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P
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This method of polar alignment allows you to get the most accurate alignment on the celestial pole and is required if you
want to do long exposure deep-sky astrophotography through the telescope. To be able to do this type of
astrophotography you will also need to have an optional motor drive and other astrophotography accessories. The
declination drift method requires that you monitor the drift of selected stars. The drift of each star tells you how far
away the polar axis is pointing from the true celestial pole and in what direction. Although declination drift is simple
and straight-forward, it requires a great deal of time and patience to complete when first attempted. The declination drift
method should be done after any one of the previously mentioned methods has been completed.
For using this polar alignment method in the southern hemisphere, the direction of the drift described below is reversed
for both R.A. and DEC.
To perform the declination drift method you need to choose two bright stars. One should be near the eastern horizon and
one due south near the meridian. Both stars should be near the celestial equator (i.e., 0° declination). You will monitor
the drift of each star one at a time and in declination only. While monitoring a star on the meridian, any misalignment in
the east-west direction is revealed. While monitoring a star near the east/west horizon, any misalignment in the north-
south direction is revealed. It is helpful to have an illuminated reticle eyepiece to help you recognize any drift. For very
close alignment, a Barlow lens is also recommended since it increases the magnification and reveals any drift faster.
When looking due south, insert the diagonal so the eyepiece points straight up. Insert the cross hair eyepiece and align
the cross hairs so that one is parallel to the declination axis and the other is parallel to the right ascension axis. Move
your telescope manually in R.A. and DEC to check parallelism.
First, choose your star near where the celestial equator and the meridian meet. The star should be approximately within
1/2 an hour of the meridian and within five degrees of the celestial equator. Center the star in the field of your telescope
and monitor the drift in declination.
• If the star drifts south, the polar axis is too far east.
• If the star drifts north, the polar axis is too far west.
Make the appropriate adjustments to the polar axis to eliminate any drift. Once you have eliminated all the drift, move to
the star near the eastern horizon. The star should be 20 degrees above the horizon and within five degrees of the celestial
equator.
• If the star drifts south, the polar axis is too low.
• If the star drifts north, the polar axis is too high.
Again, make the appropriate adjustments to the polar axis to eliminate any drift. Unfortunately, the latter adjustments
interact with the prior adjustments ever so slightly. So, repeat the process again to improve the accuracy checking both
axes for minimal drift. Once the drift has been eliminated, the telescope is very accurately aligned. You can now do
prime focus deep-sky astrophotography for long periods.
NOTE: If the eastern horizon is blocked, you may choose a star near the western horizon, but you must reverse the
polar high/low error direction.