Photonfocus SNAPSHOT RedNIR
Want to test hyperspectral scanning and analysis in the RedNIR range? With this user-friendly real-time GigE camera from Photonfocus, integrating imec?s hyperspectral sensor, you?ll be looking at relevant test data within a few minutes of the installation.
Photonfocus SNAPSHOT RedNIR
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Photonfocus SNAPSHOT RedNIR
spectral range = 600-870 nm
spectral resolution = 15 bands
spatial resolution = 2040 x 1080
imager type = CMOS imager, CMOSIS CMV2000-based
acquisition speed = Up to 42 hyperspectral cubes/second (limit of GigE vision interface)
pixel pitch = 5.5 ?m pixels, 2/3?? sensor optical format
bit depth = 10 bits
optics = 16/25/35/50 mm lenses, C-mount
camera interface = GigE vision + GPIO for triggering
power consumption <5.1 W
camera dimensions (W x H x D) = 55 x 55 x 52 mm
camera weight = 265 g without optics
software = HSI MOSAIC software for raw image acquisition, data pre-processing, hypercube visualization and classification, including API
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Quick Comparison
| Photonfocus SNAPSHOT RedNIR remove | HySpex VNIR-3000N remove | Resonon Pika L remove | HySpex Mjolnir S-620 remove | HySpex VS-1200 remove | HySpex Mjolnir V-1240 remove | |
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| Name | Photonfocus SNAPSHOT RedNIR remove | HySpex VNIR-3000N remove | Resonon Pika L remove | HySpex Mjolnir S-620 remove | HySpex VS-1200 remove | HySpex Mjolnir V-1240 remove |
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| Content | Photonfocus SNAPSHOT RedNIR Want to test hyperspectral scanning and analysis in the RedNIR range? With this user-friendly real-time GigE camera from Photonfocus, integrating imec?s hyperspectral sensor, you?ll be looking at relevant test data within a few minutes of the installation. | HySpex VNIR-3000 N HySpex VNIR-3000 N is developed for field, laboratory, and airborne applications. HySpex VNIR-3000 N utilizes the same spectrograph as the other classical HySpex VNIR models. With a pixel size of 3.45?m, compared to 6. 5?m for VNIR-1800, HySpex VNIR-3000 N will have less than 1.6 pixels per FWHM of the PSF spatially and less than 1.8 bands spectrally, ensuring that narrow band features will be resolved equally for all cameras. With 3000 spatial pixels, 300 bands and a noise floor of 2.4e-, HySpex VNIR-3000N will provide outstanding SNR levels in dark environments. The camera is offered with a USB connection, allowing camera operation from any computer and reducing the cost of supplementing equipment. To visualize that the camera has a wider PSF per pixel and band relative to our normal extremely sharp cameras, we have added an N for Nyquist to the model name. | Pika L 400 - 1000 nm Lightweight, Compact VNIR The Pika L is a lightweight, compact hyperspectral camera that covers the Visible + Near-Infrared (VNIR) spectral range. It is our most popular imager for remote sensing applications. The Pika L can be used in our airborne, laboratory, and outdoor hyperspectral systems, as well as standalone or integrated into your system. | HySpex Mjolnir S-620 The HySpex Mjolnir S-620 hyperspectral imaging system for UAVs is the SWIR version of the Mjolnir camera series. Similar to the VNIR version, it provides a unique combination of small form factor and low mass, combined with high-performance specifications and scientific grade data quality. With a weight of less than 4.5 kg and less than 50 W power consumption, HySpex Mjolnir S-620 is very well suited for a wide range of UAVs. NEO offers high-performance unmanned aerial vehicles, fully integrated with the HySpex Mjolnir S-620. The UAV is fitted with a standard battery package allowing up to 30 minutes of flight time. All HySpex Mjolnir systems can also be mounted on a tripod and rotation stage for ground use. | HySpex VS-1200 The HySpex VS-1200 hyperspectral camera is developed for airborne applications requiring extreme resolution in both VNIR and SWIR spectral regions. The HySpex VS-1200 is a novel high-resolution instrument designed for airborne applications at altitudes greater than 400m. The camera produces the highest scientific grade level data, commercially available, having FWHM less than 1.2 pixels spatially and less than 1.5 pixels spectrally. The combined VNIR-SWIR cube has coregistration errors, and smile and keystone of less than 10% of a pixel. With 40 degrees FOV, the camera is ideal for mapping large areas with high accuracy and resolution. The camera is delivered with an integrated high-performance IMU/GPS and data acquisition unit with removable storage bays as a standard. Existing navigation systems can also be integrated/utilized. A standard passive damping solution is included as a part of the default delivery package, but mounting plates for active damping solutions, such as GSM4000 or PAV80 can be supplied. | HySpex Mjolnir V-1240 The HySpex Mjolnir V-1240 hyperspectral imaging system for UAVs provides a unique combination of small form factor and low mass, combined with high-performance specifications and scientific grade data quality. With a weight of less than 4 kg and less than 50 W power consumption, HySpex Mjolnir V-1240 is very well suited for a wide range of UAVs. The system is also compatible with several off-the-shelf gimbals. NEO offers high-performance unmanned aerial vehicles, fully integrated with the HySpex Mjolnir V-1240. The UAV is fitted with a standard battery package allowing up to 30 minutes of flight time. All HySpex Mjolnir systems can also be mounted on a tripod and rotation stage for ground use. |
| Description | spectral range = 600-870 nm spectral resolution = 15 bands spatial resolution = 2040 x 1080 imager type = CMOS imager, CMOSIS CMV2000-based acquisition speed = Up to 42 hyperspectral cubes/second (limit of GigE vision interface) pixel pitch = 5.5 ?m pixels, 2/3?? sensor optical format bit depth = 10 bits optics = 16/25/35/50 mm lenses, C-mount camera interface = GigE vision + GPIO for triggering power consumption <5.1 W camera dimensions (W x H x D) = 55 x 55 x 52 mm camera weight = 265 g without optics software = HSI MOSAIC software for raw image acquisition, data pre-processing, hypercube visualization and classification, including API | Spectral range = 400 - 1000 nm Spatial pixels = 3000 Spectral channels = 300 Spectral sampling = 2.0 nm FOV* = 16? Pixel FOV across/along* = 0.096/0.32 mrad Bit resolution = 12 bit Noise floor = 2.37 e- Dynamic range = 11000 Peak SNR (at full resolution) > 170 Max speed (at full resolution) = 117 fps Power consumption = 30 W Dimensions (l-w-h) = 39 - 9.9- 15 cm Weight = 5.0 kg Camera Interface = USB3 *Can be doubled with FOV expander | Spectral Range (nm) = 400 - 1000 Spectral Channels = 281 Spectral Bandwidth (nm) = 2.1 Spectral Resolution - FWHM (nm) = 3.3 Spatial Pixels = 900 Max Frame Rate (fps) = 249 f/# = 2.4 Interface = USB 3.0 Dimensions (mm) = 115 x 104 x 66 Weight, w/o lens (kg) = 0.64 | Spectral range = 970 - 2500 nm Spatial pixels = 620 Spectral channels and sampling = 300 bands @ 5.1 nm F-number = F1.9 FOV = 20? Pixel FOV across/along = 0.54/0.54 mrad Bit resolution = 16 bit Noise floor = 80 e- Dynamic range = 10000 Peak SNR (at full resolution) > 900 Max speed (at full resolution) = 170 fps Power consumption* = 50 W Dimensions (l-w-h)* = 254 - 175 - 170 mm Weight* < 4.5 kg *Includes IMU/GPS and DAU - <5 kg including standard battery | Spectral range = 400 - 1000 nm Spatial pixels = 1240 Spectral channels and sampling = 200 bands @ 3 nm F-number = F1.8 FOV = 20? Pixel FOV across/along = 0.27/0.27 mrad Bit resolution = 12 bit Noise floor = 2.3 e- Dynamic range = 4400 Peak SNR (at full resolution) > 180 Max speed (at full resolution) = 285 fps Power consumption = 50 W Dimensions (l-w-h) = 250 - 175 - 170 mm Weight < 4 kg *Includes IMU/GPS and DAU - <6.5 kg including standard battery |
I have realized that in cameras, extraordinary receptors help to focus automatically. The sensors associated with some digital cameras change in contrast, while others employ a beam with infra-red (IR) light, especially in low light. Higher specification cameras from time to time use a combination of both systems and likely have Face Priority AF where the video camera can ‘See’ a face while focusing only on that. Many thanks for sharing your ideas on this blog site.
I’m curious to find out what blog platform you happen to be working with? I’m having some small security problems with my latest blog and I’d like to find something more secure. Do you have any solutions?