The Application Risk Advisory System is web‑based and provides alerts when conditions are favorable for nutrient loss to water, based on soil conditions and National Weather Service forecast models. This system enables farmers and commercial applicators to avoid applications of fertilizer and manure during conditions when the potential for loss to surface water is high.
This project will finalize HSPF watershed model construction by incorporating internal phosphorus loading in modeled lakes, run a suite of implementation scenarios and generate a GenScn project containing model output. The consultant will produce HSPF watershed models that can readily be used to provide information to support conventional parameter TMDLs. The consultant will deliver all modeling files for baseline and implementation scenarios and provide a GenScn project containing model output.
This project will improve our understanding of the sources of sediment (turbidity), and the processes which deliver sediment to river channels. This project will address a suite of emerging questions regarding contributions and causes of non-field sediment, thereby providing watershed managers with a better understanding of how to manage these sediment sources.
This project will complete spatial and temporal revisions , recalibration and validation of 7 watershed HSPF models. These fully functioning calibrated validated executable models will simulate hydrology, sediment (sand, silt, and clay), temperature, phosphorus, nitrogen, dissolved oxygen, biochemical oxygen demand, and algae at the 12-digit HUC subbasin scale (or finer).
The goal of this project is to enhance the current version of the Enhanced Expert System for Calibration of HSPF (HSPEXP+) so that it can more easily and quickly be used for hydrology calibration, water quality calibration, generate reports and graphs.
The primary goal of this project is to enhance the current version of the Expert System for Calibration of HSPF (HSPEXP+) so that it can better support hydrology calibration, water quality calibration, report and graph generation. A secondary goal of this project is to modify the Hydrological Simulation Program FORTRAN (HSPF) program so that precipitation additions to streams and lakes contain dissolved oxygen.
The primary goal of this project is to enhance the current version of the Expert System for Calibration of HSPF (HSPEXP+) so that it can be more efficiently used for QA/QC of hydrology and water quality models developed using Hydrological Simulation Program FORTRAN (HSPF) and develop input files for two receiving waterbody models.
The goal of this project is to develop a tool to generate meteorological time-series input data for Minnesota Pollution Control Agency Hydrologic Simulation Program FORTRAN (HSPF) models based on publicly available gridded meteorological products.
The primary goal of this project is to train the Minnesota Pollution Control Agency staff in Hydrologic Simulation Program FORTRAN (HSPF) model calibration of nutrients, oxygen demand, and algal processes and in MATLAB script development for model output processing and report generation. Additionally, a pilot application process will be developed to link HSPF applications to Water quality Analysis Simulation Program (WASP) to take advantage of the advanced sediment oxygen demand processes.
The goal of this project is to develop the guidance needed for water quality parameter evaluation and calibration for Hydrological Simulation Program – FORTRAN (HSPF) applications that utilize the general water quality constituent routines on the land surface to generate loadings of nutrients and organic material for input to water bodies to support dissolved oxygen (DO), nutrient, and algal simulation.
This project will continue HSPF watershed model construction beyond the initial framework development. The consultant will add representation of point source discharges to the model. The consultant will also compile flow data for the purposes of calibration and validation. Finally, an initial hydrologic calibration will be performed and submitted for approval.
The goal of this project is to extend the existing HSPF models through 2012 in the Chippewa Watershed (07020005) and Hawk-Yellow Medicine Watershed (07020004) to incorporate recent monitoring data to support current MPCA business needs and sediment source investigations.
This project will address the numerous recommendations included in the original Guidance Document to provide an updated and improved Guidance Document. This improved guidance will help to ensure consistency and validity of future HSPF model applications within the State as part of the One Water Program.
This project will finalize the guidance document to ensture consistency and validity of future Hydrological Simulation Program FORTRAN (HSPF) model applications within the State of MN. This improved guidance will help to ensure consistency and validity of future HSPF model applications within the State as part of the One Water Program.
This project will complete spatial and temporal revisions of 6 Hydrologic Simulation Program FORTRAN (HSPF) models, the recalibration and validation of 7 watershed HSPF models, and the revision of the drainage network and point source representation of the Pomme de Terre HSPF model.
The goal of this work is to enhance the Scenario Analysis Manager (SAM) tool. These enhancements will enable point source and stressor identification staff within the state to quickly access data, facilitate their research, and develop scenarios. This work will focus on the development of SAM by creating a user friendly interface, expanding the BMP database, and improving the BMP simulation methodology including optimization functionality. Additionally, this work includes development of a HSPF validation tool, testing and QAQC, and provides documentation and training to expected users.
The Minnesota River Basin Hydrological Simulation Program FORTRAN (HSPF) models simulate sediment erosion and transport, however these models periodically need to be adjusted to be consistent with the most recent sources of information regarding sediment distribution and loading rates. The goal of this project is to refine the sediment source partitioning and simulation in the Minnesota River basin using all relevant available sources of information.
The Minnesota River Basin Hydrological Simulation Program FORTRAN (HSPF) models, which simulate flow and pollutant transport, need to be refined to be consistent with the most recent external sources of land use, hydrologic response, and surface flow attributions. The primary goal of this work is to refine the hydrologic calibration in the Minnesota River basin.
The goal of this project is to extend existing Hydrologic Simulation Program FORTRAN (HSPF) models through 2017 for the following major watersheds: Redwood, Cottonwood, Watonwan, Blue Earth, Le Sueur, Pomme de Terre, Minnesota River-Headwaters, and Lac Qui Parle watersheds.
This project supports activities by Minnesota Pollution Control (MPCA) Watershed Division staff that provide technical assistance, project oversight, coordination, outreach and other agency activities associated with assessing, listing and conducting Total Maximum Daily Load (TMDL) studies throughout the State of Minnesota. Project also includes lab analysis, equipment, and fieldwork expenses associated with TMDL work at the MPCA.
This project will provide an interpretive assessment of nitrogen concentrations in Minnesota rivers and streams, including spatial and temporal trends based on historical data sets. The trends analyses will provide information useful for evaluating nitrogen reduction efforts in the past couple of decades.
The goal of this project is to refine the nutrient and algae simulation in the Minnesota River basin using all relevant available sources of information. The outcome of this work order is a revised Hydrological Simulation Program – FORTRAN (HSPF) watershed model application for the Minnesota River basin that correctly represents nutrient sources and algae.
The study will assess existing phosphorus data records and create a model to explain phosphorus loading into the Red River of the North. Studies have found that the majority of nutrient loading in the stream located in agricultural areas occurs with sediment loading since nutrients are typically bound to sediment particles.
The goal of this project is to provide three training sessions for the Scenario Analysis Manager (SAM) software and one training session for the Processing Application Tool for the Hydrologic Simulation Program FORTRAN (HSPF) model.
RESPEC will use the Processing Application Tool for HSPF (PATH) to construct the remaining 22 Scenario Application Manager (SAM) projects. SAM assists in understanding watershed conditions, and identifying priority areas and BMPs that will provide the greatest water-quality benefits for each dollar invested. The value of the tool is in its simplification of complex hydrologic and water quality model applications into transparent estimates of the significant pollutant sources in watershed.
The goal of this work order is to make additions and enhancements to the Scenario Analysis Manager (SAM) tool best management practice (BMP) database and the methodologies used for the application of the BMPs.
This work will involve enhancing the capability of the Scenario Analysis Manager (SAM) tool to run more complex point source alternative scenarios, produce results and output in line with the recently developed Watershed Restoration and Protection Strategies (WRAPS) report standards, and general enhancements requested by users.
This work order will address the need for technical support and updates to the Scenario Analysis Manager (SAM) tool and PATH software based on training feedback. The trainings will include exercises focusing on improved and added functionality as well as the enhanced best management practice (BMP) database.
The contractor will collect and process the necessary files needed to develop a Processing Application Tool for HSPF (PATH) and Scenario Application Manager (SAM) project for 30 HUC 8 watersheds in Minnesota. SAM provides a graphical interface to the Hydrological Simulation Program FORTRAN (HSPF) model applications and expands the state’s investment in HSPF to a broader audience in support of the development of Total Maximum Daily Load (TMDL) studies and Watershed Restoration and Protection Strategy (WRAPS) reports.
The goal of this project is to develop forestry related best management practice (BMP) pollutant reduction/management efficiencies, costs, and management information applicable to Minnesota forests and incorporate these BMPs into the Hydrological Simulation Program FORTRAN (HSPF) model Scenario Application Manager (SAM) tool. By incorporating forestry BMPs into the existing SAM tool, forestry related management scenarios can be evaluated for potential impacts on surface waters and can inform the development of watershed restoration and protection strategies.
The goal of this work order is to collect and process the watershed specific files needed to create the Scenario Application Manager (SAM) project files to apply the SAM software in selected major watersheds in Minnesota where an Hydrological Simulation Program – FORTRAN (HSPF) model has been developed. This work order will also involve technical support for the SAM users who are applying the SAM projects.
The goal of this work order is to enhance the Scenario Analysis Manager (SAM) support tool in order to represent best management practices in a more physically based manner, improve point scenario representation and analysis, and support MPCA with training in the application of the enhanced functionality.
MPCA will administer funding to eligible Local Governmental Units to use MPCA-approved Advanced Inspectors to conduct work in accordance with Minn. Rules 7080, 7081, and 7083, which requires proper location, design, installation, use and maintenance of an individual subsurface sewage treatment system (SSTS) with a design flow of 2,500 gallons per day or more that protects the public health, safety, general welfare, and the environment by the discharge of adequately treated sewage to the groundwater. Multiple contracts will be awarded.
The overall goal of this process is to compile the information developed by the MPCA into summaries, tables, graphics and tools that the MPCA can use to replace sections of the Stormwater Manual. CDM Smith has developed an approach and workplan that is aimed at complimenting the knowledge of the MPCA and assisting the MPCA through supplemental literature searches, compilation of materials into usable formats, and facilitation of discussions when needed.
The final outcome of this project will be a chloride management plan which will lay out a strategy for addressing chloride impacts to our surface waters for the 7-county metropolitan area. This chloride management plan will satisfy EPA requirements for impaired waters, address waters not yet listed, and develop a strategy to protect waters that are currently meeting the water quality standards. This management plan will also include implementation activities for reducing chloride to TCMA waters as well as identify high priority areas to target implementation activities.
The goal of this project is to construct two executable Hydrologic Simulation Program FORTRAN (HSPF) watershed models for the Minnesota River Headwaters and Lac qui Parle watersheds. The contractor will use the Minnesota River HSPF model application already developed by Tetra Tech as a starting point and will refine the model construction based on the details in this work plan. The contractor will produce HSPF models that, after calibration and validation, will readily be used to provide information to support conventional parameter Total Maximum Daily Loads (TMDLs).
This project will extend the simulation period for the Hydrological Simulation Program - FORTRAN (HSPF) models for the Grand Rapids, Brainerd, Crow Wing, Redeye, Long Prairie, Sartell, Sauk, St. Cloud, and Crow watersheds, and review and comment on the calibration.