introduction to integrated modeling - waterways
TRANSCRIPT
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Introduction tointegrated modeling
Terminology, approaches and toolsDr. Lorenzo Benedetti, Waterways (HR)
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Acknowledgements
• Peter Bach(Monash University, Australia)
• Bob Crabtree(WRc, UK)
• Elliot Gill(CH2M, UK)
• Dirk Muschalla(TU Graz, Austria)
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Content
• Introduction
• Integrated Urban Water Systems (IUWS) modeling in general
• Integrated Urban Drainage Models (IUDM) in particular
• Conclusions
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Introduction
• Models
• Integration
• Integrated modeling
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“...Model /ˈmɒd(ə)l/
(1) a thing used as an example to follow or imitate
(2) a simplified description, especially a mathematical one, of a system or
process, to assist calculations and predictions
(3) a person employed to display clothes by wearing them
...” (Source: Oxford Dictionary)
A few key definitions
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...from the literature...
“A model is an abstract description of reality, which is
developed in order to understand better some defined
aspects of the system to be analyzed or designed.”
– W. GUJER, 2008 , SPRINGER
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Science
Economics Curiosity
Design
Why use models in engineering?
Epistemological devices
Co
st-e
ffectiv
e
Rigorous
Cool &Geeky!
Assess Uncertainty
Confidence
EXPLOREIdeas Testing
Qu
anti
tati
veV
irtual Lab
orato
ry
“Wicked Problems”
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MODEL
Problem DefinitionAims & Objectives
Case Study & ScenariosParameters & Data
OUTPUTSPredictions
AnalysisInterpretation
Calibration/Optimization/Training
a “black box”
REFINEMENT, ITERATION, RE-EVALUATION
Modelling – A “Not-So-Complex” Illustration
SETUP & INPUTS
!!
Users
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“...Integration /ɪntɪˈgreɪʃ(ə)n/
the linking and coordination of various parts or aspects
...” (Source: Oxford Dictionary)
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Examples of ‘Integration’
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Our journey begins around the late 1970s
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Our journey begins around the late 1970s
Sewer Network
Wastewater Treatment Plant
Receiving Water Body
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and since then...
20022nd
INTERURBA Conference
2015Present
Day
First mentions
of integration
1970s
Emerging interest in
understanding component interactions
1980s 1990s
2000 EU Water
Framework Directive
2000s
~ 2006IUWM
paradigm emerges
FieldworkFirst concepts
Increased Awareness
Model Advancements
Water Quality Focus
I.M. Guidelines for Urban Drainage
Systems
Inter-disciplinary Integration
Real-time Control
Legislation ChangesSoftwares Emerge
New Types of Integration
New Modelling Technologies
?
19931st INTERURBA
Conference
Time
20133rd
INTERURBA Conference
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So what is “Integrated Modelling”?
“...modelling of interactions between two or more urban water system components...”
– Rauch et al., 2002, Olsson and Jeppsson, 2006
“...ability to focus on understanding the behaviour of parts of the system with respect to the broader picture...”
– Beck, 1976
“... recognises both the positive and negative feedbacks between components and exploits these for significantly more efficient solutions...”
– Marsalek et al., 1993, Mitchell et al., 2007
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Subsystem
Subsystem
Subsystem
SubsystemSubsystem
Subsystem
Subsystem
• Positive Feedback
• Negative Feedback
• Short & Long-term Effects
• More than the Sum of Parts
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MODEL
Problem DefinitionAims & Objectives
Case Study & ScenariosParameters& Data
OUTPUTSPredictions
AnalysisInterpretation
Calibration/Optimization/Training
a “black box”
REFINEMENT, ITERATION, RE-EVALUATION
SETUP & INPUTS
!!
Users
Sub-Systems
Processes
Disciplines
“...the prerequisite to an integrated approach is the identification of the ‘‘axes and planes’’ in which integration needs to take place...”
– Rauch et al., 2005
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IUWS modeling in general
• Classification
• Issues (and dangers)
• Tools
• Ways of interfacing models
• Calibration and uncertainty
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EDSSEnvironmental Decision Support Systems
Organising Integrated Modelling in UWS
IUWSMsIntegrated urban water system models
Integrated urban water infrastructure models
Decentralised & Centralised systems
Water recyclingTotal Urban Water Cycle
(Supply & Drainage)
IUWIMs
Water Resources Allocation
IWSMsIntegrated water supply modelsIntegrated urban drainage models
IUDMs Catchment Drainage,
Runoff and Pollution
Sewer Transport
Combined Sewer Overflow
Receiving Water Body Quality
Flood Protection
Water demand patterns
Reservoir Storage-behaviour
Decentralised water sources
Water distribution network
Water treatment plant
Integrated component-based models
WWTPWater Supply System
Natural Treatment
System
Natural Water Body
Sewer Processes
ICBMs
Local/Regional Climate Model
Soil & Air Quality Models
Social Behaviour
Models
Economic Models
Energy ModelsEcological
Models
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Key Considerations
Model Structure Empirical vs. Conceptual vs. MechanisticDeterministic vs. Stochastic
Simulation Config. Sequential vs. ParallelOnline vs. Offline
Spatial Detailing Branched vs. LoopedDistributed vs. Lumped
Temporal Detailing Continuous vs. Discontinuous SimulationUniform vs. Variable Time Step
Process Nature Water Quantity (Hydrologic & Hydraulic)Water Quality (Physical, Biological, Chemical)
Computation Single Core vs. Multi-Core ProcessingSingle run vs. Optimisation vs. Monte Carlo
Software Supermodel vs. Interface vs. Hybrid
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Integronsters – ugly constructions
adapted from Voinov and Shugart (2013)
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Integronsters – skewed geometry
adapted from Voinov and Shugart (2013)
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Integronsters – mismatched scales
adapted from Voinov and Shugart (2013)
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Integronsters – overwhelming complexity
adapted from Voinov and Shugart (2013)
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Integronsters – overwhelming complexity
adapted from Voinov and Shugart (2013)
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Integronsters – confusion of tongues
adapted from Voinovand Shugart (2013)
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Tools: Some Examples
Integrated Component-Based Model (ICBM):
• Benchmark Simulation Model No. 2
(whole of wastewater treatment plant model)
IUDMs (drainage) & IWSMs (supply):
• SIMBA (IFAK), WEST (DHI)
(sewer system, wastewater treatment plant, receiving
waters in single model)
• SAMBA, RUMBA, FOXTROT
(linkage of sewer system, wastewater treatment
plant, receiving waters)
• EPANET (Rossman, 2000)
(simulation of water distribution networks
& storages)
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IUWIMs (water infrastructure):
• MUSIC (eWater)
• UrbanDeveloper (eWater)
• Aquacycle (Mitchell et al., 2001)
• MIKE URBAN, WEST (DHI)
IUWSMs (water systems): current only sparse
• Work by Fagan et al., 2010
• VIBe (Sitzenfrei et al., 2010)
• OpenMI (OpenMI Association, 2010)
• DAnCE4Water & UrbanBEATS
Tools: Some Examples
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Integration
Model 1
State Variable
Model 3
State Variable
Model 2
State Variable
I‘m providing discharge every
minute in l/s
My state variable is the flow of a non-compressible fluid with a density of
1000 kg/m³
I‘m expecting the amount of
inflowing sewage in
gallons per day
???
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Interfacing and Integration
– Methodological integration
• Data produced by one model are a meaningful input to another model
– Technical integration
• Automating data exchange between models, making them jointly executable
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Methodological Integration
Model 1 Model 2
Model 1State Variables
Model 2State Variables
Model 1State Variables
Model 2State Variables
Supermodel approach
Model 1
Model 1State Variables
Model 2
Model 2State Variables
Interface M1/M2
Interface M2/M1
Interfaces approach
(Vanrolleghem, 2005)
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Technical Integration
– Scripts
– Integration in a proprietary method
– Integration using a modelling framework based on open standards
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Sequential vs. Parallel
Catchment 1
Catchment 2
Catchment 3
Treatment 1
Treatment 2 Storage 1
River
1
2
3
4
5 6
7
t2
Sequential: “One-node-at-a-time” for entire time period
Parallel: All at once“One-time-step-at-a-time”
t1
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Define Aims & Objectives and Make initial selection of Model
Features (from Table 3)
Select relevant state variables & delineate system boundary
(level of integration e.g. IUDM)
List relevant Interactions between system components
Select existing relevant modelsfor each component
(develop if non-existent)
Select method of integration & construct integrated model
Determine Transfer Functions (conversion processes, feedbacks)
Determine calibration method & data requirements
Calibrate & Run the Model
Cross-check Results with Aims & Objectives
Ide
nti
fy/Q
uan
tify
/Ack
no
wle
dge
/Tra
ck
red
uci
ble
an
d i
rre
du
cib
le U
NC
ERTA
INTY
Re
fin
e if
ne
cess
ary
Define “verification criteria” of the integrated model
Analyse Model Outputs (according to performance and
verification criteria)
Developing Integrated Models
Aims & Objectives
Find/Make the models
String’em together
Calibrate & Run
Interpret Output
Iter
ativ
e
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Calibrating and Validating these Beasts
Three methods identified:
#1 :: calibrate the whole integrated model at once
#2 :: start upstream, then gradually move
downstream, quantity before quality
#3 :: calibrate individual models first, then
integrate them
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Calibrating and Validating these Beasts
Integrated models as “unwieldy” and “highly complex”
– a technical and logistical challenge!
Error propagation, equifinality and sometimes
unavoidable auto-correlation more pronounced with
increasing complexity
Calibration/Validation feasibility decreasing with larger
integrated models – still useful?
Overcome data limitations with semi-hypothetical case
studies and exploration
Overcome overparametrisation by using simpler
surrogate models
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Uncertainty
Types:
• Statistical (outcomes known and quantifiable)
• Scenario (outcomes known but not quantifiable)
• Qualitative (not all outcomes known nor quantifiable)
• Recognised Ignorance
Statistical received great attention (many methods to
quantify)
Scenario partly explored
Should integrated modelling field rely on classical
uncertainty estimation methods?
EU QUICS project
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IUDMs in particular
• Drivers (wet-weather effects on receiving water UPM)
• Concepts
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Effects of wet weather discharges on river quality
• Reduction in Dissolved Oxygen (DO) due to:
– Degradation of dissolved BOD & BOD attached to sediment
– Resuspension of polluted bed sediments exerting an oxygen demand
– Low DO levels in spilled storm sewage
• Rapid increase in river concentrations of:
– Ammonia, bacteria, COD, suspended sediments, heavy metals etc.
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• Magnitude of impact depends on:
– River flow (dilution)
– Chanel gradient (slope)
– Channel geometry & roughness
– In-river structures (velocity & depth)
– pH (high pH increases proportion of un-ionised ammonia for a given conc. of total ammonia)
– Temperature
– Ecology (macrophytes, algae, fish & invertabrates)
Effects of wet weather discharges on river quality
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Urban Pollution Management – a short (UK) history
“ The failure to relate overflow to river needs .......puts at hazard the
attainment of target quality for the river system (and) distorts the
correct pattern of investment in the sewerage system”
Technical Committee on Storm Overflows and the Disposal of Storm Sewage, 1970
“ We would like to have been able to recommend a Formula for overflow
setting that took account of river quality flow and use……but there are
too many unknown factors to make it workable”
Technical Committee on Storm Overflows and the Disposal of Storm Sewage, 1970
DWF = PG + I + E
CSO Setting = DWF + 1360P + 2E litres/day
Dry weather flow
P (population) G (water consumption)
Infiltration
E (industrial flow)
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6,500 WWTP
25,000 CSOs
In 1990 8,000 CSOs = significant pollution
50% of all bathing waters
320 inland waterbodies
“We consider that there is an urgent need for a study to be made of the
effect of intermittent discharges of storm sewage on streams”.
Royal Commission on Environmental Pollution 16th Report 1992
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Urban Pollution Management Manual (I) 1995, (II) 1998, (III) 2013
“The management of wastewater
discharges from sewerage and
sewage treatment systems under wet
weather conditions such that the
requirements of the receiving water
are met in a cost-effective way”
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Environmental Quality Standard (EQS) –Environmental Quality Objective (EQO) principle
• EQOs are used to specify the desired use of the water body (e.g. Good Ecological Status)
• The performance of individual discharges (e.g. CSOs & WRRF%) should be set by reference to the ability of receiving waters to accommodate contaminants without detriment to the desired use of the water (the EQO)
• EQSs are the concentrations of target substances (e.g. dissolved oxygen) which if achieved enable the desired use to be protected.
• EQSs can be used in monitoring to judge water quality
• EQSs can be used in planning and design to test whether a proposed infrastructure configuration will deliver an EQO
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Why special standards are needed for ‘wet weather’
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UPM2 Fundamental Intermittent Standards DO
• 477626
• Other values for cyprinids
• Same concept for NH3
• Cross-corrections DO-NH3
≡ USEPA warm water 1 day
value
≡ British Columbia (Canada) MoE instantaneous min value
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Are UPM2 FIS consistent with needs of Water Framework Directive (2000/60/EC) (WFD)?
New data on:
– sensitivity of aquatic organisms to dissolved oxygen and/or unionised ammonia (1992 onwards)
– repeated exposure to pulses of unionised ammonia
“the UPM2 FIS provide protection against both short-term mortality and longer term effects on the physiology, growth and reproduction of the fish”
“meeting the UPM2 FIS should ensure that the good
quality status of a water body is not compromised” https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/291495/LIT_7372_bec80a.pdf
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UPM modelling approach (IUDM)
Prepare model of urban drainage systemCollection | Treatment |River | Storm water
Simulate River Water Quality
Is wet weather regime
compliant with EQS ?
Model improved systemStorage | Conveyance |
Green Infrastructure
No
Yes
Urban Drainage System not inconsistent with EQO
Sensitivity testing
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Conclusions (UPM)
• UPM FIS are design criteria – not a classification system
• Developed for use in modelling studies to check that ‘wet weather’ regime is consistent with delivering a EQO
• Re-evaluation in 2012 confirmed that using FIS design criteria for wet weather impacts (CSOs, WWTP, storm water) protects Good Ecological Status
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Conclusions (UPM)
• Track record
– UPM used as basis of £3.5 billion programme to ‘improve’ c. 8,000 UK CSOs since 1995
– Customised UPM FIS used to support development of £4 billion Thames Tideway Tunnel programme (20km 8m dia. tunnel intercepting 30+ CSOs on tidal River Thames)
• Regulatory policy
– UK regulators fully endorse use of UPM approach
– FIS are science based but usage is site specific
– Regulator reserves right to vary values
– Partnership approach in ‘initial planning’ stage
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IUDMs
Limited to urban wastewater systemdetailed vs. simplified
Catchment/sewer
WWTP
River
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Natural Runoff
Diffuse Sources
Infiltration Stormwater Treatment
Wastewater Treatment
Sewer
System Boundary
Interaction With
Groundwater
CSO
Urban Catchment
SSO
System boundaries
(Solvi, 2007)
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Catchment/sewer – detailed
High level of spatial detail (down to 20 cm diameters and many small catchments)
Can have up to 1000s network elements
Use of some version of the hydrodynamic Saint-Venant equations (PDE: 1-D, 2-D, 3-D)
Needed if velocity, water levels are important
Rainfall/runoff same models as simplified
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Catchment/sewer – detailed
Long tradition and wide diffusion of detailed modeling
Many software tools (inside models do not change much, solvers may):
InfoWorks, MIKE URBAN, SWMM, …
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Catchment/sewer – simplified
Low level of spatial detail (down to 50-100 cm pipe diameters and lumped catchments)
Can have up to 100s network elements
Use of tanks-in-series approach (ODE)
Sufficient when flows and/or water volumes are important (water quality)
Solutions for backwater are available(Vanrolleghem et al., 2009)
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Catchment/sewer – simplified
Developed mostly in countries where regulation allows/promotes it
Model more important than software around it
KOSIM, SMUSI, MUSIC, …
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Catchment/sewer – quality
Water quality usually included (solids, pollutants) but not very reliable
Specific models for specific applications, difficult to generalize to other systems
Reaeration
Sulphide production
Methanogenesis
Chemical dosage
With more use of sensors in sewers, use of such data or derived data-driven models
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Catchment/sewer – quality
Dry weather flow relatively easy to model
Per capita flow and loads
Infiltration rate (from WRRF influent data)
Processes?
Wet-weather more difficult
Accumulation / Wash-off in catchment
Sedimentation / Resuspension in pipes and tanks
CSOs concentrations
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WRRF
Tanks-in-series
No simplification needed
Still issues with wet-weather modeling
Primary and secondary settlers
Influent fractionation
Mixing
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River – detailed
Used when velocities, water levels are important (solids transport, flooding)
Often used for water quality
Inputs are measured or from basin hydrologic models
Many software tools available:
InfoWorks, MIKExx, DUFLOW, SOBEK, …
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River – simplified
Same as for sewers
Used when quality is more important than (some details of) quantity, e.g. in SWAT et similia…
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River – quality
Wide and old use of water quality (from S&P)
Many possible processes can be included
DO-BOD, solids, C-N-P cycles, algae, eutrophication, sediment, chemical equilibria, …
Difficult to predict ecological quality
Interface can be UPM FIS
Several models currentlyused in many forms
RWQM1, QUAL2E, QUAL2K,DUFLOW, …
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Integration – OpenMI
Standard interface
It allows models to exchange data with each other
On a time step by time step basis
It is defined by a set of software interfaces that a compliant model or component must implement
www.openmi.org
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Integration – single platform
Catchment Sewer WWTP RiverCatchment Sewer WWTP River
Separate Detailed Physical Models
Calibrated + Validated Surrogate Sub-Models
Catchment Sewer WWTP River
Integrated Model
Calibrated + Validated Individually
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Integration – single platform
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Integration – software
Commercial
WEST, SIMBA
Non-commercial
City-Drain (Matlab), SYNOPSIS, …
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Conclusions
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Driving the Adoption of Integrated Models
(1) Global Change & the IUWM Paradigm
(2) Changing Legislation
(3) Diversity of Integrated Model Use
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Barriers that we still face
User-friendliness
Data Requirements
Model Complexity
UncertaintyCommunication
Legislation
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So what does the future hold?
The literature’s Key goals
More ‘now-casting’
More transparent process in using
integrated models
More interdisciplinary work
The direction of future research(?) - “Virtual Playgrounds”
encompassing the technical and non-technical
Fragmentation in practice needs to be overcome
Legislation needs to evolve more than it has
Participatory approach
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Open questions
– Can we describe all processes of interest? Do we have suitable models?
– Is the linkage of socio-economic models with hydraulic, water quality and bio-process models feasible?
– Do we have to integrate physically (detailed) models or can we answer our question also with simplified (conceptual) models?
– How to deal with the uncertainty caused by the model structure (detailed versus simplified model), the interfaces (conversion of state variables), spatial and temporal integration?
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Open questions
– Is it realistic to measure all the data needed for calibration of integrated models?
– Which type of issues we would like to address or what type of problems we would like to solve with integrated model? Which degree of integration and which type of models are needed for this?
– Can we sufficiently connect model predictive control or other optimisation/analysing tools with integrated models?
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Slow uptake in practice, but there is progress
(Rogers, 1962)