• Teledyne Princeton Instruments

    Trenton, NJ 08619

    COMPANY OVERVIEW

    About Teledyne Princeton Instruments

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    3660 Quakerbridge Rd
    Trenton, NJ 08619
    United States
    http://www.princetoninstruments.com
    609-587-9797
    609-587-1970

    More Info on Teledyne Princeton Instruments

    Designs and manufactures high-performance CCD, ICCD, EMCCD, sCMOS cameras and spectrographs, for research, industrial and OEM applications. PI takes pride in partnering with researchers to solve their most challenging problems.

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    Teledyne Princeton Instruments
    The 66 Mpixel deeply cooled COSMOS camera features large-area CMOS image sensor technology.
    Photo 236693909 © Marek Uliasz | Dreamstime.com
    Dreamstime Xl 236693909
    Let’s recap all the photonics business news that was announced in April 2022.
    Teledyne Princeton Instruments
    The LANSIS 261 CCD cameras also feature a 30.72 × 3.96 mm sensor.
    Teledyne Princeton Instruments
    The IsoPlane 320A spectrograph features a patented astigmatism-free Schmidt-Czerny-Turner aberration-corrected optical system design.
    FIGURE 1. Triple spectrograph in additive dispersive mode of operation.
    With multistage spectroscopy, researchers can garner crucial information about materials’ internal properties, making them better able to investigate quantum and 2D materials....
    Teledyne Imaging
    The COSMOS large-format, back side-illuminated CMOS camera delivers over 50 fps for capturing dynamic events in astronomy.
    La Cera Pr Image
    LACera CMOS imaging technology has uses in applications such as next-generation genomics, astronomical photometry, and ultra-high-resolution x-ray and electron imaging.
    FIGURE 1. Spectral and spatial information on a two-dimensional spectroscopy camera.
    Multitrack spectroscopy collects and analyzes data from several input sources with just one spectrometer and detector.
    Teledyne Princeton Instruments
    The TPIR-785 Raman spectrometer is optimized for the near-infrared region.
    FIGURE 1. The key components of a Raman spectroscopy system are the laser, detector, spectrograph, and probe.
    Technology advances are enabling Raman spectroscopy for application as a clinical tool.

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    Michael Melle

    Product Manager

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    Additional content from Teledyne Princeton Instruments

    (Photo credit: SPIE)
    Attendees make their way into the SPIE Photonics West 2022 exhibition hall.
    Get a first look at what will be shown on the SPIE Photonics West 2023 exhibit floor.
    Teledyne Princeton Instruments
    The IsoPlane 81 compact, aberration-free, imaging spectrograph for UV to near-infrared wavelengths has use in microspectroscopy techniques such as Raman, fluorescence, and absorption...
    Teledyne
    The NIRvana SWIR camera has an InGaAs 640 × 512 focal plane array and a 20 µm/pixel sensor.
    FIGURE 1. Raman spectra of lipid-rich fat tissue (orange) and protein-rich muscle tissue (purple); the broadband, autofluorescence background is clearly visible in both spectra, each of which was collected using a similar acquisition time.
    New CCDs deliver 2–7X higher sensitivity in the wavelength range relevant for bio-Raman measurements and allow greater detection limits or shorter experiment times.
    The University of Tokyo, Japan Science & Technology Agency, Astrobiology Center, National Astronomical Observatory of Japan, and Instituto de Astrofísica de Canarias
    Content Dam Lfw Online Articles 2019 02 Muscat2 With Pixis Cameras See News Release For Credit
    The 2nd-gen Multicolor Simultaneous Camera (MuSCAT2) at the Teide Observatory (Canary Islands) will find transiting exoplanets.
    Teledyne Technologies will acquire Princeton Instruments, Photometrics, and Lumenera.
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    PI-MTE3 in-vacuum CCD cameras are engineered for direct detection in vacuum ultraviolet, extreme ultraviolet, and x-ray imaging applications.
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    Collaboration uses spectrometer on a novel pharmaceutical technology that enables close monitoring and control of drug manufacturing processes.
    FIGURE 1. A comparison (a) of the signal-to-noise ratio vs. photon intensity for two types of Zyla cameras made by Andor Technology to that of the company’s iXon back-illuminated electron-multiplying CCD (EMCCD) shows that the EMCCD is best for the lowest photon rates, including single photon counting, while sCMOS takes over for higher (but still very low) photon rates). The quantum efficiency (QE) of Andor’s Zyla cameras is optimized for use with a range of fluorophores (b).
    sCMOS cameras are now widely used in a variety of leading-edge microscopy techniques, as well as in astronomy and elsewhere.
    (Courtesy of BaySpec)
    FIGURE 1. This handheld 1064 Raman instrument for direct sampling (a) was released in 2010 by BaySpec (the handheld Raman product line was sold and transferred to Rigaku Raman Technology in 2011); a 1064 nm confocal Raman microscope was used to sample highly fluorescent amber at a 2 µm spot size (b).
    Raman spectrometers sensitively detect organic materials for bioscience, medicine, food and agriculture, and forensics.
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    The SpectraPro HRS-500 500 mm focal length spectrograph and scanning monochromator features high spectral resolution.
    FIGURE 1. Atomic emission lamp spectra acquired using InGaAs (blue) and CCD arrays (red) with a HRS-300 spectrograph and 600 g/mm grating at 1000 nm blaze are compared.
    Cameras with exceptional detection capabilities can be designed around high QE, back-illuminated CCD sensors, combined with advanced imaging spectrographs.
    Analysis of high-resolution intravital z-section imagery enables generation of 3D flow maps depicting the microvascular network in a healthy mouse brain; velocity is noted in μm/s.
    The particles provide a dramatically higher emission quantum yield, and can be easily modified for various functional-imaging applications.
    Content Dam Lfw Online Articles 2017 05 1706lfw Pro 5 Web
    The SpectraPro HRS-300 imaging spectrograph delivers the spectral resolution and astigmatism correction needed for advanced microspectroscopy and multichannel fiber applications...
    FIGURE 1. Absorption and emission cross-sections were determined for a Fe:CdMnTe sample at 80 K; the plot includes absorption features of water (H2O) and carbon dioxide (CO2).
    Specially grown Fe:CdMnTe crystal that emits in the 5 μm spectral region could be made wavelength-tunable in the future.
    (Pseudo-color image courtesy of Eliot Young, Southwest Research Institute, and R.J. Smith, Sommers-Bausch Observatory, Boulder, CO)
    FIGURE 1. A M37 star cluster image acquired using a Princeton Instruments KURO:1200B back-illuminated sCMOS camera.
    Back-illuminated sCMOS cameras provide the sensitivity and frame rates needed for applications with relatively short integration times, such as hyperspectral imaging, astronomy...
    Princeton Instruments introduces first back-illuminated scientific CMOS camera
    Back illumination boosts sensitivity while maintaining high frame rates.
    Content Dam Lfw Online Articles 2016 09 Fergie Spectrometer System Princeton Instrumetns
    The FERGIE aberration-free spectroscopy system features a low-noise, cooled detector that permits high-sensitivity spectral capture from 190 nm to 1100 nm.
    (Courtesy of BaySpec)
    FIGURE 1. Confocal measurements of fossil feathers embedded in epoxy and amber show keratin, but no carotenoid (yellow) contributions in their Raman spectra.1 The measurements were done with a BaySpec Nomadic confocal microscope (bottom) at 1064 nm, one of the microscope's three Raman excitation wavelengths (the other two are 532 and 785 nm).
    When paired with a high-resolution microscope, Raman spectroscopy opens a world of knowledge for scientists, doctors, and industrial researchers.
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    The SOPHIA ultra-low-noise cameras for low-light-level scientific applications use the company’s ArcTec thermoelectric cooling technology to bring the back-illuminated CCD to
    FIGURE 1. A typical spectroscopy system consists of a light source, optical fiber, spectrograph, and a CCD detector.
    Accurate, repeatable wavelength and intensity information is possible for a spectrometer using an LED source and nonlinear optimization by taking into account variations in system...
    FIGURE 1. The shape of Horiba's iHR550 imaging spectrometer is dictated by its requirements.
    Spectral imaging is finding more and more applications in life sciences, from noninvasive disease diagnosis to food processing. Various imaging spectrometers make those applications...
    (Image: Princeton Instruments)
    Researchers at the Optical Spectroscopy Group, Charles University (Prague, Czech Republic) and the Center for Oxygen Microscopy and Imaging, University of Aarhus (Aarhus, Denmark...
    Image courtesy of Saulius Juodkazis, Swinburne University of Technology, Melbourne, Victoria, Australia
    Array of golden chiral nanoparticles.
    Princeton Instruments, which makes low-light imaging and spectroscopic instruments, has highlighted the recent work of Saulius Juodkazis, professor of nanophotonics at Swinburne...
    (Courtesy of Headwall Photonics)
    FIGURE 1. A hyperspectral image from Headwall Photonics' Micro-Hyperspec sensor was taken from a fixed-wing aircraft.
    Imaging spectrometers capture enormous quantities of data in a 2D form that is relevant to areas from science and security to industry and art.
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    While the 802 cm-1 Raman shift band of cyclohexane measured with a traditional Czerny-Turner spectrograph has a peak width of 9.16 cm-1, the same peak measured with an IsoPlane...
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    The ProEM+ series of professional-grade electron-multiplying CCD cameras for scientific imaging and spectroscopy applications is designed for very low-light applications.
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    The IsoPlane imaging spectrograph features a new optical design that eliminates the primary aberrations present in traditional imaging spectrographs.
    (Image courtesy of B&W Tek)
    Raman spectrometers, such as the NanoRam handheld spectrometer, require little to no sample prep for applications like drug identification or antioxidant measurement in skin.
    Spectrometers—instruments that measure light intensity or polarization across a specific segment of the electromagnetic spectrum to analyze and identify chemical composition—range...
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    With their high quantum efficiency and sensitivity in the important near- and shortwave infrared range, deep-cooled, large-format InGaAs focal-plane-array cameras have many applications...
    Princeton Instruments
    FIGURE. The Princeton Instruments SCT design eliminates field astigmatism, producing sharp point images across the field (top). A conventional Czerny-Turner design shows field varying astigmatism (bottom).
    Trenton, NJ--Princeton Instruments has introduced a new toroidal-mirror-based imaging spectrograph that includes a Schmidt corrector in its optics, completely eliminating astigmatism...
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    The PIoNIR:640 scientific-grade camera utilizes a 640 × 512 pixel indium gallium arsenide (InGaAs) focal-plane array with thermoelectric cooling down to -90°C.
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    The Megaplus ER11000 CCD camera has up to 96 megapixel resolution, based on a 36 × 24 mm, 11 megapixel sensor.
    FIGURE 1. Typical QE is compared for traditional front-illuminated CCDs, standard thinned back-illuminated CCDs, and back-illuminated deep-depletion CCDs (left); a similar comparison is done for eXcelon back-illuminated CCDs and standard back-illuminated CCDs (right).
    Conventional CCDs come in several forms, each with certain disadvantages for low-light imaging; a new take on back-illuminated technology resolves these issues while maintaining...
    FIGURE 1. Results produced with a low groove density grating (600g/mm blazed at 800 nm ) demonstrate the capability of the new calibration routine. The black line is the observed Ar/Ne emission line spectrum, while red overlaid curves are the result of a Lorentzian peak fit to selected lines in the spectrum. Located above and to the right of each red peak fit are the known and calculated wavelengths of the emission lines. The spectrum was taken on an Acton Series 500 mm spectrograph with a PIXIS 1340 x 400 pixel camera and 20 micron slit width.
    How accurate is your spectroscopy data? If only you really knew.