encoord SAInt | Docs
Links
About encoord Go to User Forum Download SAInt Release Download Model Ready Datasets

Tutorials

    • Energy Markets
      • Fundamentals of Direct Current Unit Commitment Optimal Power Flow (DCUCOPF) Scenarios
        • Step 1: Create an Electric Network Model
        • Step 2: Expand the Network Topology
        • Step 3: Add External Objects
        • Step 4: Build a DCUCOPF Scenario
        • Step 5: Define Scenario Profiles
        • Step 6: Design Scenario Events
        • Step 7: Run the Energy Market Optimization
        • Conclusion
      • Analyze an Electricity Market Optimization Model
        • Step 1: Visualize Data
        • Step 2: Analyze Data
        • Step 3: Evaluate Data
        • Step 4: Export Data
      • Model Electricity Storage, Solar, and Wind Production in a Production Cost Model
        • Step 1: Create an Electric Network Model
        • Step 2: Create a Scenario and Run a DCUCOPF Optimization
      • Setting up an Electric Storage in a DCUCOPF Scenario
        • Step 1: Create a New Electric Storage Object
        • Step 2: Setting up Events for an Electric Storage Object
        • Step 3: Extract Simulation Results Data for the Electric Storage Object
      • Set up New Custom Constraint Objects in a PCM
        • Step 1: Create and Edit a Constraint Object
        • Step 2: Execute a DCUCOPF Scenario Using Custom Constraints and Analyze the Results
        • Step 3: Compare Result with Constraint and Without Constraint
    • Electricity Networks
      • Steady State and Quasi-Dynamic Alternating Current Power Flow (ACPF) Simulation
        • Step 1: Create an Electric Network Model
        • Step 2: Expand the Network Topology
        • Step 3: Add External Objects
        • Step 4: Build a SteadyACPF Scenario
        • Step 5: Run the SteadyACPF simulation
        • Step 6: Build a QuasiDynamicACPF Scenario
        • Step 7: Design QuasiDynamicACPF Scenario Profiles
        • Step 8: Design QuasiDynamicACPF Scenario Events
        • Step 9: Run the QuasiDynamicACPF simulation
        • Step 10: Conclusion
      • Analyze an Alternating Current Power Flow (ACPF) Simulation
        • Step 1: Visualize Data
        • Step 2: Analyze Data
        • Step 3: Evaluate Data
        • Step 4: Export Data
      • High Voltage and Medium Voltage ACPF Simulation
        • Step 1: Create the Electric Network Model
        • Step 2: Create and Analyze a Steady AC Power Flow Scenario
        • Step 3: Create and Analyze a Quasi-dynamic AC Power Flow Scenario
    • Gas Networks
      • Transmission System Steady State and Dynamic Simulation
        • Step 1: Create a Gas Network Model
        • Step 2: Expand the Network Topology
        • Step 3: Add External Objects
        • Step 4: Build a Steady State Scenario
        • Step 5: Run the Steady State Simulation
        • Step 6: Build a Dynamic Scenario
        • Step 7: Create Time Profiles for Events in a Dynamic Scenario
        • Step 8: Run a Dynamic Simulation
        • Conclusion
      • Analyze a Transmission System Dynamic Model
        • Step 1: Visualize Data
        • Step 2: Analyze Data
        • Step 3: Evaluate Data
        • Step 4: Export Data
      • Contingencies and Hydrogen Blending in Transmission Systems
        • Step 1: Create a Gas Network Model
        • Step 2: Add Gas Quality and Temperature Tracking
        • Step 3: Create a Scenario and Run a Dynamic Simulation
        • Step 4: Sessions, Advanced Charts, and Tables
    • Thermal Networks
      • Steady State and Quasi-Dynamic Thermal Simulation
        • Step 1: Create a Thermal Network Model
        • Step 2: Expand the Network Topology
        • Step 3: Add External Objects
        • Step 4: Build a Steady State Thermal Scenario
        • Step 5: Run the Steady State Simulation
        • Step 6: Build a Quasi-Dynamic Scenario
        • Step 7: Create Time Profiles for Events in a Quasi-Dynamic Scenario
        • Step 8: Run a Quasi-Dynamic Simulation
    • Coupled Networks
      • Feedback in Combined Dynamic Gas and Electricity Networks
        • Step 1: Create a Coupled Gas-Electric Networks Model
        • Step 2: Develop a Combined Simulation Scenario
        • Step 3: Run a Combined Simulation Scenario
        • Step 4: Bidirectional Coupling and Loops
    • Capacity Expansion Modeling
      • Fundamentals of Capacity Expansion Modeling (CEM) Scenarios
        • Step 1: Create an Electric Network Model and CEM Scenario
        • Step 2: Define Time-series Input Data
        • Step 3: Define Scenario Settings
        • Step 4: Define Object Properties
        • Step 5: Run the CEM Optimization and Analyze Results
        • Conclusion
    • Scripting
      • API Beginner
        • Basic operations
        • Inclusion operations
        • Export operations
        • Evaluate results
      • API Advanced
        • Introduction to parallel computing
        • Run parallel simulations
        • Analyze results
Tutorials latest
  • Welcome
  • Installation Guide
  • Technical Specifications
  • Reference
    • latest
    • v3.5
  • How-to Guides
    • latest
  • Tutorials
    • latest
  • Learn More
    • coming soon
  • Tutorials
  • Capacity Expansion Modeling

Capacity Expansion Modeling

This section provides tutorials on how to use the capacity expansion modeling (CEM) capabilities in SAInt.

Step 4: Bidirectional Coupling and Loops Fundamentals of Capacity Expansion Modeling (CEM) Scenarios

© Copyright 2024 encoord Inc. & encoord GmbH - All Rights Reserved

This page was built using the Antora default UI. The source code for this UI is licensed under the terms of the MPL-2.0 license.