EcoService Models Library (ESML)

Compare EMs

EM Variables by Variable Role

One quick way to compare ecological models (EMs) is by comparing their variables. Predictor variables show what kinds of influences a model is able to account for, and what kinds of data it requires. Response variables show what information a model is capable of estimating.

This first comparison shows the names (and units) of each EM’s variables, side-by-side, sorted by variable role. Variable roles in ESML are as follows:

Predictor Variables
- Time- or Space-Varying Variables
- Constants and Parameters
Intermediate (Computed) Variables
Response Variables
- Computed Response Variables
- Measured Response Variables

EM Variables by Category

A second way to use variables to compare EMs is by focusing on the kind of information each variable represents. The top-level categories in the ESML Variable Classification Hierarchy are as follows:

Policy Regarding Use or Management of Ecosystem Resources
Land Surface (or Water Body Bed) Cover, Use or Substrate
Human Demographic Data
Human-Produced Stressor or Enhancer of Ecosystem Goods and Services Production
Ecosystem Attributes and Potential Supply of Ecosystem Goods and Services
Non-monetary Indicators of Human Demand, Use or Benefit of Ecosystem Goods and Services
Monetary Values

Besides understanding model similarities, sorting the variables for each EM by these 7 categories makes it easier to see if the compared models can be linked using similar variables. For example, if one model estimates an ecosystem attribute (in Category 5), such as water clarity, as a response variable, and a second model uses a similar attribute (also in Category 5) as a predictor of recreational use, the two models can potentially be used in tandem. This comparison makes it easier to spot potential model linkages.

All EM Descriptors

This selection allows a more detailed comparison of EMs by model characteristics other than their variables. The 50-or-so EM descriptors for each model are presented, side-by-side, in the following categories:

EM Identity and Description
EM Modeling Approach
EM Locations, Environments, Ecology
EM Ecosystem Goods and Services (EGS) potentially modeled, by classification system

EM Descriptors by Modeling Concepts

This feature guides the user through the use of the following seven concepts for comparing and selecting EMs:

Conceptual Model
Modeling Objective
Modeling Context
Potential for Model Linkage
Feasibility of Model Use
Model Certainty
Model Structural Information

Though presented separately, these concepts are interdependent, and information presented under one concept may have relevance to other concepts as well.

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Comparing:

EM-92
EM-327
EM-627

Add EM to Compare:

EM Identity and Description

EM Identification

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
EM Short Name em.detail.shortNameHelp ?	Runoff potential of pesticides, Europe	ARIES sediment regulation, Puget Sound Region, USA	N removal by wetland restoration, Midwest, USA
EM Full Name em.detail.fullNameHelp ?	Runoff potential of pesticides, Europe	ARIES (Artificial Intelligence for Ecosystem Services) Sediment Regulation for Reservoirs, Puget Sound Region, Washington, USA	Nitrate removal by potential wetland restoration, Mississippi River subbasins, USA
EM Source or Collection em.detail.emSourceOrCollectionHelp ?	None	ARIES	None
EM Source Document ID	254	302	370 ? Comment: Final project report to U.S. Department of Agriculture; Project number: IOW06682. December 2006.
Document Author em.detail.documentAuthorHelp ?	Schriever, C. A., and Liess, M.	Bagstad, K.J., Villa, F., Batker, D., Harrison-Cox, J., Voigt, B., and Johnson, G.W.	Crumpton, W. G., G. A. Stenback, B. A. Miller, and M. J. Helmers
Document Year em.detail.documentYearHelp ?	2007	2014	2006
Document Title em.detail.sourceIdHelp ?	Mapping ecological risk of agricultural pesticide runoff	From theoretical to actual ecosystem services: mapping beneficiaries and spatial flows in ecosystem service assessments	Potential benefits of wetland filters for tile drainage systems: Impact on nitrate loads to Mississippi River subbasins
Document Status em.detail.statusCategoryHelp ?	Peer reviewed and published	Peer reviewed and published	Neither peer reviewed nor published (explain in Comment)
Comments on Status em.detail.commentsOnStatusHelp ?	Published journal manuscript	Published journal manuscript	Published report

Software and Access

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
EM Software Access info Exit em.detail.modelAccessInformationHelp ?	Not applicable	http://aries.integratedmodelling.org/	Not applicable
Contact Name em.detail.contactNameHelp ?	Carola Alexandra Schriever	Ken Bagstad	William G. Crumpton
Contact Address	Helmholtz Centre for Environmental Research - UFZ, Department of System Ecotoxicology, Permoserstrasse 15, 04318 Leipzig, Germany	Geosciences and Environmental Change Science Center, US Geological Survey	Dept. of Ecology, Evolution and Organismal Biology, Iowa State University, Ames, IA 50011
Contact Email	carola.schriever@ufz.de	kjbagstad@usgs.gov	crumpton@iastate.edu

EM Description

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
Summary Description em.detail.summaryDescriptionHelp ?	ABSTRACT: "The approach is based on the runoff potential (RP) of stream sites, by a spatially explicit calculation based on pesticide use, precipitation, topography, land use and soil characteristics in the near-stream environment. The underlying simplified model complies with the limited availability and resolution of data at larger scales." AUTHOR'S DESCRIPTION: "The RP is based on a mathematical model that describes runoff losses of a compound with generalized properties and which was developed from a proposal by the Organisation for Economic Co-operation and Development (OECD) for estimating dissolved runoff inputs of a pesticide into surface waters (OECD, 1998)...The runoff model underlying RP calculates the dissolved amount of a generic substance that was applied in the near environment of a stream site and that is expected to reach the stream site during one rainfall event. The dissolved amount results from a single application in the near-stream environment (i.e., a two-sided 100-m stream corridor extending for 1500 m upstream of the site) and is the amount of applied substance in the designated corridor reduced due to the influence of the site-specific key environmental factors precipitation, soil characteristics, topography, and plant interception."	ABSTRACT: "...new modeling approaches that map and quantify service-specific sources (ecosystem capacity to provide a service), sinks (biophysical or anthropogenic features that deplete or alter service flows), users (user locations and level of demand), and spatial flows can provide a more complete understanding of ecosystem services. Through a case study in Puget Sound, Washington State, USA, we quantify and differentiate between the theoretical or in situ provision of services, i.e., ecosystems’ capacity to supply services, and their actual provision when accounting for the location of beneficiaries and the spatial connections that mediate service flows between people and ecosystems... Using the ARtificial Intelligence for Ecosystem Services (ARIES) methodology we map service supply, demand, and flow, extending on simpler approaches used by past studies to map service provision and use." AUTHOR'S NOTE: "We mapped sediment regulation as the location of sediment sinks (depositional areas in floodplains), which can absorb sediment transported by hydrologic flows from upstream sources (erosionprone areas) prior to reaching users. In this case the benefit of avoided sedimentation is provided to 29 major reservoirs. Avoided sedimentation helps maintain the ability of reservoirs to provide benefits including hydroelectric power generation, flood control, recreation, and water supply to beneficiaries through the region. Avoided reservoir sedimentation likely helps to protect each of these benefits in different ways, i.e., increased turbidity or the loss of reservoir storage capacity may have a greater impact on some provision of some benefit types than others. For our purposes we ended the modeling and mapping exercise at the reservoirs. Reservoir sedimentation reduces their storage capacity, typically decreasing their ability to provide these benefits without costly dredging. We thus used a probabilistic Bayesian model of soil erosion incorporating vegetation, soils, and rainfall influences and calibrated using regional data from coarser scale and/or RUSLE derived erosion models (Bagstad et al. 2011). We probabilistically modeled sediment deposition in floodplains using data for floodplain vegetation, floodplain width, and stream gradient, which can influence rates of deposition. We calculated the ratio of actual to theoretical sediment regulation using the aggregated sink values upstream of reservoirs in the Puget Sound region, divided by aggregated theoretical sink values for the entire landscape."	ABSTRACT: "The primary objective of this project was to estimate the nitrate reduction that could be achieved using restored wetlands as nitrogen sinks in tile-drained regions of the upper Mississippi River (UMR) and Ohio River basins. This report provides an assessment of nitrate concentrations and loads across the UMR and Ohio River basins and the mass reduction of nitrate loading that could be achieved using wetlands to intercept nonpoint source nitrate loads. Nitrate concentration and stream discharge data were used to calculate stream nitrate loading and annual flow-weighted average (FWA) nitrate concentrations and to develop a model of FWA nitrate concentration based on land use. Land use accounts for 90% of the variation among stations in long term FWA nitrate concentrations and was used to estimate FWA nitrate concentrations for a 100 ha grid across the UMR and Ohio River basins. Annual water yield for grid cells was estimated by interpolating over selected USGS monitoring station water yields across the UMR and Ohio River basins. For 1990 to 1999, mass nitrate export from each grid area was estimated as the product of the FWA nitrate concentration, water yield and grid area. To estimate potential nitrate removal by wetlands across the same grid area, mass balance simulations were used to estimate percent nitrate reduction for hypothetical wetland sites distributed across the UMR and Ohio River basins. Nitrate reduction was estimated using a temperature dependent, area-based, first order model. Model inputs included local temperature from the National Climatic Data Center and water yield estimated from USGS stream flow data. Results were used to develop a nonlinear model for percent nitrate removal as a function of hydraulic loading rate (HLR) and temperature. Mass nitrate removal for potential wetland restorations distributed across the UMR and Ohio River basin was estimated based on the expected mass load and the predicted percent removal. Similar functions explained most of the variability in per cent and mass removal reported for field scale experimental wetlands in the UMR and Ohio River basins. Results suggest that a 30% reduction in nitrate load from the UMR and Ohio River basins could be achieved using 210,000-450,000 ha of wetlands targeted on the highest nitrate contributing areas." AUTHOR'S DESCRIPTION: "Percent nitrate removal was estimated based on HLR functions (Figure 19) spanning a 3 fold range in loss rate coefficient (Crumpton 2001) and encompassing the observed performance reported for wetlands in the UMR and Ohio River basins (Table 2, Figure 7). The nitrate load was multiplied by the expected percent nitrate removal to estimate the mass removal. This procedure was repeated for each restoration scenario each year in the simulation period (1990 to 1999)… for a scenario with a wetland/watershed area ratio of 2%. These results are based on the assumption that the FWA nitrate concentration versus percent row crop r
Specific Policy or Decision Context Cited em.detail.policyDecisionContextHelp ?	European Commission Water Framework Directive (WFD, Directive 2000/60/EC)	None identified	None identified
Biophysical Context	Not applicable	No additional description provided	No additional description provided
EM Scenario Drivers em.detail.scenarioDriverHelp ?	No scenarios presented	No scenarios presented	More conservative, average and less conservative nitrate loss rate

EM Relationship to Other EMs or Applications

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
Method Only, Application of Method or Model Run em.detail.methodOrAppHelp ?	Method + Application	Method + Application	Method + Application (multiple runs exist)
New or Pre-existing EM? em.detail.newOrExistHelp ?	New or revised model	New or revised model	New or revised model

Related EMs (for example, other versions or derivations of this EM) described in ESML

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
Document ID for related EM em.detail.relatedEmDocumentIdHelp ?	Doc-255 \| Doc-256 \| Doc-257	Doc-303 \| Doc-305	None
EM ID for related EM em.detail.relatedEmEmIdHelp ?	None	None	None

EM Modeling Approach

EM Relationship to Time

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
EM Temporal Extent em.detail.tempExtentHelp ?	2000	1971-2005	1973-1999
EM Time Dependence em.detail.timeDependencyHelp ?	time-dependent	time-stationary	time-dependent
EM Time Reference (Future/Past) em.detail.futurePastHelp ?	future time	Not applicable	future time
EM Time Continuity em.detail.continueDiscreteHelp ?	discrete	Not applicable	discrete
EM Temporal Grain Size Value em.detail.tempGrainSizeHelp ?	1	Not applicable	1
EM Temporal Grain Size Unit em.detail.tempGrainSizeUnitHelp ?	Day	Not applicable	Day

EM Spatial Extent

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
Bounding Type em.detail.boundingTypeHelp ?	Geopolitical	Physiographic or ecological	Watershed/Catchment/HUC
Spatial Extent Name em.detail.extentNameHelp ?	EU-15	Puget Sound Region	Upper Mississippi River and Ohio River basins
Spatial Extent Area (Magnitude) em.detail.extentAreaHelp ?	>1,000,000 km^2	10,000-100,000 km^2	>1,000,000 km^2

Spatial Distribution of Computations

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
EM Spatial Distribution em.detail.distributeLumpHelp ?	spatially distributed (in at least some cases)	spatially distributed (in at least some cases)	spatially distributed (in at least some cases)
Spatial Grain Type em.detail.spGrainTypeHelp ?	area, for pixel or radial feature	area, for pixel or radial feature	area, for pixel or radial feature
Spatial Grain Size em.detail.spGrainSizeHelp ?	10 km x 10 km	200m x 200m	1 km2

EM Structure and Computation Approach

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
EM Computational Approach em.detail.emComputationalApproachHelp ?	Analytic	Analytic	Numeric
EM Determinism em.detail.deterStochHelp ?	deterministic	deterministic	deterministic
Statistical Estimation of EM em.detail.statisticalEstimationHelp ?	None	Bayesian statistics	Conventional (frequentist) statistics

Model Checking Procedures Used

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
Model Calibration Reported? em.detail.calibrationHelp ?	No	Yes	No
Model Goodness of Fit Reported? em.detail.goodnessFitHelp ?	No	No	No
Goodness of Fit (metric\| value \| unit) em.detail.goodnessFitValuesHelp ?	None	None	None
Model Operational Validation Reported? em.detail.validationHelp ?	No	No	No ? Comment: However, agreement of submodel and intermediate components; annual discharge (R2=0.79), and nitrate-N load (R2=0.74), based on GIS land use were determined in comparison with USGS NASQAN data.
Model Uncertainty Analysis Reported? em.detail.uncertaintyAnalysisHelp ?	Yes	No	No
Model Sensitivity Analysis Reported? em.detail.sensAnalysisHelp ?	Yes	No	No
Model Sensitivity Analysis Include Interactions? em.detail.interactionConsiderHelp ?	No	Not applicable	Not applicable

EM Locations, Environments, Ecology

Location of EM Application

Terrestrial location (Classification hierarchy: Continent > Country > U.S. State [United States only])

EM-92	EM-327	EM-627
Europe United Kingdom Portugal Spain Greece Austria Netherlands Sweden Belgium Ireland Luxembourg Finland Denmark Italy France Germany	North America United States	North America United States North Carolina New York Indiana Tennessee Kentucky South Dakota Minnesota Pennsylvania Virgina West Virginia Iowa Illinois Missouri Ohio Maryland Wisconsin

Marine location (Classification hierarchy: Realm > Region > Province > Ecoregion)

EM-92	EM-327	EM-627
None	None	None

Centroid Lat/Long (Decimal Degree)

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
Centroid Latitude em.detail.ddLatHelp ?	50.01	48	40.6
Centroid Longitude em.detail.ddLongHelp ?	4.67	-123	-88.4
Centroid Datum em.detail.datumHelp ?	WGS84	WGS84	WGS84
Centroid Coordinates Status em.detail.coordinateStatusHelp ?	Estimated	Estimated	Estimated

Environments and Scales Modeled

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
EM Environmental Sub-Class em.detail.emEnvironmentalSubclassHelp ?	Rivers and Streams \| Forests \| Agroecosystems \| Grasslands \| Scrubland/Shrubland	Rivers and Streams \| Lakes and Ponds \| Near Coastal Marine and Estuarine \| Terrestrial Environment (sub-classes not fully specified)	Rivers and Streams \| Inland Wetlands \| Agroecosystems
Specific Environment Type em.detail.specificEnvTypeHelp ?	Arable lands in near-stream environments	Terrestrial environment surrounding a large estuary	Agroecosystems and associated drainage and wetlands
EM Ecological Scale em.detail.ecoScaleHelp ?	Ecological scale is finer than that of the Environmental Sub-class	Ecological scale corresponds to the Environmental Sub-class	Ecological scale corresponds to the Environmental Sub-class

Scale and taxa of organisms modeled

Scale of differentiation of organisms modeled

EM ID em.detail.idHelp ?	EM-92	EM-327	EM-627
EM Organismal Scale em.detail.orgScaleHelp ?	Not applicable	Not applicable	Not applicable

Taxonomic level and name of organisms or groups identified

EM-92	EM-327	EM-627
None Available	None Available	None Available

EnviroAtlas URL

EM-92	EM-327	EM-627
Average Annual Precipitation, Stream Length Impaired by Pesticides, The Watershed Boundary Dataset (WBD), Hectares of Vegetable Crops	GAP Ecological Systems, Average Annual Precipitation, Waterbody area	GAP Ecological Systems, National Hydrography Dataset Plus (NHD PlusV2), Average Annual Precipitation, Total Annual Nitrogen Deposition

EM Ecosystem Goods and Services (EGS) potentially modeled, by classification system

CICES v 4.3 - Common International Classification of Ecosystem Services (Section > Division > Group > Class)

EM-92	EM-327	EM-627
None	[Ecosystem] Regulation & Maintenance Mediation of flows Mass flows Buffering and attenuation of mass flows	[Ecosystem] Regulation & Maintenance Maintenance of physical, chemical, biological conditions Water conditions Chemical condition of freshwaters Mediation of waste, toxics and other nuisances Mediation by ecosystems Filtration/sequestration/storage/accumulation by ecosystems

<a target="_blank" rel="noopener noreferrer" href="https://www.epa.gov/eco-research/national-ecosystem-services-classification-system-nescs-plus">National Ecosystem Services Classification System (NESCS) Plus</a>

(Environmental Subclass > Ecological End-Product (EEP) > EEP Subclass > EEP Modifier)

EM-92	EM-327	EM-627
None	None	Rivers and Streams (111) Water (3) Liquid water Quality Indicator