Babysitter supply-chain-digital-twin

Digital twin representation of supply chain for real-time monitoring and simulation

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 "$T/library/specializations/domains/business/supply-chain/skills/supply-chain-digital-twin" ~/.claude/skills/a5c-ai-babysitter-supply-chain-digital-twin && rm -rf "$T"

manifest: library/specializations/domains/business/supply-chain/skills/supply-chain-digital-twin/SKILL.md

Supply Chain Digital Twin

Overview

The Supply Chain Digital Twin creates a virtual representation of the physical supply chain for real-time monitoring, predictive analytics, and simulation. It enables continuous optimization through what-if analysis and performance prediction.

Capabilities

Real-Time Supply Chain State Representation: Live digital model
Predictive Analytics Integration: Forward-looking performance prediction
Scenario Simulation: What-if analysis on digital model
Anomaly Detection: Deviation identification from expected patterns
Optimization Recommendation: AI-driven improvement suggestions
What-If Analysis: Impact assessment of proposed changes
Performance Prediction: Future state forecasting
Continuous Learning Integration: Model improvement from actuals

Input Schema

digital_twin_request:
  twin_scope:
    network_elements: array
    processes: array
    time_horizon: string
  real_time_feeds:
    erp_integration: object
    iot_sensors: array
    tracking_feeds: array
  model_configuration:
    physics_models: object
    ml_models: array
    business_rules: array
  simulation_scenarios: array
  prediction_horizon: string
  anomaly_detection_config:
    sensitivity: float
    alert_rules: array

Output Schema

digital_twin_output:
  current_state:
    network_status: object
    inventory_positions: object
    in_transit: array
    production_status: object
    kpis: object
  predictions:
    demand_forecast: object
    supply_forecast: object
    risk_predictions: array
    kpi_projections: object
  anomalies:
    detected_anomalies: array
      - anomaly_id: string
        type: string
        severity: string
        location: string
        description: string
        recommended_action: string
  scenario_results:
    scenarios: array
      - scenario_name: string
        predicted_outcomes: object
        risks: array
        recommendations: array
  optimization_recommendations:
    immediate: array
    short_term: array
    strategic: array
  model_health:
    accuracy_metrics: object
    data_quality: object
    model_drift: object
  visualizations:
    network_view: object
    flow_animation: object
    prediction_charts: array

Usage

Real-Time Network Monitoring

Input: Live data feeds, network model
Process: Update digital twin state continuously
Output: Real-time visibility dashboard

Predictive Performance Analysis

Input: Current state, ML models, forecast horizon
Process: Predict future network performance
Output: Performance predictions with confidence

What-If Scenario Analysis

Input: Proposed change, current twin state
Process: Simulate impact on digital twin
Output: Scenario outcome prediction

Integration Points

IoT Platforms: Sensor and device data
Real-Time Data Streams: Event streaming platforms
ML Platforms: Predictive model deployment
Visualization Platforms: 3D and interactive visualization
Tools/Libraries: Digital twin platforms, IoT integration, ML models

Process Dependencies

Supply Chain Network Design
Supply Chain Disruption Response
Supply Chain KPI Dashboard Development

Best Practices

Start with high-value use cases
Ensure real-time data quality
Validate twin accuracy regularly
Balance model complexity with maintainability
Integrate with decision-making processes
Plan for continuous model improvement