How we Measure the Distance to Stars

Someone asked me last week how we know how far away the stars are if we can’t travel to them. Whenever someone asks me an astronomy/physics related question I try to give a clear concise answer to the best of my knowledge. Afterwards, I always think of better ways I could have explained the answer. Now I’ll take the liberty of using my blog as a medium for explaining this concept. First look at the following diagram. 

There are actually a few different ways to measure the distance to stars but the first method scientists used is called stellar parallax. This method only works for close stars (relatively speaking) and uses a phenomenon with which we can experiment with our own eyes. Hold your finger at arms length and look at it with one eye open. Note what lies behind it in the background. Now switch eyes and see how your finger has “moved” with respect to the background. That is called parallax. Do it with the stars and it’s called stellar parallax. If you can measure the angular distance that your finger has “moved”, and you know the distance between your eyes, you can calculate the distance from your eyes to your finger. The way we do it with the stars only differs in that we use the orbit of the Earth around the Sun to observe the “movement” of a star against a background of more distant stars. We know the distance from the Earth to the Sun to be ~93 million miles. We measure the annual amount of movement a star makes in arcseconds (an arcsecond is 1/60th of an arcminute which in turn is 1/60th of a degree. You end up using only half of that angle so as to achieve a right angle). Knowing that opposite angles are equal, we now have a right angle for which we know the length of one of its legs and the measure of one of its angles (in addition to the 90 degree angle). Using basic trigonometry we can take the tangent of the observed angle (called the parallax angle) and solve for the length of the unknown leg.

tangent = opposite/adjacent     , therefore

tangent(parallax angle) = (93 million miles)/(parallax angle)

The answer to this equation is the distance to the star. Scientist, however, typically forego this calculation and just measure stellar distance in a simpler unit called parsecs (parallax seconds). To measure in parsecs, simply invert the parallax angle (1/arcseconds). Then if a more layman unit is needed use a conversion factor. For example, 1 parsec is roughly equal to 19 trillion miles. The star with the largest known parallax angle and therefore the closest to our star is Proxima Centauri which exhibits a parallax angle of 0.77 arcseconds corresponding to a distance of 1.29 parsecs or about 24 trillion miles.

5 thoughts on “How we Measure the Distance to Stars

  • Toni Hansen says:

    Okay, remember when I told you about figuring out your dominant eye and you said I was full of crap? That parallax thing is the same thing! Point your finger at something with one eye closed, then open your other eye, see how the object moved, then look with both eyes. When you look with both eyes, does it look the same as when you looked with your left or your right? Bingo. Dominant eye. It’s the same exact thing that I was trying to show you in the store, except I was making a circle with my hand around the object instead of pointing at it.

    • wetjosh says:

      Yes I remember you telling me this and my position hasn’t changed – you’re still full of crap. Here’s an easy way to disprove your theory: take an object with sharp edges (I used the iPhone 4 on which I’m typing this comment but any cube-ish object will suffice) and hold it at half arm’s length. Line up the LEFT edge of the object with the line of sight of your RIGHT eye so that the RIGHT eye is on the verge of seeing the LEFT side but doesn’t actually see it. Now do your test. According to your test you will find your LEFT eye is the “dominant” eye. Now repeat the test but switching all the LEFTS with RIGHTS and vice versa. Now your RIGHT eye is dominant. Pseudoscience DEBUNKED.

  • Jeremy says:

    This was useful. Now I know how to measure exceptionally obese cats. My neighbor’s cat must be at least 3 parsecs wide.

    “You’ve never heard of the Millennium Falcon?…It’s the ship that made the Kessel Run in less than twelve parsecs.”
    ―Han Solo

Leave a Reply

Wordpress theme JaeDubya © 2019 | All Right Reserved | Designed & coded by J. Arthur Wetenkamp