photometers (original) (raw)

Definition: instruments for measuring light properties such as irradiance or illuminance, or optical properties of objects

Categories: photonic devices, light detection and characterization, optical metrology

• optical metrology instruments

  • photometers
  • autocollimators
  • beam profilers
  • colorimeters
  • colorimetry
  • frequency metrology
  • laser beam characterization
  • optical energy meters
  • optical frequency standards
  • optical power meters
  • optical power monitors
  • optical profilometers
  • optical spectrum analyzers
  • optical time-domain reflectometers
  • powermeters
  • photometry
  • polarimeters
  • refractometers
  • spectrographs
  • spectrometers
  • spectrophotometers
  • wavemeters
  • (more topics)

• optical metrology

  • photometry instruments
    * photometers
    * luminous flux
    * luminous intensity
    * luminance
    * illuminance
    * luminous efficacy and efficiency

Related: irradianceilluminanceradiant fluxluminous fluxspectrophotometerscolorimetersphotodetectors

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Contents

What are Photometers?

The term photometer is used for a range of instruments with which one can measure certain properties of light, all related either to optical energies or to perceived brightness, or to related properties of objects.

Photometers for Radiometry

In the context of radiometry, one deals with physical properties of light or other kinds of electromagnetic radiation — independent of their visibility for the human eye. This implies that radiometric photometers can be applied not only to visible light, but also to infrared and ultraviolet light. Typical quantities of interest, which are measured with different kinds of photometers, are:

• the irradiance in SI units of W/m2, which in the context of laser technology is usually called optical intensity, and
• the radiant flux, which is otherwise called optical power and has units of watts.

For a given optical wavelength, the radiant flux from a source or an irradiance may e.g. be measured simply with a calibrated silicon photodiode. In the case of the total radiant flux, all incident light should be within the active area of the photodetector. For measuring an irradiance, the active area of the detector should be placed within a region of approximately uniform irradiance.

For broadband light sources, it is important to have a flat spectral response, i.e., a constant responsivity over the relevant wavelength range. If a photodetector does not naturally have such a flat spectral response, it may be equipped with a suitable optical filter. The resulting approximately flat responsivity will then of course be lower than that of the bare photodetector.

Further, there are photometers for measuring optical properties of objects such as their transmittance, their reflectance or the degree of light scattering. For example, the fractional light throughput of some partially transparent object may be measured by comparing the transmitted intensities with and without the object (e.g., some liquid solution in a cuvette) inserted. Using the Beer–Lambert law, one can then e.g. measure the concentration of an absorbing substance in liquid samples.

Photometers for Photometry

Figure 1: A multipurpose instrument which also serves as a photometer (luxmeter), displaying the illuminance on a desk.

Photometry deals with the perceived brightness of light. Typical quantities of interest are:

• the total luminous flux, which is e.g. sent out by a light source, specified in units of lumens (lm),
• the illuminance, which is the luminous flux incident on a surface per unit area, specified with the unit lux (lx) or lm/m2 (lumen per square meter), and
• the luminous intensity, which is the luminous flux per solid angle.

These quantities are related to radiant flux, irradiance and radiant intensity, but the contributions of different wavelength components are weighted with a luminosity function which takes into account the wavelength-dependent sensitivity of the human eye.

As in radiometry, photometric measurements on broadband light require an appropriate wavelength dependence of the responsivity of a photodetector. In this case, however, the responsivity should not be constant, but rather reflect the luminosity function of the human eye. That can again be achieved by equipping a photodetector with a suitable optical filter.

A common application of photometers is the measurement of the illuminance at work places. For example, it is recommended to have roughly 500 lx on office desks, e.g. when working with documents. For comparison, full sunlight corresponds to roughly 100,000 lx.

Another application is the measurement of the total luminous flux emitted by a light source. For a laser beam, this is simple because the total emitted light flux can easily be sent to a photodetector, e.g. in the form of a power meter. For light sources radiating in all directions, but not uniformly, one may require an integrating sphere photometer. For light sources with uniform emission in all directions, the total luminous flux can simply be calculated as the product of the illuminance, measured at some distance ($d$) from the source, and the area ($4 \pi \: d^2$).

Spectrally Resolved Measurements

Spectrophotometry denotes methods for spectrally resolved measurements. Spectrophotometers are instruments for measuring wavelength-dependent reflection or transmission properties of objects or substances. Also, there are spectrometers for measuring optical spectra of light sources.

If only color data are required, but not full spectral data, one can use some type of colorimeter.

Suppliers

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The DSP series combines two Class L photometers optimized for laboratory and goniophotometric use: the DSP 200 pairs cooled silicon photodiode detection with high precision analog front end and advanced digital signal processing for ultra fast, low noise measurements from 0.1 mlx to 200 klx, while the DSP 10 provides an extremely fast preamplifier (25 ksamples/s) for on the fly goniophotometry and robust PWM LED handling. Both instruments meet Class L (and DSP 10 also Class A) requirements per DIN 5032 7/CIE 69/EN 13032 1, support CAN bus system integration for goniometers and are suitable for measuring traditional lamps as well as pulse modulated LED sources.

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