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  • Getting Started with the Oryx 10GigE Camera

    This application note describes the steps to set up and use the Oryx 10-GigE camera for the first time. It provides a summary of tested hardware, interface card settings, and camera settings. It also outlines troubleshooting and diagnostic tools.

  • How We Test for White Blemish Pixels

    This technical application note explains how we identify and correct white blemish pixel defects; how to get white blemish pixel information about your camera; and what to do if you are concerned about blemish pixels from your camera.

  • How to build your own stereo vision with Teledyne FLIR machine vision cameras

    The purpose of this Technical Application Note is to provide an example of how you can build your own stereo vision system using two Teledyne FLIR machine vision cameras with OpenCV algorithms and the Spinnaker API.

  • Ladybug JPEG Image Quality and Buffer Size Settings

    The purpose of this Technical Application Note is to explain how to use the Custom Settings dialog in the LadybugCapPro program to manage JPEG image quality and frame rate.

  • Low Noise Imaging in the GS3-U3-14S5 Camera

    This application note describes the low noise imaging in the GS3-U3-14S5 camera, including: 1. Description and use of optimized mode. 2. Comparison of imaging metrics, including saturation capacity, temporal dark noise, and temperature, between standard and optimized imaging modes. 3. Comparison of images between standard and optimized modes.

  • Neural Networks Supported by the Firefly-DL

    This application note describes neural networks supported by the Firefly-DL camera.

  • Vesicle Tracking and Transport

    Research in the Pucadyil lab at the Indian Institute of Science Education and Research is focused on understanding how proteins involved in vesicular transport manage to sort membrane proteins and bud out vesicles from cell membranes. The team approaches this area of research by reconstituting partial reactions that contribute tobudding and scission of transport vesicles from model membranes that mimic native cell membranes.

  • The Development of Carbon Nanotube Optical Sensors for Early Disease Detection

    One of the main areas of research at the Memorial Sloan Kettering Cancer Center in New York City is the development of nanoscale sensors to detect cancer at its earliest stages.

  • Dynamic Neutron Radiography - Novel (3D) Neutron Imaging Technique

    Every engineer and scientist dreams of being able to investigate objects from within, without destroying them, in order to study cracks, hidden flaws, or structural material changes. Over the years, a variety of technologies have been utilized to help make this dream a reality via the ongoing development of new techniques that leverage the unique characteristics of different radiation modalities.

  • Advanced CMOS Detectors: Enabling the Future of Astronomical Observation

    Ground based astronomy provides an accessible way to image objects in space. As most of the objects in space can be observed within the visible wavelength range (380-700 nm), optical astronomy has been at the forefront of astronomical observation. Many objects in space are very faint, requiring a camera with high sensitivity and minimal noise to detect their weak signal.

  • New Era in Dynamic Range and Linearity for Scientific CMOS Cameras

    Scientific CMOS technology offers improvements over previous sensor technologies such as CCD and EMCCD in key performance areas such as speed, noise performance, energy use and sensor size.

  • Why Must I Have an emICCD?

    Intensified cameras are specialized devices that optically connect an image intensifier to a CCD sensor. One finds a wide variety of CCD sensor architectures making this camera type adaptable to many imaging and spectroscopy experimental needs.