Imaging & Measurement

Advanced optical imaging and quantitative measurement technologies for neuroscience, biomedical research, fluid dynamics, combustion, spray analysis, industrial diagnostics, and high-speed scientific visualization.

Multiphoton Microscopy enables deep-tissue and in vivo imaging with low phototoxicity and high spatial resolution, making it ideal for long-term neural activity monitoring, live-cell imaging, developmental biology, and advanced biomedical research.

Optical Coherence Tomography (OCT) provides non-contact high-resolution cross-sectional imaging for biomedical diagnostics, semiconductor inspection, microstructure analysis, and precision industrial metrology.

LDV (Laser Doppler Velocimetry) enables high-speed single-point velocity measurement with excellent temporal resolution, fast acquisition rates, and relatively simple experimental setup, making it suitable for turbulence analysis, combustion flow, and industrial flow diagnostics.

PIV (Particle Image Velocimetry) provides planar two-component velocity field measurements for quantitative flow visualization in aerodynamics, hydrodynamics, combustion, and fluid mechanics research.

Stereo PIV (S-PIV) extends conventional PIV to measure three velocity components within a plane, enabling advanced vortex, turbulence, and complex flow structure analysis.

Tomographic PIV enables fully volumetric three-dimensional flow field reconstruction for complex transient and turbulent flow measurements.

PTV (Particle Tracking Velocimetry) tracks individual particle motion in volumetric space and is particularly suitable for periodic, sparse-particle, and highly dynamic flow fields.

BOS (Background Oriented Schlieren) visualizes density gradients, thermal flow, gas leakage, shockwaves, and refractive index variations using non-contact optical imaging techniques.

Spray & Particle Diagnostics utilizes shadowgraphy and laser-based diagnostics for spray angle measurement, plume geometry analysis, droplet sizing, particle counting, particle distribution analysis, and fuel injection characterization.

Combustion Diagnostics supports advanced techniques including PLIF, Tunable-LIF, Raman imaging, Rayleigh thermometry, LII soot diagnostics, chemiluminescence imaging, flame spectroscopy, and high-speed flame imaging for quantitative combustion and reactive flow analysis.

High-Speed Imaging enables visualization of ultra-fast transient events including shockwaves, combustion, fluid instabilities, plasma dynamics, droplet breakup, and high-speed industrial processes.

Additional technologies support fluorescence imaging, reactive flow analysis, particle characterization, volumetric flow diagnostics, and advanced quantitative optical measurement for scientific and industrial applications.