2.1

Calibration concept and traceability route

The general concept of the calibration of the radiometer is that the radiometer cavity is exposed to a known optical flux, provided by a laser. Considering the area of the cavity aperture, which is measured independently, the average irradiance level is determined. The radiometer reading will be then compared to the applied irradiance. The measurement range is 0.4 kW/m² - 18 kW/m². For a nominal aperture area of 1 cm², this corresponds to an applied laser power of 0.04 W - 1.8 W. The average irradiance level applied to the radiometer will be retrieved from the applied flux and the aperture area, following the basic measurement equation:

with E the average irradiance, Φ the incident flux and A the aperture area. The calibration thus breaks down into an optical and a geometrical measurement. The traceability chain is shown in Figure 1. A primary silicon-diode-based trap detector is calibrated against an absolute cryogenic radiometer (ACR), which is based on the same physical principle as the Kendall ESR, but reaches a measurement uncertainty below 0.05%, due to the low temperature of operation (typically 5-10 K) [9]. The responsivity of the trap detector (which is a configuration of 3 photodiodes, ‘trapping’ the incident radiation) [10], is calibrated against the ACR as a function of wavelength. For this calibration a comparator setup is used, based on a tunable monochromatic source (either a laser or a white light source combined with a double monochromator system) alternatively illuminating the ACR cavity and the trap detector. Similarly, the secondary working standard is calibrated against the primary detector. The final step is to calibrate the radiometer against the secondary standard (called reference detector) using a high-power laser source, having an output power of several Watts. As described in the next paragraph some additional steps are needed here to bridge the gap between the laser power and the maximum power that can be applied to the reference detector.

Figure 1.

Traceability route for a high-irradiance radiometer to a cryogenic radiometer

2.2

Optical flux calibration

The setup for the optical calibration is shown in Figure 2. First the reference detector responsivity is calibrated against the trap detector. Both detectors are mounted next to each other on a translation stage and exposed to the laser beam that is attenuated to values < 1 mW. The laser source is a diode-pumped solid-state laser, which emits a continuous wave at 532 nm, with a maximum power of 6.5 W. Calibration takes place by measuring the detector currents of both trap and reference detector after each other at various laser powers. Here a monitor detector is used to account for possible power fluctuations of the laser. For this measurement the beam size of the laser is limited to about 4 mm by means of an aperture, to ensure underfilling of the aperture of the trap detector (6 mm diameter).

Figure 2.

Top: Overview of the setup. A collimated laser beam from a diode-pumped solid-state laser is send to a variable attenuation system and beam shaping optics. The beam is split into two by a non-polarizing beam splitter (BSP). The reflected beam is attenuated by a 13 and 6 dB optical attenuator. The transmitted beam is sent to a translation stage and is detected by a trap detector, reference detector or the Kendall radiometer. The calibration setup is shielded by a light-tight box that consists of several compartments for stray light suppression. Bottom left: details of the attenuation system, based on a rotating half-waveplate and a polarizer (PBS). Bottom right: configuration of the beam shaping optics, generating a cut-Gaussian beam profile.

Since the maximum exposure of the photodiode-based reference detector is limited to an optical power of about 1 mW, direct measurement of the laser power that will be applied to the radiometer (> 1W) is not possible. In order to bridge this gap, a small fraction (about 10^-2) of the laser beam is reflected from a beam splitter and sent to the monitor detector (PD_mon). The light propagating towards PD_mon is further attenuated with neutral density filters (1.3 dB + 0.6 dB). Both the reference and monitor detector are Si photodiodes with an area of 18×18 mm². The current of each photodiode is amplified with a calibrated trans-impedance amplifier and the resulting output voltage is measured with a calibrated voltmeter. The signals from both PD_monitor and PD_ref are measured simultaneously and the ratio between these two signals is determined for various power levels. For this measurement the laser beam has been shaped such that it will underfill the aperture of the radiometer, while achieving highest possible flux levels. The ratio between the currents generated by PD_monitor and PD_ref is about 1.5×10^-4. The amplification factor of the transimpedance amplifiers are 10 kΩ and 1 MΩ for the reference and monitor detector, respectively. From this measurement the optical flux at the position of the reference detector is thus linked to the photocurrent of the monitor detector, which we refer to as ‘effective responsivity’.

Subsequently, the radiometer head is mounted on the translation stage instead of the trap detector. Calibration of the radiometer takes place by varying the laser power to values up to 1.8 W. The applied flux to the radiometer is determined from the signal of the monitor detector. Since the photocurrent through the monitor detector is much higher than during its calibration, the amplification factor has been reduced to 10 kΩ. The shape and power control of the laser beam applied to the radiometer is discussed in the next paragraph.

In the calibration procedure described above, the current measured by the monitor detector is changing over a large dynamic range (about 4 orders of magnitude), since the calibration takes place at much lower flux than the actual calibration of the radiometer. As a check whether the detector linearity is sufficient when covering this large dynamic range, the 13 dB attenuator in front of the monitor detector has been calibrated independently. Subsequently the monitor detector was calibrated against the reference in the same way as described above, but without the 13 dB attenuator in the beam, so a larger diode current was generated from the monitor. Then the ‘effective responsivity’ of this two-step approach was calculated from the filter transmission and the calibration of the monitor detector as performed without the filter. The relative difference with the single step approach as described above turns out to be < 0.1%, which underpins that no significant nonlinearity occurs in the single-step approach.

2.3

Power control and beam shaping

The optical power is controlled by an attenuation system consisting of a rotatable half-wave plate in combination with a polarizing beam splitter, dividing the total power between the calibration setup and a beam-dump. The half waveplate is used to rotate the polarization, while the polarizer is in a fixed position. This results in a beam with a well-defined and fixed output polarization after the attenuation system and a dynamic range of about 3 orders of magnitude.

One of the challenges of the calibration is to achieve an average irradiance level over the exposed surface of the radiometer as high as possible, while at the same time not exceeding a maximum irradiance level of 42 kW/m2 locally. Furthermore, the principle of the calibration requires that all the light that is sent towards the radiometer is reaching the absorbing cavity, i.e. the aperture must be underfilled.

To create a top-hat beam profile, a commercially available beam shaper has been included in the setup and the beam shape was optimized with two additional telescopes (a 2× magnifying telescope in front of the beam-shaper and a 1.5× magnifying telescope after the beam-shaper). With this configuration a top-hat beam with a diameter of 8-9 mm was created. The beam shape was measured with a line-CCD array. A typical shape of the beam profile is shown in Figure 3 (left). The beam profile as obtained with the top-hat beam shaper shows a strong variation of the irradiance level over the beam. To obtain a smoother beam profile an alternative route to shape the beam was investigated, by expanding the Gaussian beam shape and cutting the edges with an aperture (see Figure 2). This was implemented by using a 1:4 telescope for beam expansion and cutting the beam by a 10 mm fixed aperture, followed by a variable aperture set at about 9 mm. With this method a smoother beam profile is obtained, but a large fraction of the laser power is cut (about 45% of the laser power is sent to the radiometer, compared to about 85% for the top-hat profile). It was decided to calibrate the radiometer with this beam profile. To meet the requirement to stay below 42 kW/m², the applied flux was restricted to a maximum value of 1.8 W.

Figure 3.

Left: beam profile as measured with the top-hat beam shaper. Right: beam profile as measured with the cut-Gaussian profile.

2.4

Aperture size calibration

The diameter of the radiometer aperture is measured with a coordinate measurement machine, which has a measurement uncertainty < 1 μm. The diameter is measured at several positions to estimate the typical diameter variation. From the multiple measurements an average value for the diameter is calculated. The measurement method is contact-based, with a cylindrically shaped probe touching the edge of the aperture. A cylindrical shape is chosen because of the relatively sharp edge of the aperture that needs to be measured. In contrast to a spherical probe a cylindrical probe is much less sensitive to the exact depth of the probe into the aperture. The diameter of the cylindrical probe is 3 mm, which is chosen such that local spatial variations of the cavity aperture can be observed (roundness deviation). The applied force is about 0.2 N. A test was performed on a (relatively soft) aluminum dummy aperture at various levels of probing force, to see if any permanent deformation of the aperture edge was induced. No such deformation could be observed for the force applied in the actual calibration of the radiometer aperture.

Figure 4:

Mounting of the radiometer head on the coordinate measurement machine.

The diameter of the radiometer aperture is found to be (11.2766 ± 0.0025) mm. The measurement uncertainty (k=2) includes the deviation of the roundness. The corresponding aperture area is: (0.9987 ± 0.0004) cm². The relative measurement uncertainty of 0.04% is a minor contribution to the uncertainty budget.