Universal Applications of Modern Optical Measurement Systems

· Transient events in structures, propulsion, and flow fields, enabling visualization diagnosis and quantitative validation of key mechanisms (captured using high-speed cameras). · Real deformation behaviors of structures under impact vibration, thermal loading, and complex external loads (measured using Digital Image Correlation (DIC) systems). · Key flow mechanisms such as propulsion, aerodynamic/hydrodynamic forces, turbulent structures, and boundary layer evolution (measured using Particle Image Velocimetry (PIV) systems).

· Real-time observation of dynamic biological processes involving cells and molecules under low-light and in vivo imaging conditions (using sCMOS cameras for long-term, real-time monitoring). · Transient processes driven by biomechanics, such as cellular mechanical responses, tissue impacts, and transient changes at biological interfaces (captured using high-speed cameras).

· Real dynamic response of materials and structures under transient loads such as impact, fracture, and vibration (captured using high-speed cameras). · Real deformation mechanisms of materials and structures under static, cyclic, impact, and complex coupled loads (measured using Digital Image Correlation (DIC) systems).

· Transient flow, turbulent structures, and interface evolution mechanisms (captured using high-speed cameras). · Turbulent structures, boundary layer development, and complex flow characteristics (measured using Particle Image Velocimetry (PIV) systems).

· Transient processes such as flame propagation, detonation initiation, and shock wave evolution (captured using high-speed cameras). · Transient combustion products and the velocity and turbulent structures of shock waves (measured using Particle Image Velocimetry (PIV) systems).

· Dynamic behavior and minor deformations of high-speed moving components, molten pool dynamics, weld formation process, and spatter behavior (captured using high-speed cameras). · Strain and displacement distribution of workpieces under load (measured using Digital Image Correlation (DIC) systems).

· Arc discharge, streamer generation, and transient failure processes in relay switching (captured using high-speed cameras). · Strain and displacement distribution of workpieces under load (measured using Digital Image Correlation (DIC) systems).

· High-speed dynamic processes of cells, tissues, and medical devices (captured using high-speed cameras). · Full-field deformation of tissues, materials, and implanted devices under mechanical stress (measured using Digital Image Correlation (DIC) systems). · Velocity fields of hemodynamics, drug flow, and fluids in microfluidic devices (measured using

· High-speed optical phenomena and transient electro-optical response processes (captured using high-speed cameras). · Weak light signals and high-speed optical phenomena (recorded using sCMOS cameras).

· Rapid dynamic processes and fault transients in micro-devices (captured using high-speed cameras). · Full-field deformation and strain distribution of micro-devices and structures under load or thermal stress (measured using Digital Image Correlation (DIC) systems).

Comprehensive, systematic, and professional high-speed vision solutions for automotive manufacturing.