Comprehensive Testing Solutions

Advanced measurement technology is combined with sophisticated analysis methods at SADAP's testing facility to provide detailed insights into structural dynamic behavior. The comprehensive testing portfolio has been developed to deliver accurate and reliable results across various testing requirements, from precise modal parameters to standardized vibration qualification.

Documentation Delivery

All test results are documented comprehensively and delivered in professional format:

  • Technical reports are provided with executive summaries
  • Test data is delivered in industry-standard formats
  • Visual documentation includes graphs and mode animations
  • Design optimization recommendations are included

Modal Analysis ITD (Ibrahim Time Domain)

Modal Analysis ITD Testing Setup

Single-reference modal testing optimized for:

  • Natural frequencies can be precisely identified in complex structures
  • Damping measurements are accurately determined for lightweight components
  • Aerospace and automotive prototype testing requirements are met
  • Initial design validation and troubleshooting can be performed

Modal Analysis PTD (Polyreference Time Domain)

Modal Analysis PTD Testing Setup

Multi-reference analysis specialized for:

  • Closely spaced modes in complex structures are identified
  • Mode shapes are determined with high precision
  • Turbomachinery and power generation equipment can be analyzed
  • Detailed structural optimization is enabled

Vibration Testing

Standardized Vibration Testing Setup

Standardized testing according to DIN EN 60068:

  • Products are qualified for international markets
  • Environmental stress screening and durability validation is performed
  • Electronics and industrial equipment can be certified
  • Regulatory compliance requirements are met

Mechanical Impedance and Dynamic Damping

Mechanical Impedance Measurement Setup

Precise impedance and damping measurement for complex structures:

  • Dynamic stiffness is determined across wide frequency range
  • Nonlinear damping characteristics captured through amplitude-dependent analysis
  • Frictional effects in connecting elements are identified and quantified
  • Hysteresis behavior is characterized through specialized measurement techniques
  • Interface characterization for subsystem integration
  • Validation of numerical models through experimental data
  • Optimization of connection elements and interfaces