Multichannel Imaging Systems

GaiaField-Pro (GFP) is a Hyperspectral Imaging Camera. It is capable of providing extremely high resolution images by scanning and taking multiple images to construct a hyperspectral datacube. GaiaField-Pro hyperspectral imaging devices obtain spatial slit spectra by projecting a strip of light from the scene onto a slit and ...

Specifications

Number Of Channels: >4
Sensor Type: CCD
Wavelength Range: 400-1000nm
Spectral Resolution: 3.5 nm
Numerical Aperture: F/2.8
The hyperspectral imager is a light sensor suitable for field operations. Spectral imaging system, the camera has a built-in power module, no need for external wiring, and it can be used on field. Built-in portable hyperspectral imager equipped with laser ranging module and automatic alignment focusing lens, which can quickly ...

Specifications

Number Of Channels: >4
Sensor Type: CCD, CMOS
Wavelength Range: 250-1700nm
Pixel Size: 12um, 17um
Wavelength: 400-1000nm
The Photometrics® QV2™ allows simultaneous acquisition of up to four emission channels in a single exposure. The QV2 uses a series of beam splitters to split the emission light from a microscope into four separate channels. All four channels are projected onto the CCD at the same time. Simultaneous multichannel imaging is critical ...

Specifications

Number Of Channels: 4
Sensor Type: CCD
Wavelength Range: 400-750nm
The DVΛ is an emission splitting system enabling a user to acquire two spatially identical but spectrally distinct images simultaneously. What distinguishes the DVΛ from the DV2 is that DVΛ can accommodate image sensors up to a 22 mm diagonal. Simultaneous, multichannel imaging is essential for colocalization, ratiometric analysis, ...

Specifications

Number Of Channels: 2
Sensor Type: sCMOS
Wavelength Range: 450-900nm
The Photometrics® DC2™ enables two-channel simultaneous imaging based on two distinct wavelengths or polarizations. Each channel is projected onto an individual CCD. Simultaneous multichannel imaging is essential to achieve quantitative emission ratiometric imaging.

Specifications

Number Of Channels: 2
Sensor Type: CCD
Wavelength Range: 400-750nm
The Photometrics® DV2™ utilizes a single-beamsplitter design to split the emission light from a microscope into two independent channels. Each channel is projected onto half of the CCD at the same time. Simultaneous multichannel imaging is essential for FRET and other emission ratiometric applications.

Specifications

Number Of Channels: 2
Sensor Type: CCD
Wavelength Range: 400-750nm

Frequently Asked Questions

Multichannel imaging systems are devices that allow for the simultaneous acquisition of multiple images or videos from different sources or perspectives. These systems typically use multiple cameras or sensors to capture images or videos from different angles or spectral ranges. They are useful in a wide range of applications, including microscopy, fluorescence imaging, and remote sensing.

The main benefit of using a multichannel imaging system is the ability to capture more information about a scene or object than is possible with a single camera or sensor. By combining multiple images or videos from different perspectives or spectral ranges, it is possible to obtain a more comprehensive understanding of the object or scene being imaged. This can be particularly useful in applications where high-resolution imaging is required, such as in microscopy and remote sensing.

There are several types of multichannel imaging systems available, including stereo imaging systems, multi-camera imaging systems, and hyperspectral imaging systems. Stereo imaging systems use two or more cameras to capture images from different angles, allowing for the creation of 3D images or videos. Multi-camera imaging systems use multiple cameras to capture images or videos from different perspectives, enabling the creation of panoramic or wide-angle images. Hyperspectral imaging systems use multiple sensors to capture images or videos at different wavelengths, allowing for the analysis of spectral signatures of different materials.

Multichannel imaging systems have a wide range of applications, including in microscopy, remote sensing, medical imaging, and robotics. In microscopy, multichannel imaging systems can be used to capture high-resolution images of biological samples from different angles or spectral ranges. In remote sensing, multichannel imaging systems can be used to obtain detailed information about the composition and structure of the earth's surface. In medical imaging, multichannel imaging systems can be used to obtain 3D images of internal organs or tissues. In robotics, multichannel imaging systems can be used to provide robots with a more comprehensive view of their environment.

The right multichannel imaging system for your application will depend on several factors, including the type of object or scene being imaged, the required resolution and spectral range, and the available budget. It is important to consider the specifications of each system carefully, including the number of channels, the pixel resolution, and the spectral range, before making a decision. Consulting with a supplier or expert in the field can also be helpful in choosing the right multichannel imaging system for your specific application.

There are 7 different Multichannel Imaging Systems from suppliers and manufacturers listed in this category. In just a few clicks you can compare different Multichannel Imaging Systems with each other and get an accurate quote based on your needs and specifications. Please note that the prices of Multichannel Imaging Systems vary significantly for different products based on various factors including technical parameters, features, brand name, etc. Please contact suppliers directly to inquire about the details and accurate pricing information for any product model. Simply navigate to the product page of interest and use the orange button to directly reach out to the respective supplier with one click.

Did You know?

Multichannel imaging systems are devices that enable the simultaneous acquisition of multiple images or videos from different sources or perspectives. These systems typically use multiple cameras or sensors to capture images or videos from different angles or spectral ranges. They are useful in a wide range of applications, including microscopy, fluorescence imaging, and remote sensing. One of the main benefits of using a multichannel imaging system is the ability to capture more information about a scene or object than is possible with a single camera or sensor. By combining multiple images or videos from different perspectives or spectral ranges, it is possible to obtain a more comprehensive understanding of the object or scene being imaged. This can be particularly useful in applications where high-resolution imaging is required, such as in microscopy and remote sensing. There are several types of multichannel imaging systems available, including stereo imaging systems, multi-camera imaging systems, and hyperspectral imaging systems. Stereo imaging systems use two or more cameras to capture images from different angles, allowing for the creation of 3D images or videos. Multi-camera imaging systems use multiple cameras to capture images or videos from different perspectives, enabling the creation of panoramic or wide-angle images. Hyperspectral imaging systems use multiple sensors to capture images or videos at different wavelengths, allowing for the analysis of spectral signatures of different materials. Multichannel imaging systems have a wide range of applications, including in microscopy, remote sensing, medical imaging, and robotics. They provide researchers, scientists, and engineers with the ability to obtain detailed and comprehensive images of the world around us. When choosing a multichannel imaging system, it is important to consider the specifications of each system carefully, including the number of channels, the pixel resolution, and the spectral range, to ensure that it is suitable for the specific application.