World’s First emICCD Camera Delivers Single Photon Sensitivity and Subnanosecond Time Resolution

Share Article

Princeton Instruments announces the launch of an innovative new emICCD technology, available exclusively in their renowned PI-MAX® 4 camera platform. For the first time ever, one camera combines the advantages of intensifiers (i.e., ultrashort, subnanosecond exposure times) and the benefits of EMCCDs (i.e., linear gain and high quantum efficiency) to provide single-photon sensitivity and quantitative performance for scientific imaging and spectroscopy applications.

By intelligently utilizing both the intensifier (i.e., MCP) gain and the EMCCD gain, the detector provides a larger dynamic range than that of an intensifier alone.

For more than three decades, Princeton Instruments ICCD cameras have been the industry standard for time-resolved imaging and spectroscopy applications. The recently introduced PI-MAX4 series of cameras, for example, offers advanced capabilities such as less than 500 picosecond gating, very high repetition rates, RF modulation, and complete control via a truly revolutionary LightField® software platform with an oscilloscope-like user interface.

“Traditional intensified cameras, the workhorses of ultrashort, time-resolved applications, are limited by nonlinearity due to microchannel plate (MCP) saturation as well as an inability to distinguish single photons. Alternatively, EMCCD cameras, which have become the main tools for low-light applications, lack ultrashort (i.e., psec to µsec) gating capabilities,” observes Ravi Guntupalli, Vice President of Sales and Marketing at Princeton Instruments. “However, by combining these two key technologies for the first time, we have created unique emICCD cameras that are free of the aforementioned limitations, allowing researchers in combustion, ultra-low-light chemiluminescence imaging, quantum optics, and time-resolved imaging and spectroscopy to design experiments hitherto not possible.”

Explained briefly, in an emICCD camera, either a back- or front-illuminated EMCCD is fiberoptically bonded to a “latest generation” intensifier with an S20/S25, GaAs, or GaAsP photocathode for the highest light throughput. By intelligently utilizing both the intensifier (i.e., MCP) gain and the EMCCD gain, the detector provides a larger dynamic range than that of an intensifier alone. This wider linear range of operation is very useful for quantitative measurements in comparing bright and dark scenes within a single image. The same camera can be operated at the highest system gain to detect single photons, overcoming the excess noise limitations of typical “gain” systems. New emICCD cameras also feature a built-in, fully calibrated, high-precision timing generator with 10 psec time resolution for external synchronization. These high-frame-rate (>30 fps) cameras can be operated remotely via a Gigabit Ethernet (GigE) data interface.

All PI-MAX4 cameras are fully supported by Princeton Instruments’ LightField 64-bit data acquisition software platform, which has been designed “from the ground up” for scientific imaging and spectroscopy. LightField provides a visual, interactive timing-setup interface that makes even the most complex synchronization experiments a breeze. The platform remembers each PI-MAX4 user’s hardware and software configurations and tailors its own features accordingly, displaying all relevant tools via an intuitive graphical user interface.

For more information, visit

About Princeton Instruments
Princeton Instruments designs and manufactures high-performance CCD, ICCD, EMCCD, emICCD, X-ray and InGaAs cameras; spectrographs; and optics-based solutions for the scientific research, industrial imaging, and OEM communities. We take pride in partnering with our customers to solve their most challenging problems in unique, innovative ways. Princeton Instruments is a registered ISO 9001:2008 company. For more information on Princeton Instruments products, please visit

Share article on social media or email:

View article via:

Pdf Print

Contact Author

Debby Flint-Baum
Visit website