01-24-2017 03:18 PM
01-24-2017 03:47 PM - edited 01-24-2017 03:51 PM
Those sensors are not great at high ISO. Using a tripod you should be able to get a long exposure so you don't need high ISO. If you don't like star trails you can stay like 15 seconds or faster. If trails are ok you can leave open for hours.
Long exposures can also make a little noise but not as bad as high ISO, and not accompanied by loss of detail which is the other hobgobelin of high ISO.
You can can also try wider apertures to get more light.
01-24-2017 04:25 PM
01-24-2017 04:58 PM
@Tsleel2811 wrote:
I'm getting into astrophotography and I always see people shooting at iso 3200 and above. When I shoot people in a dimly lit room the noise is unacceptable even at 1600. Is there anyway to produce a good photo with a 60d at higher ISOs than 1600? Is it something in the settings? Or the exposure triangle?
There is no in-camera solution for high ISO except for the long exposure noise filtering option. Most people I know don't really like using it.
I don't really shoot astrophotography but have been using high ISO occasionally for birds in flight...For the 60D, 1600 is about the acceptable cutoff ISO without post processing help. With careful post processing you can get by with 3200. With some plugins like Imagenomic Noise Pro and others, you might be able to go beyond that.
@Another way to do it is to get higher end models with better ISO performance. For my 7D Mark II, I can use ISO 6400 with acceptable results (after post processing). I can go as high as 12,800 with my 5D Mark III. Below is a picture taken with the 7D Mark II @ ISO 6400... remember I use the term acceptable...not great.
01-25-2017 09:58 AM
@Tsleel2811 wrote:
I'm getting into astrophotography and I always see people shooting at iso 3200 and above. When I shoot people in a dimly lit room the noise is unacceptable even at 1600. Is there anyway to produce a good photo with a 60d at higher ISOs than 1600? Is it something in the settings? Or the exposure triangle?
I'm not really into astrophotography, either, mostly because I live too far away from any "dark skies".
As far as your noise goes, are you familiar with photo stacking? Dark frames? One crude way to reduce sensor noise to is to take a large quantity of identical photos, then use software to align the images. Once the images are aligned, they can be combined into a single image by averaging them together. Averaging tends to cancel out random noise, in much the same way that a long exposure of a lake, beach, or a river averages out waves, making the water appear as a sheet of glass.
01-25-2017 11:23 AM
01-25-2017 12:57 PM
@Tsleel2811 wrote:
I don't know what dark frames are but I'm familiar with photo stacking. What I'm looking for is to cut out extensive PP and get the best quality from one picture from a 60d. If that's not possible I'll proceed to photostacking
A dark frame would be long exposure with the lens cap in place. The captured image will noise from the sensor, which can be used to average out noise from actual images.
01-25-2017 06:50 PM
I posted a reply to your other post on astrophotography. Probably I need more info on what sort of imaging you are trying to do.
Photographing a landscape (with the night sky) is very different than photographing a deep-sky object (or even a large section of sky) with no "land" in the image.
What sort of imaging are you wanting to do?
01-25-2017 07:15 PM
01-25-2017 10:57 PM
To do night time landscapes the focal length of the lens limits the time of the exposure. The Earth is spinning at a rate of 15 arc-seconds of angular rotation per each second of time on the clock. If you use a very wide-angle lens, 15 arc seconds in one second is such a small amount that you'd hardly notice it until several seconds have elapse. But if you use a long focal length length (very marry field of view) than even a short exposure can be enough that the stars have moved a noticeable amount.
For a "full frame" camera you can divide 600 by the focal length of the lens to arrive at the maximum amount of time you should expose before the motion of the Earth smears the stars and they appear elongated instead of as points of light. But with an APS-C camera, you have to divide 600 by the crop factor of the lens (which is 1.6) so and that works out to 375.
So imagine if you have a 10mm lens ... that 375 ÷ 10 = 37.5 seconds. You can expose for 37.5 seconds and you wouldn't see any elongation in the stars. Some astrophotographers think that the original value of 600 is a bit too generaous and prefer to use 500 just to be extra sure there is no elongation. 500 ÷ 1.6 = 312.5 and if you had a 10mm lens that would be 31 seconds.
You have a 24-70mm lens. At the 24mm end that would be 312 ÷ 24 = 13 seconds. You might be able to cheat that up to 15 seconds. But it's not much time. Now imagine using your 70-200mm at the 200mm focal length end... that's 312.5 ÷ 200 = about 1.5 seconds... which is not nearly long enough to collect starlight.
You can quickly see why a short focal length lens helps with this sort of phototography. But even then there's the question of focal ratio. For example an f/1.4 lens collects literally four times more light than an f/2.8 lens. Suppose (hypothetically) there's a 20mm f/1.4 lens. The focal length is double a 10mm lens. So instead of 312 ÷ 10 = 31 seconds it works out to 312 ÷ 20 = 15.5 seconds. But an f/1.4 lens collects FOUR times more light per second than an f/2.8 lens. So even if we cut the exposure time in half, the fact that we gather four times more light "per second" still works out to collecting twice as much light in in 15 seconds as the f/2.8 lens can collect in 30. It's "as if" you could take a 1 minute exposure in just 30 seconds.
So while a shorter focal length is helpful... a lower focal ratio is is also helpful. Sometimes a slightly longer focal length but a substantially lower focal ratio means the lens with the lower focal ratio "wins" in the total amount of light it can collect.
You can get around this with a tracking head and you even if you want to take landscapes you could literally double the maximum exposure duration by using a tracking head at 1/2 "sidereal" rotation speed ("sidereal" speed is the rate of Earth's rotation)... so instead of 15 arc-seconds per second it runs the motor to turn the head at 7.5 arc-seconds per second. So now a 10mm lens can expose for a full minute instead of just 30 seconds.
The digital "noise" can be reduced by processing... and all astrophotography images need processing. Capturing the image is half the work, but learning to process the image is also quite a bit of work.
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