New Performance Enhanced Marana BI sCMOS Camera
New Performance Enhanced Marana BI sCMOS Camera
Oxford Instruments Andor, a world leader in scientific imaging solutions, has today announced the launch of a performance-enhanced back-illuminated sCMOS camera, further strengthening its broad portfolio of cameras for Physical Sciences and Astronomy.
The performance of the Marana 4.2B-6 back-illuminated 4.2 Megapixel sCMOS model has been significantly enhanced to widen its application appeal within Physical Sciences and Astronomy. A new Low Noise Mode reduces the read noise to 1.0e-. When combined with market-leading -45°C vacuum cooling and 95% QE, this pushes the limits of detection further, even under the most challenging, light starved imaging applications, enabling tracking of smaller Space Debris or NEOs, shorter exposures, lower illumination powers to protect photosensitive samples or the detection of trace concentrations of species.
A new High-Speed mode has been implemented to meet the needs of fast imaging applications such as trapped ion/atom quantum computing, solar astronomy, fast spectroscopy or hyperspectral imaging. By combining this mode with a 2-lane CoaXPress connection, 135 fps of sustained and stable high-speed operation is now possible.
Furthermore, a new Long Exposure Mode has been implemented which markedly enhances the exposure flexibility of Marana 4.2B-6. Amplifier glow has been a problem that has plagued most sCMOS sensors on the market. This new mode goes a long way to suppressing the effect of amplifier glow under longer exposure conditions. This is particularly relevant for fields such as astronomy and low light luminescence detection.
A ‘Global Clear’ mode has now been implemented for the Rolling Shutter sensor type. This mode purges charge from all rows of the sensor simultaneously at the exposure start. It can be used alongside a pulsed/triggerable light source, such as LED or Laser, to simulate a Global Shutter mechanism, useful for achieving tight synchronisation with other equipment and minimising exposure 'dead times'.
For further information please contact Michael Buckett, or read more.
