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Prime BSI Express Pre-Arrival Guide
Thank you for your interest in the Prime BSI Express sCMOS, a highly optimized imaging solution. This is a guide to help you prepare for the arrival of the Prime BSI Express, ensuring that the hardware and software of both your PC and microscope/imaging system are capable of making the most of the power of the Prime BSI Express and delivering your desired data.
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Prime BSI Pre-Arrival Guide
Thank you for your interest in the Prime BSI sCMOS, which delivers the perfect balance between high-resolution imaging and sensitivity. This is a guide to help you prepare for the arrival of the Prime BSI, ensuring that the hardware and software of both your PC and microscope/imaging system are capable of making the most of the power of the Prime BSI and delivering your desired data.
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Comparing VPUs, GPUs, and FPGAs for Deep Learning Inference
A key decision when getting started with deep learning for machine vision is what type of hardware will be used to perform inference. Graphics Processing Units (GPUs), Field Programmable Gate Arrays (FPGAs), and Vision Processing Units (VPUs) each have advantages and limitations which can influence your system design.
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Complete off the shelf 3D system
High Definition Imaging (HDI) 3D Scanner which produces a digital 3D scan from physical objects in less than two seconds.
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SIM and iSIM
One of the goals of biological microscopy is to observe and analyze biological processes and structures on the subcellular scale. However, the size of the smallest structures that can be observed is set by the diffraction limit of light, meaning no detail can be resolved smaller than around 250 nm.
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Introduction To Spinning Disk Confocal Microscopy
There are two significant challenges in biological imaging that conventional fluorescence microscopy cannot overcome. Firstly, biological specimens are 3-dimensional structures so to fully understand them we often need to construct 3-dimensional images.
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Expansion Microscopy
Light microscopy techniques have been vital to our understanding of biological structures in cells and tissues since their invention in the late 16th century. However, the resolution of conventional light microscopy techniques is limited by the diffraction limit of light which prevents structures smaller than approximately ~300 nm from being resolved.
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Maximizing Data Throughput in Spinning Disk Confocal With the Kinetix sCMOS and X-Light V3
The new Kinetix sCMOS, live on an X-Light V3 spinning disk confocal system.How the unique specifications of the Kinetix sCMOS allows spinning disk users to image bigger and faster than ever before.
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Overcoming The Challenges Of High Speed Voltage Imaging With New sCMOS Camera Technology
How voltage imaging can be used to deliver structural and functional data.The opinions of experts in the field of voltage imaging and their methodologies.
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Simplifying Fluorescence Image Capture
Fibroblast cells: Texas red Mitotracker mitochondria stain (top left), FITC green actin stain (middle left) and DAPI blue nuclei stain (bottom left).
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Webinar: How the Next Level of CMOS Compares and Can Extend Your Imaging Possibilities
How you could drive experiments faster with the Kinetix.How the Kinetix could improve your light collection efficiency.
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Webinar: Advice On Choosing a Camera for Calcium and Voltage Imaging
How techniques within calcium and voltage imaging can be differentiated based on camera requirements.The unique imaging challenges presented by these techniques and how to overcome them
