Overview

This section will discuss how to run a short-term forecast using Apollo's Command Sequence.

• Required Inputs
• Step-by-step procedure
• Exercise

Short-term Forecasting

Forecasting is essential to electricity market analysis, providing analysts with insights into potential market conditions based on various assumptions.

Prerequisites

To perform a Short-Term Forecast in Apollo, the following inputs are required:

• Demand File: Forecasted load requirements.
• Must-Run Generation Capacity Factor File: Forecasted Must-Run Generation data.
• Bid Files: Forecasted bid profiles (Historical, Typical, or Custom).

Modeling Outages

To improve model accuracy, consider including a WAPOS event file for scheduled outages or enabling Monte Carlo Simulation for random outage modeling.

Tutorial Video (to add)

• Phase 1: Demand and Generation Preparation
• Phase 2: Bids and Event File
• Phase 3: Apollo Setup

1

Forecasted Demand

iLoad Demand Forecasting Service

Method 1: iLoad Forecasting Service (Recommended)

The iEnergy iLoad Forecasting Service streamlines this workflow by providing rolling Demand and MRG Capacity Factor files pre-formatted for direct use in iPool and Apollo. This service is powered by a sophisticated hybrid intelligence framework that integrates premium, high-resolution weather data with advanced machine learning and AI to provide high-fidelity energy predictions for the Philippine power grid.

• Advanced Demand Forecasting: The system processes a 70-feature matrix that includes cyclical temporal encodings, Philippine holiday detection, and "human comfort" drivers like the Heat Index and Cooling Degree Hours (CDH).
• Continuous Calibration: To ensure sustained accuracy, the service features Rolling 14-Day Auto-Calibration.

Manual Demand Forecasting

Method 2: Manual Forecasting (No Subscription)

If you do not have an active iLoad Forecasting subscription, you must manually generate your forecast files using one of the following options:

• Option 1 (Historical Persistence): Utilize historical Demand data by applying previous Demand.csv values to your target dates.
• Option 2 (Manual Correlation): Manually approximate demand by correlating historical output with daily max/min temperature forecasts.

2

Forecasted Generation

iLoad Generation Forecasting Service

Method 1: iLoad Generation Forecasting Service (Recommended)

• Wind Capacity Factors: For wind stations, the utility utilizes premium 100m hub-height wind data.
• Solar Capacity Factors: Solar forecasting is driven by a Physics+ML Hybrid model.
• Continuous Calibration: Features Rolling 14-Day Auto-Calibration.

Manual Generation Forecasting

Method 2: Manual Forecasting (No Subscription)

If you do not have an active iLoad Forecasting subscription, you must manually generate your forecast files using one of the following options:

• Option 1 (Historical Persistence): Utilize historical Must-Run Generation data by applying previous MRHCFac.csv values.
• Option 2 (Manual Correlation): Manually approximate solar generation by correlating historical output with daily max/min temperature forecasts.

Note

If multiple scenarios are present, the top-most scenario in the list will be executed first. When new scenarios are added to Apollo, you must click the Restart button to ensure proper initialization.

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Exercise

Give it a try and do this exercise:

Step 1 of 4

Backcast Calibration

Execute a one-week Historical Load simulation

Perform Backcast Calibration to establish a baseline