4D IMAGING AT YOUR FINGERTIPS Real-time, Portable, High-Resolution Solutions for your Quality Control Needs

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STDO Dynamic 3D 4D Imaging Microscopy Instrument Systems 4D IMAGING AT YOUR FINGERTIPS Real-time, Portable, High-Resolution Solutions for your Quality Control Needs STDO-HOLO Overview: STDO-HOLO enables quantitative, non-invasive, non-contact 4D characterization of reflective surfaces. Based on the principles of digital holography, STDO-HOLO provides real-time depth measurements with comparable accuracy to that of atomic force microscope at only a significant fraction of the cost and hassle. for STDO-HOLO for STDO-HOLO Reflective materials Intensity and Quantitative Phase Contrast Camera 1280x960 pixels, 8 bits, 4.65μm x 4.65μm/pixel Laser source 642nm Magnification 2.97x, 10x-60x Axial Resolution 10nm 7.81 μm, 1.1 to 4.4 μm 4.27cm x 3.20cm; 790 μm x 620 μm Working Distance 17cm Sample Stage Manual x,y,z axis, travel range=10cm (optional) Size and Weight L x W x H: 120 x 42 x 62 x cm and 460g Vertical Measuring Range Wavelength Dependent User-friendly Real-life capture Quantitative phase analysis Line profile analysis, color maps 3D plot of sample and height/depth analysis Fully customizable to customer s needs 1

MEMS Microsystem Characterization in real time 3D Inspection Static and dynamic characterization On line process monitoring Surface roughness Online MEMs/Microsystems inspection Characterization of Si Wafers Warpage measurement Defect Analysis Non-destructive testing and inspection Micro-mechanics Static and dynamic deformation analysis Residual Stress Micromechanics design and characterization 2

STDO-NANO Overview STDO-NANO provides non-contact, non-invasive 4D measurements for transparent objects. By obtaining quantitative phase information with noninterferometric methods, STDO-NANO enables real-time nanometerresolution depth measurements with comparable accuracy to that of digital holography and atomic force microscopy Transparent or Reflective Object Real-time quantitative phase and depth Image sensors 1280 x 1448 pixels, 8 bits Axial Resolution λ/20 3.48 μm 7.1 mm x 5.2 mm Max step size 300mA (abt 11mm) Sample Stage Manual x,y,z axis, travel range=10cm (Optional) Dimensions L x W x H: 205mm x 80mm x 40mm Vertical Measuring Range Up to depth for smooth surfaces Wavelength LED tunable Real-time image capture Quantitative Phase Phase to height conversion Video creation from time-based quantitative phase measurements Roughness measurement Microlens array and diffractive optics characterization Microfluidics Spherical beads shaping and characterization Extended range depth measurement. Diamond turned component testing Flatness measurement Roughness measurement Refractive index profiling Any other transparent objects 3

STDO-POLAR Modular and customised packing, High Resolution, Whole field birefringence and stress measurement STDO-POLAR provides dynamic whole-field stress analysis and birefringence measurements for transparent objects. By measuring the polarization of light through transparent objects, d'polariscope enables robust high-resolution quality-control for 3D-printed or injection-molded components. s Birefringence Integrated Stress Spatial Resolution Illumination time Working distance Stage Travel Wavelength Polarisation angle ( o ), normalized retardation (nm.cm), integrated stress (Mpa) 5 nm/cm 1 MPa (PMMA) 2 μm LED Light Source 520nm 25mm x 25mm <5 seconds 150mm 100 mm x 100mm Green (520nm LED) Stress Anaylsis Visualization and FEM Validation Stereo-lithography Injection Molded and 3D printed Component Inspection Biomedicine Dynamic Stress Analysis Optical Materials (e.g Fused silica, crystals, lenses) Polymer materials (PMMA, COC, epoxy, etc) 4

STDO-BIO STDO-BIO is a microscope camera that converts 2D bright-field images into 4D videos. By obtaining quantitative phase information, STDO-BIO allows one to capture dynamic quantitative depth information of live cells and tissues. STDO-BIO can be used with any existing light microscope with a camera port. Image sensors Axial Resolution Field of view Size Transmission Real-time quantitative phase and depth 1280 x 1448 pixels, 8 bits <20nm Magnification-dependent Magnification-dependent LxWxH: 205mm x 80mm x 40mm Real-time image capture Quantitative Phase Phase to height conversion Video creation from time-based quantitative phase measurements Cancer Biology Regenerative medicine /tissue engineering Infectious diseases Neurological diseases Drug development Biological assay development 5

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