Laser Probe Inc.

Laser Probe continues the proud tradition established by the LPC Radiometric Division as a market leader in the laser measurement field.

  • 315-797-4492x304
  • 315-797-0696
  • sales@laserprobeinc.com
  • 2145A Dwyer Ave.
    Utica, NY 13501
    United States

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Showing results: 1 - 10 of 10 items found.

  • Power Meters

    Rk-5700 - Laser Probe Inc.

    The Rk-5700 Series Power Meters accept a wide variety of probes – pyroelectric, silicon, and thermopile – enabling them to perform absolute radiometry, total laser power (cw and average), and irradiance measurements from the UV to far-IR, pW to kW. Integrated lock-in amplifier circuitry allows for synchronous detection of chopped optical signals, improving both S/N ratio and background rejection. The dual channel Rk-5720 simultaneously measures Channel A, Channel B, and the ratio B/A. An IEEE-488 GPIB computer interface, Analog Outputs, Background Cancel, and Autorange are all standard features.

  • Power Probes

    RkP-400 Series - Laser Probe Inc.

    The RkP-400 Series probes consist of a compact head containing the detector and a preamplifier housed in a separate enclosure. The external dimensions of all the 400 Series Probes are the same, with identical detector planes, allowing for easy interchange of probes in an experiment. The heads have both ¼-20 and M6 tapped holes, a built-in 1” (25mm) filter holder, and a side-mounted BNC connector. Probe specific data, including spectral response curves and calibration dates, is stored in the preamplifier for access by the instruments.

  • Power Probes

    RkT Thermopile Series - Laser Probe Inc.

    The RkT Series thermopile power probes are ideal for measuring Nd:YAG, CO2, and other mid-power lasers. The probes are designed to withstand average power densities up to 20kW/cm2 (15MW/cm2 peak pulse power density). The flat UV to far-IR spectral response allows the probes to measure broadband sources as well. Measure the power of cw sources or the average power of sources pulsed at 5Hz or greater.

  • Energy Probes

    RjP-700 Series - Laser Probe Inc.

    The RjP-700 Series probes are designed to measure lower pulse repetition rate, longer duration pulses - up to 1msec pulse width at a maximum rep rate of 40Hz. This allows for measurement of pulsed flashlamps and other sources not possible with other probes. The combination of large area detector surface and long pulse width allow for measurements up to several Joules total energy. Integrated preamplifiers allow for longer probe-to-instrument cable runs, useful for manufacturing environments.

  • Energy Probes

    RjP-400 Series - Laser Probe Inc.

    The RkP-400 Series probes consist of a compact detector assembly, or head, and a preamplifier housed in a separate enclosure. The external dimensions of all the 400 Series Probes are the same, with identical detector planes, allowing for easy interchange of probes in an experiment. The heads have both ¼-20 and M6 tapped holes, a built-in 1" (25mm) filter holder, and a side-mounted BNC connector. Probe specific data, including spectral response curves and calibration dates, is stored in the preamplifier for access by the instruments.

  • Universal Radiometer

    Rm-3700 - Laser Probe Inc.

    The Rm-3700 Single Channel Universal Radiometer, when used with the correct probe, can measure cw and average power (in Watts), as well as the energy (in Joules) of individual pulses up to 2 kHz, over a wide range of intensities and wavelengths. A high-speed Rs-232 computer interface, full statistical analysis of pulse sets, battery/AC power, and audible tuning are just some of the standard features. This tremendous versatility makes it the ideal instrument for research labs, universities, hospitals, and other facilities with multiple light sources and applications.

  • Energy Meters

    Rj-7600 - Laser Probe Inc.

    The Rj-7610 Single Channel Energy Meter works with a variety of probes – pyroelectric, silicon, and thermopile – to measure true energy per pulse from single-shot to 40 Hz, picojoules to Joules, UV to far-IR. Sets of 10 or 100 pulses can be statistically analyzed (mean, minimum, and maximum energies, standard deviation), and data can be transferred to computer via the IEEE-488 GPIB computer interface or using the 0-10 VDC analog outout.

  • Energy Probes

    RjP-600 Series - Laser Probe Inc.

    The RjP-600 Series energy probes integrate the detector and preamplifier in the same enclosure, thereby maximizing signal integrity between the detector and preamplifier. This permits longer cable runs between the probe and instrument, as is often necessary in production environments. Probe specific information, like calibration date and wavelength response curves, is stored in the probe for access by the instrument. Other features include interchangeable filter holders and ¼-20 mounting hole.

  • Power Probes

    RkP-500 Series - Laser Probe Inc.

    The RkP-500 Series probes take advantage of synchronous detection (chopper/lock-in amplifier) technology to offer unparalleled background noise rejection, S/N ratio, and sensitivity. Total power, average power, and irradiance can be measured. The probes can be mounted directly onto the Rk-570C Optical Chopper to form an integrated measurement system, or the chopper can be operated remotely from the probe.

  • ECPR System (Electrically Calibrated Pyroelectric Radiometer)

    Rs-5900 - Laser Probe Inc.

    Developed in conjunction with NIST, the Rs-5900 ECPR is a ±1% absolute accuracy radiometric transfer standard for the visible to near-IR (0.25-2.0µm), with the RsIR Option extending the ±1% accuracy to >20µm. The RsP-590 Pyroelectric Probe requires no cooling and maintains ±1% accuracy from 1 µW to 100 mW. The ECPR uses an auto-nulling, electrical substitution technique that allows the instrument to be referenced against NIST electrical standards, insuring maximum accuracy and precision. Unlike most electrically calibrated radiometers, there is a direct correlation between electrical and optical heating because the same material serves as both the optical absorber and electrical heating element.

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