Babysitter demand-forecasting-engine
Statistical demand forecasting skill using multiple algorithms with automatic model selection and accuracy tracking
install
source · Clone the upstream repo
git clone https://github.com/a5c-ai/babysitter
Claude Code · Install into ~/.claude/skills/
T=$(mktemp -d) && git clone --depth=1 https://github.com/a5c-ai/babysitter "$T" && mkdir -p ~/.claude/skills && cp -r "$T/library/specializations/domains/business/supply-chain/skills/demand-forecasting-engine" ~/.claude/skills/a5c-ai-babysitter-demand-forecasting-engine-1f717a && rm -rf "$T"
manifest:
library/specializations/domains/business/supply-chain/skills/demand-forecasting-engine/SKILL.mdsource content
Demand Forecasting Engine
Overview
The Demand Forecasting Engine provides comprehensive statistical and machine learning-based demand forecasting capabilities. It supports multiple forecasting algorithms with automatic model selection, ensemble averaging, and continuous accuracy tracking to generate reliable demand predictions for supply chain planning.
Capabilities
- Time Series Forecasting: ARIMA, exponential smoothing, Holt-Winters methods
- Machine Learning Models: XGBoost, LSTM neural networks for complex demand patterns
- Causal Factor Integration: Incorporate promotions, seasonality, trends, and external drivers
- Demand Sensing: Short-term signal incorporation for near-term forecast adjustment
- Accuracy Metrics: MAPE, WMAPE, bias calculation and tracking
- Automatic Model Selection: Best-fit algorithm selection based on data characteristics
- Ensemble Averaging: Combine multiple model outputs for improved accuracy
- Confidence Intervals: Generate prediction intervals for uncertainty quantification
- Forecast Value-Add (FVA) Analysis: Measure contribution of each forecasting step
Input Schema
forecast_request: sku_ids: array[string] # SKUs to forecast historical_data: object # Historical demand data forecast_horizon: integer # Periods to forecast granularity: string # daily, weekly, monthly causal_factors: # Optional external factors promotions: array seasonality: object trends: object models_to_evaluate: array # Optional specific models confidence_level: float # e.g., 0.95 for 95% CI
Output Schema
forecast_output: forecasts: array - sku_id: string predictions: array[object] confidence_intervals: object selected_model: string accuracy_metrics: object model_comparison: object recommendations: array
Usage
Generate SKU-Level Forecast
Input: Historical sales data for SKU-12345, 12-month forecast horizon Process: Evaluate ARIMA, Holt-Winters, XGBoost models Output: Monthly forecasts with confidence intervals and best model selection
Promotional Demand Planning
Input: Base demand + planned promotions calendar Process: Adjust baseline with promotional lift factors Output: Promotion-adjusted forecast with uplift quantification
Multi-Model Ensemble
Input: Complex demand pattern with multiple seasonalities Process: Run multiple models and create weighted ensemble Output: Ensemble forecast with individual model contributions
Integration Points
- ERP Systems: SAP, Oracle for historical demand data
- Planning Platforms: o9 Solutions, Kinaxis, Blue Yonder
- Data Sources: POS systems, channel inventory data
- Tools/Libraries: Prophet, statsmodels, scikit-learn, TensorFlow/PyTorch, pandas
Process Dependencies
- Demand Forecasting and Planning
- Sales and Operations Planning (S&OP)
- Forecast Accuracy Analysis and Improvement
Best Practices
- Ensure sufficient historical data (minimum 2 years for seasonal patterns)
- Cleanse outliers before model training
- Validate forecasts against holdout periods
- Document model selection rationale
- Track forecast accuracy over time for continuous improvement
- Consider demand segmentation for heterogeneous portfolios