context in
which information is acquired and utilised are
significant for assessing processed information
(Arazy et al., 2017; Bizer and Cyganiak, 2009; Strong
et al., 1997; Wang & Strong, 1996), this study
clarifies both the process and the dimensions to assess
information. In the Swedish case, the decision-
makers in the multi-level process are both creators
and users of information, whereas a subsequent
planning level employs information from a previous
level as input in the national policy-making process.
The results have illuminated crucial deficiencies
in inter-organisational emergency preparednes and
CIP planning that stem from the complexity of
information management in such processes. Since
S
TYREL applies decentralised information processing,
the reference process regulates neither information
security management nor quality management. In
particular, a filtering and altering of information that
affect the quality of decisions alongside the process
and the emergency response plan that relies on them
manifest at four stages in the Swedish approach. By
tracing the information and decision-making during
this large-scale approach, this study contributes
evidence-based foundations for information
management in inter-organisational settings, such as
the multi-level planning for CIP.
This study contributes an assessment framework
that specifies a set of dimensions and attributes as
baseline for assessing information and information
processing in CIP. Furthermore, the framework
provides support in identifying the extent to which
conflicts occur between dimensions and enables
analysis to balance them. This element is particularly
relevant for CIP, wherein information security and
information sharing are important yet conflicting
aspects.
The proposed framework and its attributes require
further specification, and future studies in domains
beyond power infrastructure may reveal additional
attributes. Attributes may also differ according to
legal situation. Therefore, future development of a
process assessment model for CIP should evaluate the
relevance of each dimension and attribute in relation
to the others. Moreover, concrete definitions should
describe the maturity levels in detail. To establish
auditable conditions for a planning process for CIP,
such as S
TYREL, minimal requirements must be
specified to determine the lowest acceptable level of
each dimension and attribute. The development of
such maturity model for CIP processes should further
consider (upcoming) legal regulations and emerging
international strategies for CIP (Mattioli and
Moulinos, 2015). Such framework can provide a tool
for internal self-assessment by each actor as well as
an external audit by an independent body.
ACKNOWLEDGEMENTS
This study was supported by the Swedish Energy
Agency alongside the project: ‘Från myndighet till
medborgare och tillbaka: En studie av samverkan och
kommunikation inom ramen för Styrel’, which is
gratefully acknowledged.
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