2.1 Photometric accuracy

The uncertainties for the flux accuracy in Table 1 are given for sources observed in the central part of the detector array. The values are based on the analysis of observations of standard stars.

Note that although Polarization Observations (CAM05) are handled by the current version of the off-line software, the corresponding products have not been formally validated yet.

**Table 1:** Photometric Accuracy of V9.5
CAM AOT	mJy	mJy	Notes
CAM01 (staring)	20%	30%	-
CAM01 (micro raster)	10%	20%	1
CAM03	20%	30%	-
CAM04 (one way scan)	40%	40%	2
CAM04 (back and forth scan)	30%	30%	2
CAM05	-	-

Table NOTES:

The better accuracies can be achieved by the SLICE package within CIA (results soon to become available as post-processed archived products)

The distinction between one way and back-and-forth scans are nolonger relevant to LWS data processed using the OLP9.5 transient corrector

General notes:

The fluxes for point sources in the CPSL (CAM Point Source List FITS file) are derived by PSF-fitting in the image. These photometry values can have larger errors than stated in Table 1 if the fitting is incorrect.

Because of wheel-jitter the ``library'' FlatField may not cover the same detector region as the sky image does. The effect is small in the central region of the array where the uncertainty is less than 1%. The uncertainty becomes however very large near the edges (up to a factor of 5 in extreme cases), where vignetting is important (for example in the case of a $6^{\prime \prime}$ PFOV measurement).

Most CVF observations are performed after a discrete filter observation thus implying a large decrease in the incident flux on the detector. This may lead to important transient effects that may last several readouts and hence several wavelength steps. The down transient is not always well corrected by the transient algorithm in OLP9.5; the result is a larger than true flux for the first wavelength steps.

CVF observations are affected by the existence of ``ghosts'', i.e. bogus images generated by multiple reflections between the detector and the CVF surface. Ghosts can appear away from the source image but may also fall onto (and surround) the sky image, depending on the actual position of the source on the detector.

2.2 Astrometric accuracy

CAM's astrometrical calibration is based on the premise that the optical axis of the telescope intersects the detector at pixels [16.5,16.5]. This is true when the lenses are centered with the optical axis. However, the lens wheels have a small amount of play within each motor step and hence a lens wheel may not come to rest exactly at its nominal position to better than a fraction of a step (one wheel turn equals 480 motor steps). This may lead to a bending of the optical axis along a direction perpendicular to the detector's columns, i.e. along the direction of the spacecraft Y-axis. As with the pointing error, all pixels are affected in the same manner.

A third error element is due to the ``pin-cushion'' effect: the lens magnification changes as a function of the distance from the optical axis on the detector plane. The distortion is about 1 PFOV in the corners of the array for a $6^{\prime \prime}$ PFOV measurement. The distortion is negligible in the case of a $1.5^{\prime \prime}$ PFOV measurement.

**Table 2:** Astrometry Accuracy of V9.5
Channel	Pointing error	Wheel Jitter
SW	$\simeq 1.5$ arcsec	$\simeq 1.5\times$ PFOV
LW	$\simeq 1.5$ arcsec	$\simeq 1.5\times$ PFOV

2.3 Spectral accuracy

**Table 3:** Spectral Accuracy of V9.5
CVF Segment	Error central pixels	Error border pixels
SW CVF	negligible	$\simeq$ Wavelength step
LW short CVF	negligible	$\simeq$ Wavelength step
LW long CVF	negligible	$\simeq$ Wavelength step

2. Accuracy of ISOCAM's OLP V9.5 products

2.1 Photometric accuracy

2.2 Astrometric accuracy

2.3 Spectral accuracy