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How to Polar Align Easily: PHD2 Drift Alignment

Dylan O'Donnell telescope

By far the most frequently asked question I hear from beginners is “How the hell do I polar align my telescope?”.  Even at star parties, experienced users can be thrown off by a new location and suddenly need to relearn the art of accurate polar alignment.

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Typical PHD2 guiding configuration

Because I’m Australian, the methods described here are particularly sympathetic to those of us who can’t see, or don’t have a pole star like Polaris. We do, however, have everything else worth looking at in the night sky! (Feel the burn, northern hemisphere!)

This process is typically done with a guide scope and guide camera as pictured, but if you don’t have a guide scope you can do this with the main scope and a guide camera, as long as PHD2 supports the camera.

Preparation

You will need the following things:

  • A telescope and guide camera (usually a CMOS camera) that connects to the guide port on the mount
  • A laptop or computer with PHD2 installed from openphdguiding.org
  • A spirit level
  • A vague idea of where the south or north celestial pole is in the sky — a compass, smartphone compass, or planetarium will help you
  • An equatorial mount
  • Your exact latitude and longitude GPS coordinates, and date and time
  • The “setting circles” on your mount set to 0 when in the parked/home position

settingcircles

scp_03

What is the “celestial pole”?

It is the point in the sky that all the stars appear to be rotating around in a long exposure. It’s due south in the southern hemisphere, and north in the north, but its height in the sky varies depending on your latitude.

What is polar alignment?

Ultimately, all polar alignment really boils down to is that when your scope is in the parked / home position, it should be pointing exactly at the celestial pole. Easy right? Not really. The celestial pole is a very exact and virtually invisible point in space. We want to adjust the mount with precision until you are so well aimed at the pole that while tracking the apparent movement of the sky, only one axis of your mount (right ascension) is moving (in theory).

Once polar aligned accurately and with a few synced alignment points, your mount GOTOs will work better, targets won’t drift out of frame, you’ll be able to take short exposures without guiding, and very long exposures with guiding. Your images should also be free of field rotation distortion in the corners.

Step 1 – Rough it in

Plonk your mount tripod so that the scope would be pointing as close to south as you can guess. You could use a compass, BUT magnetic north/south is not actually the true north/south we want. We want to align the pole that the earth is actually spinning around. The compass is a lie!

By holding your smartphone planetarium in fast forward to the sky, you can find the celestial pole.

Here’s my trick. Use a smartphone planetarium app and look up and find a constellation or star near the pole. Or if you are setting up during the day, hold the app (I use SkyGuide) up to the sky and put it in fast forward. Boom – you can see the celestial pole because the stars are spinning around it! Point your tripod in that direction.

Don’t worry about being super accurate, just make sure the tripod is level for the mount. If you really screw it up too far from the pole and all your heavy gear is setup later, there’s no shame in putting your back into it and pretending to be Mr. Universe to lift and rotate everything a little bit. We’ve all been there. It works and is easier than stripping it all down to start again!

Step 2 – Start your engines

Set up the rest of your mount, telescope, and guide scope. Enter any calibration info your particular mount wants (date, time, GPS, etc.) and adjust the “ALTITUDE” axis (or as I like to call it, the uppy-downy one, as it makes your telescope go up or down) on the mount to match your latitude. E.g. – if your latitude starts with 28 or -28, the ALTITUDE on your mount needs to be angled at 28 degrees.

Once you’re set up and ready, do a star alignment as normal for your brand so the mount has some idea of where it is and starts tracking the approximate motion of the sky relative to earth (this is called sidereal motion).

Step 3 – Drift 1 at the celestial equator and the meridian

celestialequator
At the celestial equator the apparent motion of the stars is straight.

The celestial equator is 90 degrees away from the pole, so finding it is actually pretty easy. We are going to point the scope to where the celestial equator and the meridian meet.

Don’t worry if you don’t know what these mean exactly, just follow these next two quick steps and you’ll be in the right area.

 

 

First, manually slew your scope east-west until the counterweight bar is parallel with the ground. Use your spirit level to make sure it’s totally horizontal. It doesn’t matter which way you rotate.

Now here is where we need the setting circle. Slew the scope on the north-south axis until the setting circle on that axis says 90, assuming it was set to 0 in the first place.

Your scope is now angled at a point in the sky 90 degrees away from the celestial pole (not a 90 degree angle to the ground… unless you actually live ON the equator, then it would be!) and along the north-south meridian line.

Now fire up PHD2, connect your guide cam, find a star and tell it to guide. It will calibrate itself and start guiding, poorly. Stop guiding and go to TOOLS -> DRIFT ALIGN. There are two screens in here for the two drift aligns we will do – ALTITUDE and AZIMUTH. We are adjusting the lefty-righty one first so we want to be in “AZIMUTH ADJUSTMENT”.

phd-screen

Here’s the crux of this whole process. Pick a star and hit drift and wait a few moments. Click “trendlines” on the guiding graph if it isn’t already ticked. You’ll see the RED line drifting UP or DOWN instead of staying flat. Give it 10-30 seconds at least. Remember which direction it’s going, then hit the ADJUST button.

Now fiddle with your AZIMUTH adjustment bolts on the mount (see picture below). Try, say, adding half a degree. Then hit DRIFT again.

 

Did the RED line get closer to being flat? Or did it get worse? If it got worse, just click ADJUST and adjust the AZIMUTH angle on your mount in the other direction. If it helps, use the “Notes” section to write down your last steps, e.g. “red drifting up, turning left DEC screw…” or whatever you like. Repeat this process. DRIFT, ADJUST, DRIFT, ADJUST. You’ll soon get the RED line pretty flat. The magenta coloured circle around the star will get smaller and smaller with each adjustment. When it’s nice and small around the star – congratulations – one axis is aligned!

Step 4 – Drift 2 in the west. Or east. Doesn’t matter.

Point your telescope at a star or region of the sky roughly due east or west. Either is fine. Use your planetarium app on your smartphone to find something along the east or west lines of the sky and manually point to it. Ideally it should be low to the horizon if possible. Your guide camera will be able to see stars you can’t, just make sure you are generally pointing as west/east and as low as you can.

Head back to PHD2’s drift align tool and click on the ALTITUDE button, pick a star and hit DRIFT. Note the direction of the RED line and wait a few moments, then click ADJUST and this time, fiddle with the ALTITUDE (uppy-downy) adjustment bolts on your mount. Shift slightly in one direction, then click DRIFT again.

Keep repeating this (DRIFT, ADJUST) until you get that RED line as flat as possible and the POLAR ALIGNMENT number as low as possible. Don’t despair if you can’t get the error to zero, because you won’t be able to.  Some of that error is just the starlight twinkling and bouncing in the atmosphere and you won’t be able to adjust it out. Just get it as low as you can.

IMG_9226

Congratulations, you are aligned!      

At this point it’s best to do another star (or multi-star) alignment so the mount knows where it is again. Once that’s done you should be getting better GOTO slews, very little drift of your targets, and great guiding in PHD2 the next time you use it. If you did very well, you’ll even be able to do short unguided exposures.

There are lots of different techniques and tools for polar alignment, but any drift-based method uses some version of these steps.

If you have any tips and tricks for polar alignment, leave them in the comments below!

Thanks also to core PHD2 developers Bruce Waddington and Andy Galasso for their input and feedback on this tutorial. You’ll find Andy’s more thorough outline of PHD2 drift alignment here.

Dylan O’Donnell is an amateur astronomer and astrophotographer from Australia. He is listed in the credits for the open source project PHD2 for help redesigning UI elements, the PHD2 logo and the openphdguiding.org website.

BONUS TIPS

If you are at home, mark the ground where the tripod legs are. This will save you time when you rough it in next time.

If the mount isn’t changing locations, you shouldn’t need to do the east/west horizon / ALTITUDE drift alignment for a while. Just do the AZIMUTH / celestial equator drift alignment and you should be good to go.

If the weather is good, you can leave your gear set up for the next night, or take the telescope itself inside as long as the mount doesn’t move. Then you won’t need to do any alignment tomorrow, just switch on and start framing, guiding, and imaging.

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About the author

Dylan O'Donnell

Dylan O’Donnell is an Australian web developer, Director of DNA Digital and zen10 Australia and public science communicator. He has a Masters of Information Technology and his astrophotography been featured by NASA and ESA among others. He is also a member of Team Celestron where he also contributes. To date, two of his images have been selected for NASA Astronomy Photo of the Day (APOD).

See more of Dylan’s work on his website.

26 Comments

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  • […] explaining how you can use PHD2 to perform a drift alignment (PHD2 has a special mode for this): How to Polar Align Easily: PHD2 Drift Alignment • PhotographingSpace.com One other thing… when you start tweaking in adjustments on your mount, take careful note (e.g. […]

  • I’ve been playing with darv alignment which has been working for me of late. Same idea but using the main imaging camera and track pad to force and east then west movement over a 30s exposure. If the resulting image is a v you need an adjustment, if a flat line not. Better description herehttp://www.cloudynights.com/page/articles/cat/articles/darv-drift-alignment-by-robert-vice-r2760

  • Hi Dylan

    Excellent tutorial. I like the way you write.

    I have perhaps a stupid question: Why could I not do the Altitude adjustment using the same star used for the Azimuth adjustment? I am in the Hills District and it is impossible to catch a star (ANY star) East – Sydney’s light pollution wipes all out in that direction – and West is back wall of the house. Not textbook but what is the drawback of doing that?

    Suresh

    • Hey Suresh! Not a stupid question at all. I hear what you are saying. Once you have done this drift align method once, assuming you aren’t changing location, there is a “cheat” shortcut you can use on subsequent nights. I used it myself last night in fact as I was in a rush. You don’t need to do the western-star drift align, you can assume that’s fine since you haven’t moved. SO, in theory you can point to any star and with sidereal tracking enabled, watch it move on your screen in real time. If it’s moving, twiddle the N-S knobs of the mount until it stops. That’s it! It’s not ideal as going to the celestial equator will give you are star that moves most on the axis you are trying to align, but it will get you aligned quickly if you aren’t too worried about tuning it in very accurately.

      In your case you still really need to nail that East-West alignment at least once so the best you can do is try on a star in the direction even if it’s not low on the horizon, just on the East/West line is fine.

      • Hi Dylan, thanks for that.

        I think I can find something in the East above 30deg LATER in the night.

        Suresh

  • Hi Dylan…great write up! Thank you for doing this.

    I have a Celestron AVX mount, which has no setting circles. Do you have any tips on how to get pointed at the intersection of the meridian and celestial equator (Step 3) for this type of mount?

    Thanks!

    Matt

    • Hi Matt! I’m so sorry for not getting back to you earlier. I’m really unfamiliar with your mount so I just looked at the manual and you’re right.. no setting circles! How odd. If it were my mount, I’d probably just mark them out with white marker.. 0, 90, 180, 270 … 4 equidistant points around the circle, and always start on 0 in home position. A quick google shows other people generally find a star in the vicinity using a planetarium program on their phone or pc then use the hand controller to guide to it.. which is kind of fiddly but should work. Alternatively if you bypass the hand controller altogether and use planetarium software to drive the mount, then you can just tell it to go to the meridian and celestial equator with a click. Hope this helps! And again.. so sorry for the delay. I just hesitated because I’m not familiar with that mount. Clear skies!

  • Hi Dylan,
    On your step “First, manually spin your scope east-west until the counterweight bar is parallel with the ground. ” I have found that by slewing it to parallel, that works much better. I kept getting a horizon limit on eqmod and this avoided it.
    Secondly, if using eqmod I also made sure “sidereal” was enabled right at the start. That’s not explicitly stated, but if it’s not tracking then doing drift alignment doesn’t work.

    Also as a final note to beginners, if you notice that your drift alignment works well for the first 30 seconds, then starts to go south (figuratively speaking) then it’s likely your leveling of the mount. I made that mistake the first couple of times.

  • Hi Dylan:

    Excellent tutorial.
    But I’m somewhat confused with this statement on step 3, and want to make sure I understood right.

    “Did the RED line get closer to being flat? Or did it get worse? If it got worse, just click ADJUST and adjust the ALTITUDE angle on your mount in the other direction.”

    Is this correct?

    Thanks,

    Hector

    • Hi Hector,

      Yes, I believe you’ve got it. Basically, you want to adjust the angle (altitude in this case) to get the red line to move as close to the middle (flat), as you can. The red line is the overall average drift of the mount over time, so if it’s nice and flat, you know you’ve got it nailed.

      I hope that makes sense!

      Cheers,
      Cory

    • Hi Dylan

      Thanks for your reply. What got me somewhat confused was that at this phase you are explaining the AZIMUTH adjustment and thought I should concentrate on adjusting the AZIMUTH adjustment bolts on the mount (lefty-righty).

      As soon as weather permit I will try it.

      Thanks,

      Hector

      • Hi Hector,

        OH! I see what you mean! Yes, there seems to be an error in the article, I’ll have Dylan take a look and correct it to be sure! So sorry!

        Cheers,
        Cory

  • Dylan,
    After watching and reading countless rather obscure tutorials on polar alignment… yours is the one that really made the difference. Your article is short but to the point. Your images of the scope position was the key for me to understand.

    Now i can polar align in less than 7 minutes in most of my nights… thanks to you for your excellent tutorial.

  • Hi – this sounds very interesting, as someone just getting into this stuff in Australia, but I have a question:

    In your list of equipment, you include:

    “A telescope and guide camera (usually a CMOS camera) that connects to the guide port on the mount”

    I have an EQ3-2 mount, a CMOS camera, and a laptop, but I do NOT have an autoguiding setup (I have a ‘dumb’ dual axis motor drive setup). Will this technique still work?

    I.e., can I use PHD2 in this way even though I have no way for it to give any feedback by adjusting the motors in my system, simply by hooking up my CMOS camera to my laptop directly?

    • Hi Paul,

      My apologies for the long delay! 🙂

      I’ll reply for Dylan here: Technically you could use this method, yes. But I’m not sure if the software would let you, as it attempts to automatically turn off the motors to let the start drift, which you’d have to do yourself. If you can let the software *think* it turned off the motors, and it still goes forward, it would work, yes.

      However, with a more manual setup like that, I’d highly recommend doing a standard “old school” drift align, maybe. You can use PhD and your guide camera, utilizing the grid and crosshairs instead of a reticle eyepiece. It works great!

      Cheers, and clear skies!

      Cory

  • Polar alignment with PHD2
    In your article you talk about aligning the polar with the guide camera, but can the main camera, a Canon 500D, be used for alignment?
    If possible, how can I do it? ”
    Thank you

    • Hi Julio,

      The main imaging camera, like your Canon 500D, for example, is not compatible with PhD, no. So, you would not be able to use it for polar alignment using the PhD method.

      However, you WOULD be able to use the main imaging camera to do a drift alignment if you utilize the on-screen grid as a reference. I hope to do a tutorial on “easy drift alignment” sometime soon!

      Cheers,
      Cory

  • Hello Dylan,

    I live in kolkata, India..which is in Northern Hemisphere as you know..and from my location North and East is blocked..this method looks very handy and user friendly to me..instead that i will point my scope in the northward direction..isn’t it? Will the rest methods be the same? I use a Bresser EXOS II GOTO EQ5 mount . It has no Dec circle.
    Please tell me.

    • Hello Mainak,

      In the north, you would point your scope SOUTH to drift align with PhD.

      To drift align and adjust the azimuth axis, the scope needs to be pointed SOUTH when you are in the northern hemisphere. The principles are the same. The main idea is that it must be pointed OPPOSITE the celestial pole for the hemisphere where you are located.

      In the southern hemisphere, we aim the scope NORTH to adjust the azimuth axis. In the northern hemisphere, we aim the scope SOUTH to adjust the azimuth axis.

      When adjusting the altitude axis for polar alignment, you can use either the East or the West.

      I hope that helps!

      Cheers,
      Cory

      • Hi Cory,

        I live in Germany and from my balcony I have only south west/east view. Sadly, polaris is at the opposite side of the house. From what I understand from your reply to Mainak, my telescope is already pointed at the South. So I guess this method should work for me as well. At least I hope so.

  • Greetings from Switzerland Dylan !

    Thank you for this excellent article.

    Please allow me a question though : I am about to have my fork-mounted Meade (wedge) installed on a permanent pier. Usually, from October to March, I am able to see Polaris from backyard. However, as springs is nearing, I won’t be able to see Polaris anymore. Hence my question :

    – by roughly pointing my pier to Polaris (or true North), and then using the declination drift method via PHD2, would I need to align my pier each time I am imaging ? Usually, people just do an accurate polar align and then make some adjustment one a year (provided you have your scope on a permanent pier).

    I would be grateful if you could help me.

    Regards and all the best.

    Aygen

  • Hi There,
    I made a neat pdf file of the whole process so anyone can bring it out in the field using their tab or phone. How can I pass this to the author for all to download if the author so wishes.

  • Thanks for this Dylan,
    I had a eureka moment reading about the planetarium/speed up solution for rough polar alignment before drift aligning in PHD2. If only I’d known that when I started. I don’t trust the smart phone compass any more, especially near metallic objects like mounts – but they ARE good for levelling.

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