Wide field landscape astrophotography is an impressive form of photography, and it’s accessible to nearly everyone.
Astrophotography in its simplest form is increasing in accessibility, especially with today’s affordable, large sensor, high signal-to-noise ratio digital cameras. In my opinion, there are few photographs that have as much existential impact as a nighttime landscape against the Milky Way. Here, I will show you how to make an amazing photo of the Milky Way Galaxy with a minimum of effort and a minimum of equipment.
There are a few things that you will need. Here is a concise checklist of some of the most helpful things. Also check out my article on putting together your Beginner Astrophotography Kit.
- Digital Camera with Manual Controls
- Fast Lens (f/2.8 or lower, optional)
- Flashlight or Headlamp
- Intervalometer Remote Timer (Optional)
- Smartphone Star Map App (Optional)
- Dark Location at a Dark Time of Night
Digital Camera with Manual Controls
It is a common misconception that you need an expensive camera and lens combination to make a great Milky Way photograph. Pretty much any Digital SLR (DSLR) or camera with a Micro 4/3 sensor or larger is more than capable of photographing the Milky Way, especially when paired with the right lens. In fact, I’ve spent a lot of time testing the capability of certain point and shoot cameras and even certain smartphones that can photograph the Milky Way. DSLRs are generally the most common high performance cameras available and they offer an excellent price-to-performance ratio. If you’re interested, I personally use or recommend the following modern camera systems, but there are a plethora of other models that will work great. It’s likely that the camera you already own will work just fine.
- Full-Frame Mirrorless: Sony a7S ( Amazon )( B&H )
- The Sony a7S, more than any other camera currently available on the market, is my absolute favorite camera for night photography. It’s sensor, while only 12 megapixels, is particularly good in low-light and that makes shooting the Milky Way super easy.
- Full-Frame DSLR: Canon EOS 6D ( Amazon )( B&H ) with Magic Lantern
- APS-C Mirrorless: Sony a6000 ( Amazon ), Fujifilm X-T1 ( Amazon )( B&H ) (Updated: Apr 16, 2015)
All told, don’t get too hung up on what camera to use. The above ones are some of my favorite but almost any decent digital SLR is capable of shooting the Milky Way and it’s likely that the camera that you already own is worthy of trying.
Buying a good and professional camera is expensive. For those who may want a good camera, but have a limited budget I’d personally recommend this services for financing.
Fast Lens (Optional)
Let me start by saying that the kit (likely an 18-55mm f/3.5-5.6 or similar) lens that came with your camera is a fine lens to start with. If you’re just getting into trying to shot the Milky Way, stick with what you’ve got. The image below was made with the regular Canon T2i (a much older model) and the Canon 18-55mm f/3.5-5.6. I set it to 18mm and f/3.5, shot a 30 second exposure at ISO 6400 and I think the results turned out great for such a cheap lens. I am often asked the question: “I have such-and-such DSLR with the 18-55mm f/3.5-5.6 kit lens. Can I photograph the Milky Way with it?” The answer is absolutely yes!
Learning to shoot within the limits of equipment you have is always the first suggestion I make to readers. After a few nights of shooting you’ll start to learn the limits and figuring out what direction to go next will be a lot easier when you’re finally ready to upgrade. Once you’re convinced that you want to improve your results with equipment, some of the information below will be helpful:
In an older revision of this article, I talked about the merits of needing and using a “fast wide angle lens” for astrophotography. But with a bit more experience behind my belt and some more acquired knowledge, I’ve made an amendment to the suggestion and removed the “wide angle” requirement and instead suggest having pretty much any fast lens from 8mm to 50mm, especially an affordable, relatively fast, 35mm to 50mm prime lens with an f/number of f/2 or lower. The advantage of using a longer (less wide) fast lens are two fold: they tend to be cheaper and they can provide extra resolution and light gathering when compared to their wide angle brothers. In order to capture a wider field of view with these longer lenses, it’s possible to stitch together multiple frames for a high resolution panorama with quality levels exceeding those of an expensive medium format camera. Here’s my original suggestion below:
A “fast” wide angle lens will give you the best results when photographing the Milky Way. The important traits are a low aperture f/number rating and short focal length. The lower the f/number rating, the faster and better the lens will be for really dark shooting conditions. Most digital camera kits come with the ubiquitous 18-55mm f/3.5-5.6. While the minimum f/number of that lens (at 18mm) is f/3.5 is a little bit “slow” for Milky Way photography, you can still squeeze by with a slower kit lens like the common 18-55mm. Keep in mind that you will actually see a tangible difference with a faster lens that has a lower f/number rating.
For the most significant improvement in the quality of your landscape astrophotography, I recommend a wide angle with a focal length of about 35mm or less on full-frame cameras, 24mm or less on APS-C cameras and 16mm or less on Micro 4/3 cameras. The Milky Way takes up a huge portion of the night sky and so a lens with a wide field of view will make it easier to capture as much of it as possible. The wider field of view will also allow us to use longer shutter times to gather more light without seeing the effects of the earth’s rotation as star trails. The shorter the focal length, the wider field of view of the lens. If you’re interested in the technical reasons for what makes a good lens for astrophotography, check out my guide on how to pick a lens for Milky Way photography. My absolute favorite lenses to use for Milky Way photography are the following:
- Full-Frame: Rokinon 14mm f/2.8 (Amazon)(B&H) and Rokinon 24mm f/1.4 (Amazon)(B&H)
- APS-C: Rokinon 10mm f/2.8 (Amazon)(B&H) and Rokinon 16mm f/2.0 (Amazon)(B&H)
- APS-C Mirrorless: Rokinon 12mm/2.0 (Amazon)(B&H) and Rokinon 8mm/2.8 Fisheye (Amazon)(B&H)
All of these lenses are relatively affordable and are excellent for nighttime landscape photography. They are available on a wide range of camera mounts including Canon, Nikon, Sony, Olympus, Fuji, and Samsung. You will be hard pressed to find better lenses for night photographs any price. For a more complete list of the best lenses for photographing the Milky Way on your camera system, check out my best lens lists:
- Best Lenses for Milky Way Photograph for Canon
- Best Lenses for Milky Way Photograph for Nikon
- Best Lenses for Milky Way Photograph for Fuji
There’s nothing special to remember for your tripod choice, just make sure it’s stable enough for your camera and is light and compact enough that you’ll actually want to carry it around with you. It’s not very fun lugging around a heavy tripod, even if it could support an aircraft carrier. I personally use: the Sirui T-025X( Amazon )( B&H ). One recommendation I always make for photographers looking to buy a tripod is to find one with a ballhead. It’s much easier to quickly re-compose a tripod with a ballhead than one with the more video-centric pan-tilt head. A super cheap yet high quality option for a tripod that I tend to suggest is the ultra cheap Dolica Aluminum or Dolica Carbon Fiber Tripods (Amazon).
Since you’ll be in the dark, a headlamp is pretty much a necessity. I think I once listed this a optional but it really isn’t. You’ll need to see in the dark so definitely make sure you have one. I prefer an LED headlamp with a red “night vision” mode. For a long time I used an older version of the Petzl Tikka XP. It can be switched to night vision mode without needing to cycle through the white lighting modes. This control scheme makes it possible to turn on and off the red mode without blinding yourself with the white mode first. Petzl headlamps are great. I’ve never had one fail on me, the batteries will last for over 7 days straight of continuous output and they do a great job of warning you when the batteries are low with a red blinking indicator. Even when they’re running out of juice, it will keep on lighting for an extended period of time at reduced output so that you aren’t left in the dark.
I’ve recently started recommending the newer Tikka R+ headlamp for its USB rechargeable Lithium Battery. It has all the functionality of my older XP headlamp (red night vision mode, variable brightness, waterproof, etc.) but can also be easily recharged via USB so I can keep it juiced up from a variety of power sources like my car, a lithium Battery pack, or even a solar charger.
Intervalometer Remote Timer (Optional)
An intervalometer will allow you to trigger your camera remotely without needing to touch the camera. This is particularly nice to prevent vibration in the camera that can add blurring or streaking in your images. An intervalometer will also allow you to make timelapse sequences and allows you to program exposures longer than 30 seconds when your camera is in Bulb (B) exposure mode. From experience, I particularly recommend theNeewer Intervalometers. They’re less than $20 and have never failed me. Plus, they use AAA batteries just like the my headlamp so I don’t need to carry two different types of batteries. Check if your camera has a built-in interval timer too. Some models like the Nikon D7100 have the functionality built in which makes it great for timelapses. If you’re using a Canon EOS camera, I recommend checking out the Magic Lantern firmware hack. It will enable all kinds of extra functionality like a built-in intervalometer and programmable Bulb timer.
Keep in mind that there are a lot of cameras that feature built in intervalometers (a list of cameras that d0). My Sony a7S and a7II have a built in timelapse apps that allows me to make timed exposures without the need to buy an accessory. Check your camera’s manual to see if your camera has a built in intervalometer.
Smartphone Star Map App (Optional)
One of the first challenges of photographing the Milky Way is knowing how to find the Milky Way in the night sky. I personally use and recommend Stellarium for Android oriOS. Stellarium shows a map of the stars with the plane of the Milky Way in view so you can more easily figure out where to point your camera. There are also a number of free applications like Google Sky Map for Android or Night Sky Lite for iOS that will help you find out where the Milky Way is in the sky at any given time of year.
The free apps work great if you’re just starting out. Two other great photo planning applications are PhotoPills for iOS and The Photographer’s Ephemeris for Android andiOS which will allow you to plan for the phase of the moon, moonrise, moonset, sunrise and sunset. The brightest part of the Milky Way is near the constellations Sagittarius and Scorpius but those constellations aren’t completely visible all year or in all parts of the world. To find the plane of the Milky Way at any time of year and in any part of the world, you’ll want to look for which of these constellations will be visible on the night you take photographs:
- The Summer Triangle
Use the app to familiarize yourself with where those constellations are. That’s where you will be pointing your camera. If you don’t have a smartphone, I recommend checking out the free and open source software Stellarium for Mac, Linux or PC.
Check out a more detailed list of tools and tips for finding the most important constellations in the night sky in my How to Find the Milky Way article.
Dark Location at a Dark Time of Night
Of all the items on the list above, a dark location is probably the hardest thing to find. Two-thirds of the United States population are unable to see the Milky Way Galaxy due to light pollution. Unless you are lucky enough to live in a remote rural location with super dark night skies, you will probably need to make a trek out somewhere relatively remote in order to photograph the Milky Way. This is a great opportunity to explore new places.
If you live in North America, check out Dark Sky Finder, or the Clear Sky Charts on cleardarksky.com. Both have light pollution maps and Clear Dark Sky has weather and seeing forecasts for locations with the darkest skies. If you live elsewhere in the world, check out The World Atlas of Artificial Night Sky Brightness and the Blue Marble Navigator. I recommend finding publicly accessible lands like national parks and state parks as they’re often located away from cities and usually feature unique and beautiful landscapes. Once you pick your location, plan on venturing there some time between the last quarter and first quarter of the moon calendar, ideally during a new moon. This is not a hard rule, but the closer date to the new moon, the more time you will have during the night with dark, moonless skies.
Making the photo
Now that you have all your equipment, are in a beautiful outdoor location with dark skies and have located the Milky Way with your smartphone app, you are ready to make a photograph. There are a number of things that you’ll need to do to make a successful exposure of the Milky Way. Here’s a checklist of what we will cover.
- Setup your Camera
- Focusing in the Dark
- Choosing your Exposure
- Exposure Adjustment
Setup Your Camera
I am going to suggest some settings that will be a good ballpark start for your exposure. You may not even have to change them for your final exposure but that will depend on things like moonlight, light pollution, your camera, and your lens. We will start here and adjust accordingly. You should be familiar with each of these settings and how to change them. If any of these settings are unfamiliar to you, review your camera’s manual for how to change the setting.
- Shoot in RAW recording mode
- RAW image files contain more data than JPEG files and thus allow for greater flexibility in post-processing adjustments.
- Zoom out to the widest field of view your lens supports (24mm or wider)
- The wider field of view will reduce streaking of the stars due to Earth’s rotation and will allow us to capture as much of the Milky Way as possible.
- Manual focus
- Use manual focus (M or MF) mode on your lens and set it to the infinity mark if possible. We will focus more precisely later.
- Manual exposure
- Set your exposure mode to Manual (M)
- Enable long exposure noise reduction (optional).
- This will reduce grain on your photos by taking a second photograph without opening the shutter to record and subtract noise data from your image. Note that this will usually add additional wait time to each exposure before you will be able to use your camera again for the next exposure. If your camera takes particularly low noise images, such as a Canon 6D, you probably don’t need to enable this feature.
- Enable the histogram in the image review.
- This will allow us to see a graphic display of our exposure and adjust accordingly.
- Use automatic white balance.
- Many things like light pollution or moonlight can change the white balance of the image so just set it to auto. Since we’re shooting in RAW, we can make adjustments to the white balance later. If you’re shooting a timelapse, a custom setting of 3900K or a setting of tungsten can prevent unexpected changes during the timelapse sequence.
The exposure settings that I recommend in a dark sky area are dependent on the type of camera and lens that you are using. Use the calculator below to determine the exposure that I recommend you use initially. Once you take your first exposure, you can adjust as necessary based on your exposure histogram.
- The shutter speed is calculated based on the focal length of your lens and the size of your camera’s sensor. Longer focal lengths and smaller sensors require shorter shutter speeds to prevent star trailing.
- The f/number should generally be set to the lowest possible number, preferably f/2.8 or lower if your lens supports it. Lenses with f/numbers of f/4.0 or higher are not recommended.
- The ISO is calculated based on your aperture and shutter speed but it’s a little dependent on the noise performance of your camera. Start with the calculator’s recommendation and adjust accordingly.
For a more complete explanation of how to figure out the exposure for shooting the Milky Way, visit my article on the Milky Way Exposure Calculator for a complete explanation of the calculations that are being used.
Focusing in the Dark
I like focusing before composition because it’s generally easier to focus your camera first, tape your focus ring, and then re-compose later. In general, you will want to make sure your lens is in manual focus mode (M or MF) and is focused at infinity. But rather than just setting the focusing ring to the infinity mark (on some lenses) and forgetting about it, we will want to make more precise focus adjustments to ensure the best possible photo quality. Here are a couple methods that I use to focus in the dark.
- Manual focus with Live View
- This is by far the most accurate method if your camera supports it. Enable live view on your camera and use the focus checking or the digital zoom function on a bright star to make the star appear like a pinpoint. I recommend centering the star in the frame before focusing on it to have the most even focus field. Note that you may need to change the Live View settings on your camera to “exposure simulation” or “manual,” in order to be able to see stars on the LCD. If you cannot see stars in the LCD, try focusing on a flashlight at a distance like in the method below.
- Auto focus or manual focus on a flashlight that is placed far away (greater than 100 feet or so)
- This can be an easy way to get your camera to focus at close to infinity in the dark but can be difficult if you don’t have a helping hand to hold the flashlight for you. It’s often best to place a flashlight next to an object in your frame that is at a distance of 100 feet or greater, the farther the better but after about 150 feet or so, it makes less and less difference. Plus, walking back and forth 300 feet just to focus your camera can be a drag. As soon as you get focus confirmation on the lit object, switch the lens back to manual focus (MF) mode to lock the focus at infinity, being careful not to twist the focus ring and mess up your focusing work. A flashlight can also be helpful if you wish to instead focus on a foreground object rather than infinity.
Regardless of the method of focus, make a test shot of the stars with the exposure settings above to check your focus. Zoom the LCD all the way into the image review to make sure that the stars look like pinpoints, if they are out of focus circular blobs, re-focus and check again. Always zoom the LCD into the preview review to check the focus, don’t take the initial thumbnail at face value. Once your shots are in focus, a piece of electrical tape or gaffer’s tape between the focus ring and the lens body can help prevent you from bumping the focus.
Understanding the Histogram and Adjusting Exposure
The settings that you calculated above when we setup your camera should be a good start. Once you are satisfied with your focus and your framing, the next thing is optimizing your exposure. This is where we will review the camera’s histogram information (The histogram is usually available by pressing “INFO” or “Display” or Up/Down arrows when reviewing photos. It really depends on your camera so check your instruction manual.) Typically we will desire a histogram that shows peaks toward the center of the graph from left to right. See below for examples of histograms for various exposures of the Milky Way.
Try to push your camera to the limits of its light gathering capability without compromising quality. Check and re-check your image review, zoom in on the LCD to check focus, review the histogram for exposure information and re-compose your frame throughout the night. Once you find an exposure you like, you can usually maintain the same exposure throughout the night.
If your image was exposed correctly, you should need only a little bit of post processing. RAW images are typically pretty flat and require some post processing to make the photograph as high quality as possible. I personally use Adobe Lightroom to process my photographs. The RAW editor that came with your camera is probably just fine. The thing to keep in mind here is that less is more. If you push the exposure of your photograph too much in post processing, you will often increase noise levels and reduce the quality of your photograph. For this reason, make your best effort to properly expose your photographs in the camera. There isn’t one right way to process your photograph and my methods might not be best for your particular shot but in general, I focus on just three things:
- White Balance
- Exposure (Brightness)
- Contrast (Curves)
Let’s take a look at an image as it came, straight from the camera.
White Balance Apparently, the color temperature of the Milky Way is about 4840K [pptx]. I find that 4840K is a little too yellow/orange in color, usually because there’s alway some influence from light pollution, no matter where you are in the world. A lot of astrophotographers swear by shooting in tungsten white balance (3200K) which will keep the stars looking blue. That said, I use about 3900K most of the time for my white balance setting but this may just be a personal preference. I don’t typically pre-set white balance on my camera when taking the shot. 90% of the time, I usually just leave it in auto white balance (AWB) unless I’m shooting a timelapse sequence where I’ll set it to roughly to 3900K.
When shooting in RAW, we can adjust white balance in post processing so the camera settings doesn’t matter that much. Try 3900K and adjust from there. Other factors like the moon and the sun can affect your white balance. Even if both the moon and sun are set below the horizon, they will continue to turn the sky a blue tint even an hour or two after they set, forcing the white balance to a higher temperature Kelvin. Adjust until you have a nice neutral picture:
Exposure (Brightness) Hopefully the exposure will require the least adjustment. (If you made a good exposure in the camera.) Here I will add about +0.5 Exposure Value (EV), which makes the photograph 50% brighter. Try to avoid adjusting more than +/-1.0 EV unless noise levels allow for it. You will discover that adjustments larger than +/-1.0 EV will increase noise levels too. The amount of post exposure adjustment necessary will depend on your exposure in the camera.
Contrast (Curves) Contrast is the final essential post processing adjustment to use. I tend to increase contrast as much as possible without blowing out highlight or shadow details. Curves adjustment allows for a more precise contrast adjustment of specific lightness values and is my choice for making detailed adjustments. With curves to can make just the darks darker and just the brights brighter. Lightroom also allows you to adjust only designated portions of an image using the graduated filter or adjustment brush tools.
That’s just about it! Even with a very limited set of tools, it’s possible to create some amazing photographs of our home galaxy. This lesson should have give you the most basic information needed to make some amazing Milky Way photographs. You have the tools, now all you need to do is let your creativity go crazy.