# Analysis

A comprehensive suite of tools for analyzing and visualizing simulation results in Flow360.

Option	Description	Purpose
`Dashboard`	Interactive overview of simulation progress and key metrics	Real-time monitoring and analysis
`Convergence`	Analysis of solution convergence behavior	Solution quality assessment
`Monitor`	Tracking of flow field variables at specific locations	Detailed flow analysis
`Visualization`	Advanced visualization tools for flow field data	Flow pattern analysis
`Aeroacoustic`	Acoustic analysis and noise prediction	Sound generation and propagation

The Dashboard provides an interactive overview of your simulation's progress and key performance metrics.

Features:
- Real-time progress tracking
- Key performance indicators
- Simulation status overview
- Resource utilization metrics

Convergence analysis tools help assess the quality and stability of your simulation results.

Features:
- Nonlinear residual monitoring
- Linear residual tracking
- CFL number visualization
- State variable bounds
- Maximum residual location tracking

Monitors enable detailed tracking of flow field variables at specific locations during simulation.

Available Types:
- Total Forces
- Forces by Surface
- Heat Transfer by Surface
- BET Forces and Moments
- Force Distribution (X/Y)
- Actuator Disk metrics

Advanced visualization tools for analyzing flow field data and patterns.

Features:
- Surface visualization
- Volume visualization
- Slice analysis
- Isosurface generation
- Streamline visualization

Specialized tools for acoustic analysis and noise prediction.

Features:
- Acoustic pressure monitoring
- Frequency spectrum analysis
- Overall Sound Pressure Level (OASPL) calculation
- A-weighting support
- Multiple observer positions

Dashboard Usage:
- Monitor simulation progress in real-time
- Track key performance metrics
- Identify potential issues early
Convergence Analysis:
- Check residual history for stability
- Monitor CFL numbers for numerical stability
- Use maximum residual location to identify problematic regions
Monitor Setup:
- Place monitors strategically for meaningful data collection
- Consider both steady and unsteady simulation needs
- Use appropriate sampling frequencies
Visualization Best Practices:
- Start with surface visualization for quick insights
- Use slices for detailed flow analysis
- Generate isosurfaces for specific flow features
Aeroacoustic Analysis:
- Ensure sufficient temporal resolution for acoustic analysis
- Place observers outside the flow domain
- Consider both solid and permeable approaches

What is the difference between pseudo steps and physical steps?

Pseudo steps are used in steady-state simulations, while physical steps are used in unsteady simulations (though they consist of pseudo steps). Physical steps represent actual time advancement in the simulation.
How do I interpret convergence plots?

Look for decreasing residuals over time. A stable, decreasing trend indicates good convergence. Sudden spikes or oscillations may indicate numerical issues.
When should I use aeroacoustic analysis?

Aeroacoustic analysis is valuable for applications where noise prediction is important, such as aircraft design, wind turbine performance, and automotive aerodynamics.
What is the purpose of A-weighting in acoustic analysis?

A-weighting adjusts sound levels to match human hearing sensitivity, providing more meaningful noise assessment for human perception.