UCL MSSL Swift USA Swift UK Grism Home

NOTE: The following describes the accuracy of anchor and wavelength for observations of the Grism+lenticular filter combination only.

Verification method

The wavelength calibration was verified using the new calibration file, and the calibration spectra. Of course, using the same spectra for deriving the calibration and verifying them is no more than a check that the wavelength calibration is internally consistent, but the number of free parameters in creating the wavelength calibration is kept to a minimum by using a simple scale factor to scale the Zemax model dispersion. The scale factor was allowed to vary over the detector as modeled by a smoothing bispline to fit the calibration observations.

How to find the spectra and wavelength accuracy plots of the wavelength calibration sources

There are for each of the 29 calibration observations figures showing the spectrum both as a function of wavelength and pixel position. These were not flux calibrated, so they are in the observed counts. They have not been shifted to adjust for shifts in anchor position, nor corrected any other way, since they serve to show the result of applying the wavelength calibration and anchor position determination to each spectrum. The estimated error has been derived from these spectra by determining the mismatch between the extracted spectrum and a reference spectrum. In order to make the data accessible and organise the data according to their anchor position on the detector, two clickable maps are provided on this page where clicking on the anchor position opens a page with the spectrum or accuracy plot.

A clickable map for count rate spectra

Here the count rate calibration spectra can be found. The top panel as a function of fitted wavelength, the bottom panel as function of pixel coordinate. The stronger lines have been identified and a vertical line has been plotted at the correct wavelengths. Any shifts between the predicted line position and the actual spectrum can be seen in the top panel as an offset.


A Map for count rate spectra

Here the count rate calibration spectra can be found. The top panel as a function of fitted wavelength, the bottom panel as function of pixel coordinate. The stronger lines have been identified. Any shifts between the predicted line position and the actual spectrum can be seen in the top panel as an offset.


anchor position for clocked UV grism
WR121 sw00057520006_1 WR4 sw00056900002_1 WR4 sw00056900004_1 WR4 sw00056900003_1 WR86 sw00057000002_1 WR52 sw00056950004_1 WR52 sw00057914001_1 WR52 sw00057911001_1 WR52 sw00057912001_1 WR52 sw00057913001_1 WR52 sw00057918001_1 WR52 sw00057920001_1 WR52 sw00057926001_1 WR52 sw00057916001_1 WR52 sw00057924001_1 WR52 sw00057915001_1 WR52 sw00057922001_1 WR52 sw00057919001_1 WR52 sw00057908001_1 WR52 sw00057905001_1 WR52 sw00057909001_1 WR52 sw00057923001_1 WR52 sw00057925001_1 WR52 sw00057921001_1 WR52 sw00057906001_1 WR52 sw00057904001_1 WR52 sw00057901001_1 WR52 sw00057902001_1 WR4 sw00056900001_1
The count rate in the spectra can be seen to vary across the detector, which is particularly large in the left hand side of the detector, and is further discussed in the flux calibration.

How to read the wavelength accuracy plots

Wavelength accuracy plots were made for each useful calibration spectrum. The format of the accuracy plots is to have two panels.
Upper panel: Since the main variation of the dispersion can be represented by a constant with a linear term, those have been divided out in the top panel of the accuracy plot. The higher order terms are zero at the adopted anchor points for a perfect anchor position, which for the UV-clocked grism mode is ~2600 Å. The figures also show the dispersion from the scaled Zemax optical model for the appropriate position, as interpolated by a polynomial. After extracting the spectrum with the new calibration file, and measuring the line positions, the measured line positions have been plotted as blue dots.
The lower panel of these wavelength accuracy plots shows the remainder after subtraction of the predicted position. The measured position was found as a the pixel distance to the anchor point by applying the inverse dispersion relation, while the predicted position shows the correct wavelength. If the model dispersion is good, the difference can be divided into an offset and a random looking spread around that offset. The values for the offset and the standard deviation from the spread are given in the plot. In some points near the edges of the detector, the scaled model dispersion deviates and the points will not evenly be distributed around some mean offset.
At very long wavelengths, there appears a systematic growth in the difference, indicating that the linear scale factor of the Zemax model as derived from the calibration spectra is not sufficient. This was due to an error in the calculation of the Zemax model used. In version 2 (May 2013) of the wavelength calibration this has been corrected.
The upper left corner (low det-X, high det-Y) has no first orders because of the aperture effect from rotating the filterwheel. This also effects the flux calibration, which is discussed elsewhere.

A clickable map for wavelength accuracy plots

The map below provides links to the wavelength accuracy plots.

anchor position for clocked UV grism

WR121 sw00057520006_1 WR4 sw00056900002_1 WR4 sw00056900004_1 WR4 sw00056900003_1 WR86 sw00057000002_1 WR52 sw00056950004_1 WR52 sw00057914001_1 WR52 sw00057911001_1 WR52 sw00057912001_1 WR52 sw00057913001_1 WR52 sw00057918001_1 WR52 sw00057920001_1 WR52 sw00057926001_1 WR52 sw00057916001_1 WR52 sw00057924001_1 WR52 sw00057915001_1 WR52 sw00057922001_1 WR52 sw00057919001_1 WR52 sw00057908001_1 WR52 sw00057905001_1 WR52 sw00057909001_1 WR52 sw00057923001_1 WR52 sw00057925001_1 WR52 sw00057921001_1 WR52 sw00057906001_1 WR52 sw00057904001_1 WR52 sw00057901001_1 WR52 sw00057902001_1 WR4 sw00056900001_1

The calibration file used was swwavcal20090626_v2_mssl_uc160_wlshift6.1.fits. In some browsers the maps do not work. In that case the plots/images can be found here.

In part, the uncertainty in the position of the anchor point is due to a possible drift of the pointing during the observation which can typically be around 4 pixels, which for a dispersion of 3.2A/pixel translates to about 13A.