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The Deval in the Details Report

This is an automated data analytics tool designed to enhance the user experience for WEPPcloud users. It generates comprehensive run reports that include detailed and interactive graphical outputs and tabulated summaries of the WEPPcloud watershed run results. These reports can be easily downloaded and utilized for various purposes such as reports, presentations, or any other information needs.

ET-Persistance

Using historic satellite remote sensing evapotranspiration imagery this tool helps identify fields that could potentially benefit from variable rate management strategies.

Viz-ERMiT

A Shiny web application with interactive visualization for some specific variables generated by Online interface WEPPcloud for the Watershed Erosion Prediction Project (WEPP) model combined with variables from the spreadsheet version of Batch ERMiT tool.

Pi-VAT

A post-processing, interactive visualization, and analysis tool to synthesize multi-scenario, multi-watershed outputs from process-based geospatial models WEPP and SWAT.

WEPPeval

A Shiny application bundled into an R package aimed at quick and interactive synthesis of WEPP model runs executed on WEPPcloud.

WEPP Performance Explorer

A Shiny web application that allows users identify the climate product that results in a relatively better WEPP model predictions for their watershed area.

ET-Persistance (Prototype for CAFE sites)

Using historic satellite remote sensing evapotranspiration imagery this tool helps identify fields that could potentially benefit from variable rate management strategies.

Viz-WEPPcloud

A Shiny Web app implementation to assist in targeted management using WEPPcloud simulated outputs. Synthesize multi-scenario, multi-watershed outputs from process-based geospatial model WEPP (WEPPcloud) using this post-processing, interactive visualization, and analysis tool.

WEPPRecipes

An R package for post processing Watershed Erosion Prediction Project (WEPP) model simulations.

Sorption

An R package for predicting sorption processes using empirical models