Short wave infrared micro hyperspectral imaging instrument

Overall description

ATH5500-17yesA product launched by Aopu TianchengSmall sizeHigh definition, high qualityofmicroscopicHyperspectral imaging instrument,Composed of high-power microscope, hyperspectral imaging instrument, data processing workstation, etcShort wave infrared micro hyperspectral imaging instrument.

ATH5500-17Short wave infrared micro hyperspectral imaging instrumentHyperspectral analysisadopt1920X1080 pixels（2048 × 2048 pixels）High performanceCCD imaging device, with clear imaging and less noise; Internally integrated with a unique high compression ratio image compression algorithm, the storage endurance is greatly improved, reaching more than 3 hours, meeting the needs of drones;

ATH5500-17Imaging spectroscopy technology is used for spectral imaging of samples, which has the characteristics of fast, accurate, high spectral resolution, high spatial resolution, and strong universality. It can be used for research in medicine, pathology, pharmaceuticals, and life sciences, and can be used as experimental research equipment for medical institutions, research institutions, medical schools, and pharmaceutical companies.

Feature:

lBand range：1000~1700nm

lHyperspectral resolution:<35nm

lCustomized infrared high transmittance microscopy system;

lObjective lens magnification:

nStandard configuration:4X、10X、20X；

noptional40X、100X

l5-megapixel high-definition camera

lHigh stability and high blue infrared light source lamp;

lhigh brightnessLED lighting

Application fields:

lMedical institutions: cancer tissue screening, blood cell classification;

lResearch institutions, colleges and universities

lPharmaceutical companies: anti-counterfeiting of traditional Chinese medicinal materials

lFood safety: Meat source identification;

lIdentification of Microplastics

lMineral screening

lJudicial appraisal: document inspection appraisal

lBiology: Bacterial and Cellular Analysis

lsemiconductor inspection

lMaterials Science: Microscopic Testing of Materials

Medical hyperspectral imaging combines two-dimensional spatial images with one-dimensional spectral signals into a three-dimensional data cube. Combining spectroscopy and imaging techniques, the essence of medical hyperspectral images is to reflect how materials absorb and reflect light at the molecular level under electromagnetic waves. It not only contains rich spatial information, but also includes many continuous narrow bands called spectral features, which can accurately distinguish different blood cells. At present, medical hyperspectral imaging technology has been applied to the detection of tongue tumors, intestinal ischemia and cancer, hemorrhagic shock, medical food safety, and other diagnostic diseases.

Blood cell classification plays a significant role in diagnosis. For example, the recognition of cell spectrum is associated with a specific disease, and the counting of white blood cells has been shown to be associated with multiple diseases, including obesity, smoking, allergic asthma, etc. Initially, blood cell classification and counting were done manually under a microscope, which was not only time-consuming but also had a high error rate. Automatic blood cell classification can be achieved through digital microscopy imaging technology. Due to the similar shapes of different types of blood cells, the accuracy and specificity of cell classification still pose challenges to traditional microscopy imaging techniques. Medical hyperspectral imaging combines two-dimensional spatial images with one-dimensional spectral signals into a three-dimensional data cube. Combining spectroscopy and imaging techniques, the essence of medical hyperspectral images is to reflect how materials absorb and reflect light at the molecular level under electromagnetic waves. It not only contains rich spatial information, but also includes many continuous narrow bands called spectral features, which can accurately distinguish different blood cells. At present, medical hyperspectral imaging technology has been applied to the detection of tongue tumors, intestinal ischemia and cancer, hemorrhagic shock, medical food safety, and other diagnostic diseases.