Reference Date: Feasibility study outcomes Preparation overview · Reference: URMS 143938 Date:...
Transcript of Reference Date: Feasibility study outcomes Preparation overview · Reference: URMS 143938 Date:...
Reference: URMS 143938 Date: 08.03.2017
Micro behaviour to Macro resilience Final Report
Purpose of report
This report details the deliverables and costs delivered in respect of this grant, for Infrastructure Typologies feasibility study (round 2), awarded by Sheffield for the ENCORE project. The scope of the work includes preparation, holding of an event and follow-up after the event on the topic of infrastructure typologies.
Feasibility study outcomes
Following excellent engagement with attendees, there is desire to develop the literature review into a journal article, and to identify the key typologies for infrastructure interdependencies. Attendees contributed expert opinion in response to two stimulating talks (Richard Ploszek) and Warren Greig) which will form a substantial part of the article. The transcripts have been produced but the funding did not stretch to developing a full journal article.
Preparation overview
A literature review was conducted focusing on the question “How have infrastructure interdependencies been defined and modelled in the literature”?
A series of refined Web of Science searches were conducted based on this question, and focusing on the infrastructure sectors of waste, water, energy, transport and telecommunications. 1,451 articles were obtained in the initial set of searches. Duplicate articles were removed leaving 1411 articles. These were then screened in two stages. First, they were screened for inclusion based on their titles and abstracts, using specific criteria for inclusion and exclusion. 350 of these made it through to a second round of screening, which involved a stricter application of the inclusion and exclusion criteria based on the full texts of the articles. This resulted in 62 items being included in the review.
These articles were read in full and codes or categories applied to them, based on the research question above and on themes found to be of importance in the literature itself. The research question led to the use of themes related to types of interdependencies, and different methodological approaches to modelling and simulation. The literature itself helped in the refinement of these themes, which were then used to classify and describe the different articles and by extension the state of the theoretical (consisting mainly of defining and broadening our understanding of interdependencies and their typologies) and methodological research (consisting of the multitude of approaches used for simulating, modelling and understanding interdependencies in a variety of cases across infrastructure sectors) for conceptualising and modelling infrastructure interdependencies. Other themes arose as salient topics of interest in the research, such as resilience, human and social factors in interdependencies, and many others, and these were used to further classify and describe articles according to their coverage of these themes.
The reviews and short-lists of the analyses and articles are attached in Appendix 2.
Event overview
There were 25 registrations for the event. Five participants sent apologies: Ruth Hughes (NERC), Mehroz Shaikh (Goldsmiths), Sagar Sumaria (SO Ethical Media), Dee Tarday and Gulsana Mussagaliyeva. See Appendix 1 for the 20 attendees.
Liz Varga chaired the event. The meeting agenda appears in Figure 1. The keynote speaker, Richard Ploszek, from the Infrastructure and Projects Authority, presented thought provoking ideas: Presentations appear in Appendix 3. The transcripts from the event are available upon request.
AGENDA11.00: Welcome Liz Varga 11.05: Key note – Richard Ploszek – Infrastructure Interdependencies 11.40: Interdependencies – a literature review – Warren Greig 12.10: Panel Discussion – Richard Ploszek, Liz Varga, Jennifer Whyte, Neil Carhart, Simon Jude, Warren Greig. Five minute thought pieces from each followed by Q&A. 13.00: Lunch and networking
14.00: Break out sessions 15.15: Plenary feedback 15.45: Discussion and next steps 16.00: Close
Figure 1: event agenda
Cost statement
Breakdown of Financial Expenditure Item Amount Spent T&S General £162.75 T&S for Early Career researcher to attend Event
£28.00
T&S: Workshop at Imperial College - Catering deposit
£590.00
Workshop at Imperial College, London 25.01.18. Venue Hire plus associated costs
£2079.74
DI Researcher (Warren Greig) 01.10.17 – 31.03.18 @ 0.25 FTE.
£3430.03
TOTAL: £6290.52 (100% FEC)
Invoice has been submitted by Cranfield University’s finance team.
Next steps
Include development of these outputs in the ESCRIT programme grant.
End of report
Appendix 1 – event attendees
ENCORE Infrastructure Interdependencies workshop
Thu 25 January 2018 10:30 – 16:00 GMT
Imperial College London 58 Prince’s Gate
London SW7 2PG
Registered Attendees
Bhamra, Herpreet Dept for BEIS Carhart, Neil University of Bristol Chatzimichailidou, Mikela Imperial College Doherty, Sharon City Business School Evans, John AIG Eyanga Nkombe, Tania myHela Foden, Mark Mark Foden Greig, Warren Cranfield University Hutchinson, Simon Digi2al Jude, Simon Cranfield University Lovell, Kat University of Sussex Mayfield, Martin University of Sheffield Mian, Juliet ARUP Naghshbandi, Neda Cranfield University Nazer, Zeina University of Chicago Ploszek, Richard Infrastructure & Projects Authority Street, Roger UKCIP Varga, Liz Cranfield University Whyte, Jennifer Imperial College Yabari, Oday 20
Appendix 2 – Reviews and short-lists of the analyses and articles
Essential Reading
Rinaldi Steven M, Peerenboom James P, and Kelly Terrence K. (2001). Identifying,
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Systems Magazine, 21(6), pp.11-25.
Pederson P, Dudenhoeffer D, Hartley S, and Permann M. (2006). Critical Infrastructure
Interdependency Modeling: A survey of US and international research. Contract, (August),
Ouyang Min. (2014). Review on modeling and simulation of interdependent critical
infrastructure systems. Reliability Engineering & System Safety, 121, pp.43-60.
Rinaldi Steven M. (2004). Modeling and simulating critical infrastructures and their
interdependencies. In: . : IEEE, pp.8-pp. Available at: files/121/Rinaldi - 2004 - Modeling and
simulating critical infrastructures a.pdf files/99/1265180.html.
Saidi Saeid, Kattan Lina, Jayasinghe Poornima, Hettiaratchi Patrick, and Taron Joshua. ( ).
Integrated infrastructure systems—A review. Sustainable Cities and Society, 36, pp.1-11.
Long List
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Interdependencies – What do we know, and how do we come to know it? A systematic literature review of interdependency conceptualisations and methods for modelling these in critical infrastructure settings.
(Names here…)
Abstract Our understanding of critical infrastructure systems is arguably too domain-specific, and not systematic enough. A more systemic understanding can be reached by means of understanding the interdependencies between infrastructure sectors, thus recognising critical infrastructures as complex, interconnected systems. This review addresses conceptualisations of interdependencies in the energy, waste, water, telecommunications, and transport sectors, and represents an attempt to work towards an integrated account of infrastructure interdependencies, building upon and complementing seminal, existing integrated accounts. Existing conceptualisation are seen to capture potential understandings of interdependencies effectively, and modelling methodologies are effective, however there are a number of research gaps in the literature. Although there is an increasing recognition that infrastructure interdependencies can be understood as complex systems, work remains to be done on integrating approaches to reach a common framework of understanding that recognises and can explain holistically these complex, socio-technical systems.
Interdependencies – what do we know? This review of infrastructure interdependencies will outline the diverse, yet increasingly convergent, ways in which interdependencies have been conceived in the literature. It will also address the multitude of methodologies used in modelling and understanding interdependencies, in an attempt not only to visualise the evidence base, but to come to an appreciation of the extent to which these models lend themselves to an integrated understanding of interdependencies, grounded in a holistic, complex-systems based framework. The first section will examine how interdependencies have been conceptualised, by drawing on the definitions employed in the literature. Following this, an outline will be given of how interdependencies have been used, understood and modelled in the context of the critical infrastructure sectors of water, waste, energy, transport and telecommunications. Understanding interdependencies within critical infrastructures is of crucial importance for understanding resilience, risks and the potential for failure propagation at different levels affecting general populations, economies and even national security. Yet our understanding of critical infrastructure independencies is spread across and shaped by different disciplinary frameworks and models. A multiplicity of fields including policy studies, planning, economics and engineering research draw on different examples, treating certain interdependencies as more important than others, and using different models for understanding interdependencies. In order to conceptualise and manage critical infrastructure interdependencies, a ‘common language’ for understanding outside of and across these disciplinary silos is arguably needed. To address issues of resilience and prevent failures, it is necessary to ensure collaboration and
an interdisciplinary, cross-sector framework of understanding at a systemic level involving multiple stakeholders. This means consciously working towards a holistic understanding, in which rather than individual infrastructures being understood discretely, they are conceptualised within a ‘system of systems’ framework; that is, as connected parts within a complex system (Carhart & Rosenberg, 2016; Eusgeld, Nan, & Dietz, 2011). The systemic metaphor also speaks to the importance of understanding interdependencies within the complex global system. As processes of globalisation and economic integration increase at both local and global scales, so do infrastructure systems become enmeshed, and new interdependencies arise. An understanding of interdependencies allows for a better overview and management of systemic infrastructure interdependencies, arguably to a greater extent than does an understanding of individual components by themselves. However, it is also true that the growth of such links increases the growth of vulnerabilities at a systemic and component level – as links increase, so do the chances of failures in one part of the system affecting others. Factors in the environment connected to business, the economy, public policy, legal and regulatory concerns, security, health and safety, socio-political and technical issues all potentially affect interdependent infrastructures in subtle and potentially disruptive ways (Rinaldi, Peerenboom, & Kelly, 2001). An understanding of interdependencies and ways to model them thus promises a better assurance of management and mitigation strategies to augment resilience within infrastructure systems that critically underlie the foundations upon which societies, and indeed the daily lives of everyone within them, operate and function. This review focuses on the definitions and methodologies used to understand interdependencies within the literature covering infrastructure relating specifically to water, waste, energy, transport and telecommunications sectors. Although the aim is for this work to represent an early contribution towards constructing such an integrated understanding, it acknowledges that there is seminal work that has already been done in this area, which the review cannot presume to supplant but aims to supplement. A number of researchers have recognised the importance of addressing this dispersed set of understandings. Rinaldi et al. (Rinaldi et al., 2001) provided arguably the most influential classification structure for interdependencies, pointing to four interdependency types, namely physical, cyber, logical and geographic types of interdependency. Their framework has been influential and has been used as a building block by other researchers working towards an integrated account. Rinaldi (Rinaldi, 2004) then addressed this expansion and added to his original framework by adding a number of organising principles with the potential to influence infrastructure interdependencies.
Reviewing the literature:
In attempting to carry out a systematic review of literature on infrastructure interdependencies, it was necessary to come up with a research question. This was “How have infrastructure interdependencies been defined and modelled in the literature”? Recognising that incorporating theoretical or conceptual papers and empirical studies with different methodological frameworks necessitated a flexible review, this review took the form of an iterative, thematic analysis, an approach that also allows for the combination of quantitative work with more qualitative work (Gough, Oliver, & Thomas, 2012; Petticrew & Roberts, 2006). In order to find relevant articles from across literatures, such as management and engineering, the Web of Science database was used. This allowed for searches to be conducted across disciplinary areas, and also for refinement and exclusion of areas thought to be less relevant,
for example physics and many areas of information technology focusing on ‘infrastructures’ of a different kind. Search strings were created based on the research question and the infrastructure sectors of interest, and so definitions, methodologies, the sectors in question and synonymous terms were searched for in an iterative manner. The goal was to be precise enough to identify the most relevant material, and also sensitive enough to identify as much relevant material as possible (Brunton, Stansfield, & Thomas, 2012).
Figure 1: Final search strings:
The final set of results obtained from the search strings above included 1,451 articles. These were then screened in two stages. After duplicate removal, 1,411 were screened for inclusion based on their titles and abstracts. 350 of these made it through to a second round of screening involving looking at the full texts of the articles. This resulted in 62 items being included for review. These details are outlined in the figure below:
Figure 2: Flow chart detailing systematic review screening procedure
TS=(Interdepend* OR link* OR coupl* OR connect* OR sharing OR coopetition OR mutual use OR shared use OR shared usage OR mutual usage OR joint usage OR collaborat*) AND TS=("water" OR "reservoir" OR "infrastructur*" OR public utilit* OR private utilit* OR energy OR power trans* OR power dist* OR electricity OR grid OR network OR transport* OR waste OR sewage OR sewerage OR telecom* OR wireline OR wireless OR mobile OR pipeline*) Refined By: TOPIC: ("model" OR "theor*" AND "definition") AND WEB OF SCIENCE CATEGORIES: (ENVIRONMENTAL SCIENCES OR ENGINEERING ENVIRONMENTAL OR ECONOMICS OR ENGINEERING MULTIDISCIPLINARY OR WATER RESOURCES OR BUSINESS OR TELECOMMUNICATIONS OR MANAGEMENT OR TRANSPORTATION)
Results:
Reviews of interdependencies: A number of reviews of interdependency research have been undertaken to date. Ouyang (Ouyang, 2014) conducted a ‘review-of-reviews’, also examining interdependency types and frameworks for simulation. More recently, Saidi et al. (Saidi, Kattan, Jayasinghe, Hettiaratchi, & Taron, 2018) reviewed the evidence for the purposes of understanding infrastructure systems within an integrated framework. Pederson et al. (Pederson, Dudenhoeffer, Hartley, & Permann, 2006) attempted a review of global efforts to understand and model interdependencies, reporting in brief on the various labs undertaking such work, their research programmes and the strengths and weaknesses of each. A similar synthesis was undertaken by Satumtira and Duenas-Osorio, who provided a more focused overview of salient research efforts to date and framed their discussion in terms of major research trends over time in the area (Satumtira & Dueñas-Osorio, 2010). Interdependencies: A typology A number of types of interdependencies have been identified in the literature. Perhaps the most influential typology is that argued for in Rinaldi et al. (Rinaldi et al., 2001), who delimited physical, cyber, logical and geographic interdependencies; actually an adaptation of an earlier classification scheme (Peerenboom, Fischer, & Whitfield, 2001). Pederson at al. (Pederson et al., 2006) expanded on this typology, suggesting 5 types, physical, informational, geospatial, policy/procedural and societal. Zimmerman simplified this account and outlined two types, functional and spatial (Zimmerman, 2004). Zhang and Peeta combined some of these approaches and argued that due to economic factors, both ‘budgetary’ and ‘market and economic’ types should be included alongside ‘functional’ and ‘physical’ (Zhang & Peeta, 2011). Wallace et al. (Wallace, Mendonça, Lee, Mitchell, & Chow, 2003), approaching the issue in terms of mitigation and response in managing critical infrastuctures and potential disruptions, took a different approach, naming input, mutual, shared and exclusive/or types. The table overleaf, adapted from Ouyang (Ouyang, 2014), lists these typologies and gives details of each.
Table 1: Summary of interdependency types Authors Interdependency
types Definitions
Pederson et al. 2006 Geospatial Informational Physical Policy Societal
There is co-location of infrastructure components within the same footprint There is a binding or reliance on information flow between infrastructure systems There are direct linkages between infrastructure systems from a supply/consumption/production relationship There is a binding of infrastructure components due to policy or high level decisions Interdependencies or influences that an infrastructure component event may have on societal factors e.g. public opinion, confidence, fear cultural issues. Even if no physical linkage exists, consequences from events in one infrastructure may affect others.
Rinaldi et al 2001 Cyber Geographic Logical Physical
The state of one infrastructure system depends on information transmitted through the information infrastructure A local environmental event can create state changes in two or more infrastructure systems The state of one infrastructure system depends on the state of others via a mechanism that is not physical, cyber or geographic The state of one infrastructure system is dependent on the material output(s) of another infrastructure system
Wallace et al. 2003 Co-located Exclusive Or (XOR)
Input
Mutual Shared
Components of two or more systems are situated within a prescribed geographical region Only one of two or more services can be provided by an infrastructure system, where XOR can occur within a single infrastructure system or among two or more systems The infrastructure systems require as input one or more services from another infrastructure system in order to provide some other service At least one of the activities of each infrastructure system is dependent upon each of the other infrastructure systems Some physical components or activities of the infrastructure systems used in providing the services are shared with one or more other infrastructure systems
Zhang and Peeta 2011
Budgetary Functional Market and economic
Physical
Infrastructure systems involve some level of public financing, especially under a centrally-controlled economy or during disaster recovery The functioning of one system requires inputs from another system or can be substituted to an extent by the other system Infrastructure systems interact with each other in the same economic system or serve the same end users who determine the final demand for each commodity/service subject to budget constraints, or are in the shared regulatory environment where the government agencies may control and impact the individual systems through policy. Legislation or financial means such as taxation or investment Infrastructure systems are coupled through shared physical attributes, so that a strong linkage exists when infrastructure systems share flow right of way, leading to joint capacity constraints
Zimmerman 2004 Functional Spatial
The operation of one infrastructure system is necessary for the operation of another infrastructure system This refers to physical proximity between infrastructure systems
Eusgeld et al. 2011 Physical Cyber Geographic Logical Input Mutual Co-located Shared Exclusive-Or (XOR)
*Definitions as for Rinaldi and Wallace above. Emphasis is given as to their functions/interactions within SCADA IT control systems (Although note they did not provide an example of a logical interdependency in their framework).
Although the above table does a good job in counting for many of the interdependency types, the review uncovered a number of other types, as will be outlined in the results section below. Modelling and simulating typologies
A number of researchers have also provide notable classificatory schemes of methods used to simulate and model interdependencies. Rinaldi (Rinaldi, 2004), building on his earlier work on interdependency typologies, isolated six approaches to modelling interdependencies. Approach Description
Aggregate supply and demand tools Evaluate total demand for infrastructure services in given area along with the ability to supply these services. Ability to meet demand is indicator of system health.
Dynamic simulations Generation, distribution and consumption of infrastructure commodities and services seen as flows and accumulations in a dynamic simulation context.
Agent-based models Physical components modelled as agents for analyses of operational characteristics and physical states of infrastructures. Also allows for modelling of decisions when agents are decision/policy makers.
Physics-based models Standardised engineering techniques used. Power flow and stability analyses, hydraulic analyses. Detailed information down to component level.
Population mobility models Looks at movement of entities through urban regions, which interact with each other, generate and consume infrastructure commodities. Useful e.g. in modelling transport use, social networks, multimodal urban interdependencies.
Leontief Input-Output models Economic flows applied to infrastructure. Linear, aggregated, time-independent analysis of generation, flow, consumption of infrastructure commodities. Extensions incorporate time dependencies and non-linearities.
Ouyang (Ouyang, 2014) later outlined six approaches he had identified to modelling and simulation. These reflect Rinaldi’s classification, but arguably go a step further and subsume some of Rinaldi’s categories into a more general schema.
Table 2: Categories of modelling and simulation framework Category Description Empirical approaches Analyse critical infrastructure interdependencies
according to historical accident/disaster data and expert experience. Failure patterns, strength metrics, risk analysis, risk minimisation alternatives.
Agent-based approaches Envisions complex adaptive system. Bottom-up method assumes complex behaviour/phenomena emerge from simpler individual autonomous agent interactions. Agents modelled to interact with each other and environment based on simple sets of rules.
System dynamics based approaches Top-down modelling involving feedback, stock and flow concepts.
Economic theory based approaches Situated within market economy framework. Goods/services, labour/capital exchanged. Critical infrastructure systems seen as ‘intermediate goods’ and analysed using economic interdependencies. Models used include Input-Output models (IO) and Computable General Equilibrium (CGE) Models.
Network based approaches Critical infrastructure systems described as networks in which different components represented by nodes, with links representing physical/relational etc. connections between these. Topology and flow based methods used to model connection behaviours and patterns.
Other approaches Hierarchical Holographic Modelling High Level Architecture Petri Net Dynamic Control System Theory Bayesian methods
Another strength of Ouyang’s paper is that, he evaluates the modelling techniques in terms of a number of criteria. These consider which approach can be used effectively with which types of interdependencies, how much data is needed for each and how accessible this data is, what the computational cost of each approach is, how well developed or ‘mature’ the approach was at the time of writing (2014). He also usefully attempts to categorise all of these approaches in terms of how they can be used to ensure infrastructure resilience, which he categorises as a combination of resistant, absorptive and restorative capacity.
Using these efforts as a template, the present review attempted to classify and identify research themes across the set of items included in the review. Many of these items were theoretical papers that helped to define or conceptualise interdependencies, their uses and how they are modelled, and these include the papers that were just discussed above. Other papers included case studies or methodological papers applying one or more methods to particular infrastructure frameworks. These papers have all been published over a timeline starting in 2001, the date not being a coincidence. Although the importance of better understanding and managing critical infrastructures is an older project, with research beginning in the early 1980s and picking up through the 1990s (Satumtira & Dueñas-Osorio, 2010) with the advent of attacks on critical infrastructure in the US (Clinton, 1998), the terrorist attacks on September 11 2001 this year in New York lent a new criticality to this research in the years that followed. Indeed, the framework for the Rinaldi typology lay in a conference presentation given by his colleagues running over September 10-11 organised as a quick response to events of that year (Peerenboom et al., 2001). Although a number of papers do accord due importance to security issues, the understanding of the importance of interdependencies has expanded to include many other environments. The graph below illustrates the trend in publishing since the first paper in 2001.
The mean number of articles published per year is 3.65. There seems to be a trend in which more articles in this set have been published in more recent years. Discounting 2018, which has not yet finished, the first 8 years saw an average of 2.38 articles published, and the subsequent 8, 5.25 articles. Articles were published in the journal listed in the graph below. Journals contributing to the review by frequency:
21
2 2 2
5
2
3 3 3
2
5 5
8
7
9
1
2001 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018
Articles by Year
There were 50 articles drawn from journals. Most journals contributed one article, although two came from The Bridge and from Natural Hazards, six from the Journal of Structural Engineering and nine from the largest contributor, Reliability Engineering and System Safety. Twelve items of the 62 were from other sources, with three items being reports, two book chapters and seven from conferences or symposia. These are listed in the table below:
Non-journal articles: Reports 1 by Institution of Civil Engineers, UK
1 from Argonne National Laboratory, USA 1 from International Centre for Infrastructure Futures, UK
Book Chapters 1 Chapter from Wiley Handbook of Science and Technology for Homeland Security 1 Chapter from Beyond September 11th: An Account of Post-Disaster Research
Conferences or Symposia 1 Paper presented at International Conference on Computer Safety, Reliability and Security 1 Paper presented at International Conference on Systems, Man and Cybernetics 1 Paper presented at International Symposium of Next Generation Infrastructure, Australia. 1 from Proceedings of 3rd International Conference on Urban Sustainability & Resilience 1 from Proceedings of Security in Critical Infrastructures Today
11111111111111111
61111
2111
9111
2111
0 1 2 3 4 5 6 7 8 9 10
Applied Energy
Contract
Energy Journal
European Journal of Transport and Infrastructure…
IEEE Control Systems Magazine
IEEE Transactions on Systems, Man, and Cybernetics,…
International Journal of Complexity in Applied Science…
Journal of Computing in Civil Engineering
Journal of Industrial Ecology
Journal of Structural Engineering
Journal of Systems Science and Systems Engineering
Natural Hazards
OR Spectrum
Reliability Engineering & System Safety
Sustainable and Resilient Critical Infrastructure Systems
The Bridge
Urban Studies
Number of items
1 from Proceedings of the 2006 Winter Simulation Conference 1 from Proceedings of the 37th Hawaii International Conference on System Sciences
As for the location of the research studies conducted, there is a prevalence for US-based studies (26 or 42% of the studies), with the UK next (8 or 13%), but otherwise there is a fairly wide selection of countries represented. 18 studies did not list a country (29%) and 5 listed multiple countries (8%). This is illustrated in the graph below:
Characterising the research: Considering the research question regarding how interdependencies have been defined and modelled in the literature, it would be expected that both theoretical material on definitions and methodological material covering modelling would be included in the set of final papers reviewed, and indeed this was the case. There were 19 theoretical papers discussing aspects of interdependencies, 39 discussing modelling or simulation approaches, and 4 that did both.Type of paper Number of papers Theoretical 19 (31% of total) Methodological 39 (63% of total) Both of the above 4 (6 % of total)
Interdependencies: There were many different types of interdependencies identified in the literature. The table below lists these and the frequencies identified in the various papers: Types of interdependencies Count Physical interdependency 40Cyber interdependency 24Geographic interdependency 40Logical interdependency 24Functional and spatial 11Horizontal 2Multiple 3Vertical 2Wallace types 2Other 9Geospatial 6Policy 4
Informational 7Input 5Mutual 3Co-located 5Shared 3Exclusive-Or 3Organisational interdependency 2Societal 4Interdependency opportunities 2Managerial 2Environmental 1Operational 3Budgetary 4Economic market supply and demand 7Digital interdependency 1Buehne framework 1Duedenhoeffer et al Mathematic formalisation of interdependencies 1PESTLE framework 1Internal interdependency 1External interdependency 1Interdependency matrix typology 1Synergistic and substitutive interdependencies 1
Another manner of understanding interdependencies is according to the environment they are situated in. The following table lists the different environments found for interdependencies in the review: Environment Count Economic 24Legal or regulatory 8Technical 24Social or political 20Health or safety 7Security 20Public policy 11Business 7Ecological impact 29None of the codes above 1
In terms of infrastructure, this review focused on a specific set of infrastructure sectors, namely water, waste, energy, transport and telecommunications, meaning that only papers focusing on one or more of these sectors was included. Nevertheless, among these papers there were also other infrastructure sectors represented, as can be seen below:
Infrastructure characteristics are also an important framework through which to understand critical infrastructures, and the following were found in the papers included in the review:
Also of interest were the state of operation, the type of failure and coupling and response behaviour, categories found in a number of, although not all of, the papers. These are listed in the tables below: State of operation Count Normal 3Repair or restoration 12Stressed or disrupted 10None of the codes above 46
Type of failure Count Common cause 4Coupling strength as indicator of probability of coupling damage 1Cascading 19Escalating 5Inoperability 3Nojima and Kameda 1996 2Yao et al 2004 1None of the codes above 40
Coupling and response behaviour Count Adaptive 4Coupling damage 1Inflexible 2
Loose or tight 4Linear or complex 2Functional coupling via network topology 1Stochastic association 1None of the codes above 55
A few papers focused specifically on resilience, and enumerated different frameworks for understanding resilience. These are outlined below: Resilience focus Count Resist, Absorb, Recover model 1Absorption, adaptation, recovery model 1Robustness 4Redundancy 1Resourcefulness 1Rapidity 1Robustness, vulnerability, recovery 1None of the codes above 56
Modelling and simulation approaches: Although there are a number of categories that can be used to organise similar approaches, as listed in Table 2 above, there were a large amount of modelling, simulation and other frameworks found in the papers. Some of these have been placed into the above tabulated categories, but not all of them. This is due to the large number of different approaches, paper authors not stating the categorisation for their approach, or uncertainty about which category to place these into. Model or method for understanding interdependencies Count Agent-based modelling or simulation 11Aggregate supply and demand tools 1Artificial data sets 1Carbon emission reduction model 1Cascade effects 9Case analysis 1Cost-benefit analysis 2Cross-correlation functions 1Data issues 2Data mining 1Decision making tools 5Dependency curves 1Distributed Interactive Simulation (DIS) 1Dynamic mixed integer algorithm 1Emergency Management Strategies 1Empirical 4Expected consequence modelling 1Expert interviews 3Flood frequency analysis 1Gas flow equations - Partial Differential Equations 1Generalised sequential pattern (GSP) discovery algorithm 1Genetic algorithms 2GIS visualisation 4
Graph theory 3Hierarchy modelling 1High Level Architecture (HLA) 3Hybrid systems 5Hypothetical extraction method 1Income multipliers 1Industrial symbiosis networks 1Influence diagramming 1Infrastructure disruption model using optimization techniques 1Infrastructure failure interdependencies model 1Input-output models 11Interactive workshop 4Interdependence Fragility Algorithm (IFA) 1Interdependency matrices 2Interdependency planning and management framework (IP&MF) 2Interdependency strength 1Joint interdependency matrices 1Joint restoration strategy 1Key linkages analysis 1Knowledge discovery process 1Latent-class residential community choice model 1Level of analysis considerations 2Lifeline systems 3Linear time invariant model 1Literature review 6Machine learning 1Market-based economic approach 4Markov models 3Mathematical model 5Matrix mapping 1Megaprojects 2Mixed qualitative and quantitative methods 2Monte Carlo simulation 3Network models 21Nonlinear dynamics 1Nonlinear optimization algorithms 1Optimisation procedures 1PESTLE framework 1Petri net 3Physics-based models 1Preliminary interdependency analysis 1Probabilistic analysis 3Political sovereignty 1Population mobility models 1Predictive 4Qualitative models 1Reliability Block Analysis 1Research programme evaluation 1
Resilience factor model 1Resilience quantification metric 1Retooling strategy 1Risk mitigation 6Scenario planning 1Secondary datasets 2Security-constrained unit commitment model 1Seismic damage propagation model 1Single Degree of Freedom (SDOF) model 1Software 19Stakeholder engagement 3Stochastic process 5Survey instruments 2Survivability and dependability 1Sustainability 2System dynamics model 9Systemic safety management model 1System reliability theory 1Targeted attacks framework 6Topological complex weighted graphs 1Value creation 1Vulnerability assessment 11Water stress 1None of the codes above 0
Conclusions: Interdependency research is a mature, yet still unintegrated field. A number of scholars have discussed the need for integrating understanding of infrastructure interdependencies, to construct a ‘common language’ of understanding and escape from disciplinary silos, many have also noted that this is a difficult task. However, it is argued here that this is not insurmountable, and that adopting a complex systems framework, as indeed a number of researchers in this review have, holds promise in terms not only of integrating our understanding of infrastructure interdependencies, but also of creating new ways of working with them and even shifting the debate from one merely focused on risk mitigation to one focused on opportunities. With regard to further research, it can be seen that while there has been fairly extensive study of systemic interdependencies, there are large gaps in one of the areas identified as of relevance – that of behavioural and human influences. As recognised by Saidi et al (Saidi et al., 2018), work remains to be done in this area. Survey instruments represent one of the potential avenues for understanding, and questionnaires addressing the attitudes and behaviour of both experts and members of the public regarding these sectors could prove a fruitful avenue for further research. Arguably, however, research on behaviour change with regard to infrastructure sectors already represents a particular area of research that is already abundant and can be integrated into our understanding by means of reframing existing work and replicating it in an interdependency framework.
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Appendix 3 – Presentations from Event
21/06/2018
1
Interdependencies
ENCORE Infrastructure Interdependencies Workshop - 25 January 2018Imperial College London
2
Introduction to Interdependencies
Dictionary definition:
interdependencenoun
plural noun: interdependencies
1. the dependence of two or more people or things on each other.: "the new economic
interdependence of the two nations".
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2
3
Introduction to Interdependencies
Council for Science and Technology:A National Infrastructure for the 21st
Century• Recognised the interdependence of
infrastructure networks
• Saw interdependencies as both
risks AND opportunities for
resilience and cost saving
4
Introduction to Interdependencies
Engineering the Future report Infrastructure, Engineering and Climate Change Adaptation• Started to develop interdependency
mapping
• Many climate change risks were
interdependencies and outside of
the control of individual sectors
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3
5
Introduction to Interdependencies
Engineering the Future report Infrastructure Interdependencies Timelines
• Looked across all Govt
Infrastructure projects /policies
• Looked for obvious
interdependencies between policies
• Recommended more join-up
6
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4
7
Messy and Wicked problems
● Messy problems are characterized by Systems Complexity.
● Wicked problems by Behavioral Complexity.
● Interdependencies are a key component of Messy and Wicked Problems
Hancock, D, 2017
8
The question about Interdependencies
1. Infrastructure is definitely a Messy problem, probably a Wicked problem when regulation, markets and policy are taken into account.
2. Interdependencies are crucial to the normal functioning of the wider system.
BUT - Do they represent a Risk or an Opportunity?
AND - Do we understand them enough to know which?
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History
Infrastructure Interdependencies are not new - However:● Recognition surged around 2000● Citations still rising exponentially
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Infrastructure: network of networks
Electric
Oil
Water
Transportation
Natural Gas
Telecom
Financial Markets
Fuels, Lubricants
SCADA, Communications
SCAD
A, C
omm
unic
atio
ns
SCAD
A,
Com
mun
icat
ions
Fuel for Generators, Lubricants
Fuels, Lubricants
Fuel for Generators
Power for Pumping Stations, Storage, Control Systems
Power for Pump and Lift Stations, Control Systems
Power for Compressors, Storage, Control Systems
Fuel for Generators
Shipping
Shi
ppin
g
Fuel Transport, Shipping
Rinaldi et al., 2001
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11 Enter the presentation's title using the menu option View > Header and Footer
Resilience
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Resilience
Verizon Building 9/11
● 70,000 copper pairs severed
● 4 digital switches
● 17,000 optical lines
● 4.4m data circuits
● 41,600m3 water inundated
● PATH tunnels flooded
● NY Telecoms severely disrupted
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UK Interdependency Research
1. Driven by researchers with Systems Engineeringbackground
2. Recognises substantial benefits from understanding and managing interdependencies
3. Emphasis on interdependencies in new, large projects rather than managing existing infrastructure/assets
4. Based on understanding and managing interdependencies at the earliest possible stage of project delivery.
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ITRC and NISMod
1. The Infrastructure Transitions Research Consortium (ITRC) developed the National Infrastructure Systems Model (NISMod)
2. Computer model of major infrastructure systems in UK with interdependencies
3. Used to study UK infrastructure responses to climate change and other externalities over time, but worked with IPA to look at interdependent resilience and the impact of the Infrastructure Pipeline
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Hotspot analysis - ITRC
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IP&MF
1. In 2012, IUK sponsored a joint research project by Bristol University and UCL.
2. Created the Interdependency Planning and Management Framework (IP&MF)
3. Evidence base provided through UCL OMEGA Centre expertise on major projects
4. Case studies included● Northern Line Extension● HS2● Lower Thames Crossing
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IP&MF - Output
1. Categorization of Interdependency Types
2. Tool for mapping and understanding interdependencies
3. Three main elements:● Problem Structuring● Measurement and Appraisal● Creating Stakeholder
Understanding
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IP&MF - Output
1. Models of infrastructure as a system of systems
2. Need to understand the services that infrastructure provides to society in the policy context
3. Three key layers to consider
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IP&MF - Output
1. Types of interdependency are important to consider
2. Some are avoidable and increase risk inherently
3. Some provide opportunities for joint delivery
Interdependency Characteristic
Physical Interdependency/Dependency
Digital Interdependency/Dependency
Geographic Interdependency/Dependency
Organisational Interdependency/Dependency
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IP&MF - Lano n2
1. The key tool to emerge from the IP&MF work was the development of the Interdependency Matrix
2. Based on early 1970s work by Robert Lano3. Original purpose was to identify and engineer-out
interdependencies in spacecraft systems to make satellites more resilient.
4. Applied at a project level, but as a tool to identify and manage
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Valuing Infrastructure Spend
1. Using IP&MF has the potential to improve projects, highlight risks and opportunities
2. Identify conditions within which they become important
3. identify the value of resultant impacts in terms of costs and benefits
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Larger Scale
1. The Oxford - Milton Keynes - Cambridge Corridor presents a really good opportunity to use these tools
2. Already complex with multiple investments over a 2.5m acre area.
3. Huge number of stakeholders4. Transport solutions affect housing opportunities and vice-
versa.
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NIC StudyOverarching strategy will need to account for recommendations made by NIC.Question: Is the strategy the government’s response to the NIC or are these different products?Action: Need close dialogue between NIC and programme team.
NIC Report may recommend particular routes, stations, frequency of services etc for East West Rail and Expressway projects.Action: DfT and the overall programme needs to be prepared to respond to recommendations.Question: Would announcements risk harming land value capture prospects?
NIC Report may recommend particular locations for expanded or new settlements.Action: DCLG and the overall programme needs to be prepared to respond to recommendations.Question: Would announcements risk harming land value capture prospects?
NIC Study may make particular recommendations for water, utilities, broadband, etc.Action: programme needs to quickly define the scope of ‘other infrastructure’ and begin to establish issues and solutions, working with BEIS, Defra and DCMS .
NIC may make recommendations on land value capture.Action: programme needs to be prepared with government response.Specific announcements could harm land value capture potential.Action: dialogue with NIC to avoid losing opportunities for LVC.
NIC Study remit includes economic growth, but most dialogue to date has been on infrastructure and housing.Action: to explore how NIC is handling economic growth, as their recommendations could be accounted for by wider IS/clusters work.
NIC’s recommendations for infrastructure and housing would need to be delivered buy the planning system.Action: planning work stream to consider what governance and planning mechanisms would be needed to deliver NIC recommendations.
NIC has close links with local places, and its line of thinking could influence what places aim for through deals.
Given its remit the NIC will make recommendations independent of the government’s strategy, but they may be more successful if they take account of government intentions and priorities.Action: Need close dialogue between NIC and programme team.
Overarching Strategy
Overarching strategy will specify new settlements; areas of major housing growth; areas of new businesses. This will influence transport infrastructure plans.
Overall strategy will dictate housing locations. E.g. are we primarily increasing employment in the corridor rather than supporting employment in London?
NIC study takes evidence from government and non-government bodies.Action: DfT ensures NIC has correct range of information on transport schemes, opportunities and constraints to carry out its work.
Some sections or road & rail strategy are settled (western section of EW Rail is an existing line & the central section is limited by landscape. Expressway will run along upgraded portions of the A34, A421 & A428.) New transport links and junctions will be constrained by economic viability.
Transport•New housing development must take full advantage of East-West rail expansion and Expressway.•Feasibility of different route options for E/W railway and Expressway will dictate potential for increasing housing supply through new settlements/urban densification/urban extension will dictate most suitable routes of E/W railways and Expressway (e.g. if have fewer station stops – does that mean we need fewer but larger settlements?)
•Road & rail network will dictate location and effectiveness of new wider infrastructure developments.•East-West rail and Expressway expansions will provide opportunities for new sites and investment.
The announcement and construction of new transport links will result in uplift in land values.Details on Route and stations will be included in public consultation documents.
Some sections or road & rail strategy are settled (western section of EW Rail is an existing line & the central section is limited by landscape. Expressway will run along upgraded portions of the A34, A421 & A428.) New transport links and junctions will be constrained by economic viability.
Some sections or road & rail strategy are settled (western section of EW Rail is an existing line & the central section is limited by landscape. Expressway will run along upgraded portions of the A34, A421 & A428.) New transport links and junctions will be constrained by economic viability.
Feasibility of increasing housing supply through new settlements/urban densification/urban extension will dictate general approach to corridor.
Feasibility of increasing housing supply through new settlements/urban densification/urban extension will dictate most suitable routes of E/W railways and Expressway (e.g. do you have a transport spine or multiple transport routes?).
HousingWider Infrastructure investment must be directed with consideration towards housing sites. e.g. weak network in-between towns could lead to high reinforcement costs for new self-contained communities.
Planning permission grants for new housing development present opportunities for LVC.
Potential for home building will impact success of clusters (e.g. Oxfordshire’s low affordability –does this threaten long term viability of Life Science cluster?).
Establishing strategies for meeting house-building targets will be key deliverable for Place-based deals.
East-West Rail and Expressway must integrate optimally with new planned infrastructural assets. Plans for new rail station at Calvert would, for example, be dependent on all other planned infrastructure; the area currently having none.
•New housing sites must integrate with new utility infrastructure. New housing sites may need to be located within existing settlements if networks outside them are weak.•The capacity of existing infrastructure must also be considered (e.g. concerns flagged in OXIS report for Oxfordshire’s electricity capacity if promised
Other Infrastructure
Wider infrastructure investment will be a major factor for place-based deals, particularly as part of remit to cultivate sense of place and regional identity.
Opportunities for capturing land value uplift for funding East West Rail, Expressway and A1 upgrade are critical. Funding for these projects is not committed beyond 2019.
•LVC will be major financial factor towards development of new housing sites. Sites with higher potential for LVC will be key focus.•Publication/public discussion of potential housing sites will limit potential for LVC.
Land Value Capture and Private Finance
LVC mechanisms that government is willing to devolve may form key part of deals with areas (e.g. Oxfordshire have asked for this) .
Rail and road links and junctions must consider geographic & economic clusters to ensure that these areas are optimally served. E.g. commuter routes.
•Ensure housing work packages are framed in the context of industrial strategy directive.•Clusters will direct where new housing should be built (e.g. need to be easily commutable to key hubs of Oxford and Cambridge) .
Industrial strategy directive may establish hard targets or specific vision, which will need to be directly incorporated into infrastructure work package. Industrial
Strategy and Clusters
Clusters are a core feature of the economic geography of each place-based deal. The No. 10 directive to use a Cluster-centric framework to identify and promote regional growth will likely share objectives with place-based deals.
New road/rail networks will span breadth of corridor’s Local Authority jurisdictions.
•Place-based deals will establish housing need and plans/sites in concert with Local Authorities.•Housing delivery will in some cases rely on changes to governance (e.g. the need for a Joint Statutory Spatial Plan for Oxfordshire).
Planning and Governance
The Government’s preference for governance along the Corridor will be a major consideration in establishing the terms of the place-based deals.
Size & location of new settlements and new local road networks (first/last mile) will impact road & rail strategy.
•Place-based deals will be key deliverer of housing objective.•Potential for housing delivery will dictate place prioritisation .
Input from Local Authorities, collected during place-based deals will inform strategy towards infrastructure need/ambition.
LVC mechanisms that government is willing to devolve may form key part of deals with areas (e.g. Oxfordshire have asked for this) .
Place-basedDeals
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Any Questions
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Infrastructure interdependencies–
a systematic literature reviewWarren Greig
Cranfield University
ENCORE NetworkInterdependencies Workshop25 January 2018
© Cranfield University 2018
www.cranfield.ac.uk/som
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Outline
I will:
- Describe the structure of the review, which is a work in progress.
- Focus on key, informative papers:
These capture important themes in understanding types of interdependencies and ways of modelling and simulating them.
© Cranfield University 2018
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Plan
• Structure of the SLR
• Description of SLR steps
• Findings – Key readings and themes
• Further development, synthesis and research opportunities
© Cranfield University 2018
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Systematising the review
• Based on guidelines including Gough et al 2012, Petticrew and Roberts 2006.
• First step is to formulate a research question
• In order to design search strings and conduct valid searches
• Then come mapping, screening and coding studies, followed by synthesis
• Used EPPI-Reviewer Systematic Review software for conducting the review
Gough, D., Oliver, S., & Thomas, J. (2012). An introduction to systematic reviews. London: Sage.Petticrew, M., & Roberts, H. (2006). Systematic Reviews in the Social Sciences: A Practical Guide. Blackwell Publishing.
© Cranfield University 2018
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Guiding question
How have infrastructure interdependencies been defined and modelled in the literature?
© Cranfield University 2018
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Searching for relevant items
• Need to search for ‘interdependencies’ and synonymous terms
• As well as searching for models and frameworks of understanding
• While keeping the search relevant to the infrastructure sectors of interest – for us, these were energy, transport, telecommunications, waste and water.
© Cranfield University 2018
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Quick definition: Interdependency
• Rinaldi 2004:
“An interdependency is a bidirectional relationship between infrastructures through which the state of each infrastructure is influenced by or correlated to the state of the other”
© Cranfield University 2018
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Quick definitions: Infrastructure
• From Saidi et al 2018 (Drawing on Allen, 1999):
“systems that organise and manage complex systems of flows, movement and exchange”
• Or ‘critical infrastructures’, from Rinaldi 2004 (Drawing from the USA Patriot Act, Public Law 107-56, October 26, 2001):
… “systems and assets, whether physical or virtual, so vital to the United States* that the incapacity or destruction of such systems and assets would have a debilitating impact on security, national economic security, national public health or safety, or any combination of those matters”
*Of course, here replace ‘United States’ with the UK or another country of your choice!
© Cranfield University 2018
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Conducting the search
• A combined strategy – using targeted search strings, feedback from peers and ‘snowballing strategy’
• Used Web of Science for searches due to coverage of engineering and technology sectors
• Search results saved as .ris files and uploaded to EPPI-Reviewer for screening and coding
© Cranfield University 2018
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Search strings
Refined in stages- By topic- By inclusion/exclusion of fields- In consultation with Information Specialist
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Flow diagram
Search database
(WoS)
Output –data
retrieved(1451 items)
Title and abstract
screeningExclude Include
(350 items)
Include(70 items)
ExcludeFull text
screening
Included documents
Descriptive data extraction
Descriptive coding
Thematic and emergent coding
SynthesisSLR
Duplicate removal
(ca. 40 items)
Start
1411 items were screened based on their Titles and Abstracts.
70 were found to be relevant to our question
350 made it to the ‘second round’ of
screening based on the full text
versions of the documents.
End© Cranfield University 2018
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Key papers for this presentation
• Rinaldi Steven M, Peerenboom James P, and Kelly Terrence K. (2001). Identifying, understanding, and analyzing critical infrastructure interdependencies. IEEE Control Systems Magazine, 21(6), pp.11-25.
• Rinaldi Steven M. (2004). Modeling and simulating critical infrastructures and their interdependencies. In: Proceedings of the 37th Hawaii International Conference on System Sciences - 2004 pp.1-8. Available at: files/121/Rinaldi - 2004 - Modeling and simulating critical infrastructures a.pdf files/99/1265180.html.
• Pederson P, Dudenhoeffer D, Hartley S, and Permann M. (2006). Critical Infrastructure Interdependency Modeling: A survey of US and international research. Prepared for the Technical Support Working Group Under Work For Others Agreement, DOE Idaho Operations Office (August), pp1-126.
• Ouyang Min. (2014). Review on modeling and simulation of interdependent critical infrastructure systems. Reliability Engineering & System Safety, 121, pp.43-60.
• Saidi Saeid, Kattan Lina, Jayasinghe Poornima, Hettiaratchi Patrick, and Taron Joshua. (2018 ). Integrated infrastructure systems—A review. Sustainable Cities and Society, 36, pp.1-11.
© Cranfield University 2018
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Classic interdependency typology: Rinaldi 2001
Types of interdependencies : Logical, Geographic, Cyber, Physical
Physical: Two infrastructures are physically dependent if the state of each depends on the material output(s) of the other. Physical interdependencies arise from physical linkages or connections among elements of the infrastructures.
Cyber: An infrastructure has a cyber interdependency if its state depends on information transmitted through the information infrastructure. The computerization and automation of modern infrastructures and widespread use of supervisory control and data acquisition (SCADA) systems have led to pervasive cyber interdependencies.
Logical: Two infrastructures and logically interdependent of the state of each depends upon the state of the other via some mechanism that is not a physical, cyber or geographic connection. For example, various policy, legal or regulatory regimes can give rise to logical linkage among two or more infrastructures.
Geographic: Infrastructures are geographically interdependent if a local environmental event can create state changes in all of them. This implies close spatial proximity of elements of different infrastructures, such as collocated elements of different infrastructures in a common right-of-way.
© Cranfield University 2018
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Illustration of interdependent Chains of influence and nth-order effects
From Rinaldi, Peerenboom and Kelly 2001© Cranfield University 2018
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Factors affecting interdependency analysis: Rinaldi 2004
• Time scales
• Geographic scales
• Cascading and higher order effects
• Social/psychological elements
• Operational procedures
• Business policies
• Restoration and recovery policies
• Government regulatory, legal, policy regimes
• Stakeholder concerns
© Cranfield University 2018
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Activities for protecting critical infrastructures (USA): Rinaldi 2004
• Integrate modelling, simulation and analysis
• Develop long and short term economic models re effects of terror attacks
• Develop critical node/chokepoint and interdependency analysis capabilities
• Model interdependencies among sectors with respect to conflicts between sector alert and warning procedures and actions
• Conduct integrated risk modelling of cyber and physical threats, vulnerabilities and consequences
• Develop models to improve information integration
© Cranfield University 2018
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Modelling interdependencies 1: Rinaldi 2004
6 general modelling/simulation approaches:
1. Aggregate supply and demand tools
2. Dynamic simulations
3. Agent-based models
4. Physics-based models
5. Population mobility models
6. Leontief Input-Output models
© Cranfield University 2018
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Modelling interdependencies 2: Pederson et al 2006
• Report attempts to provide a ‘reference framework’ based on survey of available tools.
• Report (126 pages) is notable for description of individual methodologies and the research groups involved with them.
• Provides informative tables detailing the modelling approaches, categorised by infrastructures, modelling/simulation techniques, integrated vs coupled models, hardware/software requirements (for running programmes), intended users and maturity levels (of development of programmes). Separate tabulated notes also provide more information on the programmes.
© Cranfield University 2018
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Summaries and descriptions of modelling approaches Pederson et al. 2006
© Cranfield University 2018
Subsample – table of modelling approaches
Brief tabulated notes to supplement the first
table
Bulk of report consists of more detailed notes on each
program/approach
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Interdependency typology
• Different (expanded) typology:
5 types: Physical, informational, geospatial, policy/procedural, societal.
Type Explanation
Physical Physical inter-reliance between different components
Informational Informational or control requirement between components, e.g. relianceof managing process on control systems
Geospatial Relationship due to proximity of components
Policy/procedural Policy or procedure where event or state changes to one component have effect on another
Societal Effect component event has on societal factors e.g. attitudes, anxiety, cultural changes
Pederson et al. 2006 expanded interdependency typology
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Recommendations: Pederson et al. 2006
•Authors note that there is ‘No cross program working group’ for working on critical infrastructure interdependencies.
•Recommend that such work take place at national or international level, i.e. formal/informal working group with central focus on infrastructure interdependency.
© Cranfield University 2018
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Ouyang 2014
• Comprehensive review of interdependency types and modelling/simulation approaches (including ‘review-of-reviews’)
• Provides a comparative perspective on modelling approaches using ‘resilience’ as an organising concept
• Identifies 6 modelling and simulation frameworks:
1. Empirical approaches
2. Agent-based approaches
3. System dynamics based approaches
4. Economic theory based approaches
5. Network based approaches
6. Other approaches
© Cranfield University 2018
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A summary of interdependency types in Ouyang 2014
Authors Interdependency types Definitions
Rinaldi et al. PhysicalCyberGeographicLogical
The state of one infrastructure system is dependent on the material output(s) of another infrastructure systemThe state of one infrastructure system depends on information transmitted through the information infrastructureA local environmental event can create state changes in two or more infrastructure systemsThe state of on infrastructure system depends on the state of others via a mechanism that is not physical, cyber or geographic
Zimmerman FunctionalSpatial
The operation of one infrastructure system is necessary for the operation of another infrastructure systemIt refers to proximity between infrastructure systems
Dudenhoeffer et al. PhysicalGeospatialPolicyInformational
There are direct linkages between infrastructure systems from a supply/consumption/production relationshipThere is co-location of infrastructure components within the same footprintThere is a binding of infrastructure components due to policy or high level decisionsThere is a binding or reliance on information flow between infrastructure systems
Wallace et al. Input
MutualShared
Exclusive ir (XOR)
The infrastructure systems require as input one or more services from another infrastructure system in order to provide some other serviceAt least one of the activities of each infrastructure system is dependent upon each of the other infrastructure systemsSome physical components or activities of the infrastructure systems used in providing the services are ahared with one or more other infrastructure systemsOnly one of two or more services can be provided by an infrastructure system, where XOR can occur within a single infrastructure system or among two or more systemsComponents of two or more systems are situated within a prescribed geographical region
Zhang and Peeta Functional
Physical
Budgetary
Market and economic
The functioning of one system requires inputs from another system, or can be substituted, to a certain extent, by the other systemInfrastructure systems are coupled through shared physical attributes, so that a strong linkage exists when infrastructure systems share flow right of way, leading to joint capacity constraintsInfrastructure systems involve some level of public financing, especially under a centrally-controlled economy or during disaster recoveryInfrastructure systems interact with each other in the same economic system or serve the same end users who determine the final demand for each commodity/service subject to budget constraints, or are in the shared regulatory environment where the government agencies may control and impact the individual systems through policy, legislation or financial means such as taxation or investment
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Which type? Ouyang 2014
Argues that Rinaldi’s typology is the most self-contained, based on a classification exercise for a number of real-life infrastructure interdependency examples.
© Cranfield University 2018
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Modelling/simulation frameworks compared: Ouyang 2014
© Cranfield University 2018
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Strategies for improving resilience: Ouyang 2014
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Saidi et al. 2018
• Discuss interdependencies in the context of trying to develop an account of ‘integrated infrastructure systems’
• Emphasise interdependency types and definitions, complex network abstractions and differen modelling and simulation techniques. Emphasis on networks and particularly ‘multi-layered networks’.
• Present an ‘infrastructure interdependency matrix’ to illustrate mapping of implementation, utilisation and integration/lack of integration among infrastructure systems.
• Argue that most modelling focuses on the short term an extreme events, and that longer term scenario and policy planning efforts are needed
© Cranfield University 2018
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Illustration of integrated, multi-layered network of interdependencies between (civil) sectors: Saidi 2018
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Scale of integration: Saidi 2018
• The interdependency matrix on the following pages includes literature with real-life case studies or that discuss practical applications of infrastructure systems.
• The table includes civil, social and ecological environments, methods used, focus of studies and relative scales of integration, as follows:
1. No integration within or among civil infrastructure systems
2. High level integration within one civil infrastructure systems
3. Detailed level integration within a single civil infrastructure systems
4. High level integration within multiple civil infrastructure systems
5. Detailed level integration within multiple civil infrastructure systems
© Cranfield University 2018
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Interdependency Matrix: Saidi et al 2018
© Cranfield University 2018
Lists 23 studies involving civil infrastructure
Organised by:
- Author and year- Civil entities (transport, energy, waternwaste, telecom,)- Ecology (urban form, land, climate)- Social structures (economic system, community)- Scale of integration- Method used- Focus of study
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Calls for further research: Saidi et al 2018
•Need for longer-term models e.g. scenario planning
•A call for more social and behavioural models to be included – e.g. looking at behavioural trends, preferences, perceptions and responses to infrastructure. Would add to complexity of scenarios, but represents an essential component of understanding.
© Cranfield University 2018
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Discussion
•The review papers mentioned summarise interdependency research effectively, as well as discussing outstanding issues
•More integration is needed, as well as cross-party working groups –cross-sector, nationally and internationally
•There are systemic elements that have not been integrated into models or conceptualised within interdependencies effectively, such as the social and behavioural levels – hopefully we will discuss aspects of these in our workshop!
© Cranfield University 2018