JoFT said:
midluk said:
JoFT said:
The noise consideration was new to me. For me noise is related to pixel size: a pixel is a photon counter - and less size means less photons and more deviations and therefore noise....
Less size means less photons if the illuminance (i.e. photons per area) on the sensor is the same. But if you shrink the sensor and at the same time increase the illuminance to compensate (which you effectively do if you also shrink the focal length by the same factor while keeping the area of the lens constant) you end up with the same number of photons. Assuming no transmission losses all light from the image-visible part of the "world" that reaches the lens area ends up on the sensor. This amount of light is independent of the size of the sensor (if you move the sensor closer to the lens, which you do by decreasing the focal length). If you do not keep the area of the lens constant but also shrink the lens diameter by the same factor (i.e. keep the f stop constant) then you will end up with less photons.
If you do long exposures where dark current becomes important, bigger pixels should even have more noise because the dark current scales with pixel area.
Here I disagree to some extend: I was not talking about sensor size but pixel pitch. My question is how many Photons a pixel can count:
- EOS 7D2: 4,1µ => 16,81µ2
- EOS 5D3: 6,25µ=> 39,06µ2
- This means that each pixel can count ca 2.32 more photons in the 5D3 against the 7D2
Yes, the full well capacity should indeed change with absolute pixel size. This helps you at low sensor sensitivities (i.e. low ISO). This is consistent with my statement that ISO 100 on APS-C corresponds to an equivalent ISO (the ISO that the light meter gives you when you use the equivalent f number) of 250 on FF. So FF can reach a factor of 2.5 lower ISO. Which of course if you can compensate for lower ISO with a longer exposure or a bigger aperture gives you lower Poisson noise on FF compared to APS-C. As soon as you are above ISO 250 it will give you no advantage, but higher pixel (electrical) capacity (proportional to area) should even increase read noise, because the same number of electrons (caused by photons) in the pixel area cause a voltage that is proportional to the inverse capacity. Bigger pixel size means less voltage and therefore more read noise (relative to the signal).
So to sum up all the points I have stated before:
An image taken with an APS-C camera with focal length f, f-stop N, and ISO s would look exactly the same (including noise level and DOF) as an image taken with a FF camera (same pixel count) and focal length 1.6*f, f-stop 1.6*N and ISO 2.5*s. This is as long as you do not take differences in the fill factor (possible advantage for FF) and differences in the read noise and dark current (disadvantage for FF) into account.
FF has an advantage in areas that APS-C can not reach:
- low (equivalent) ISO (below 250)
- low (equivalent) f-stops at the same equivalent focal lengths
- very low (equivalent) focal lengths
APS-C has an advantage mainly at long focal lengths where you do not have the equivalent focal length available on FF (lens weight, size and cost).
In all other situations where you can take the image at the corresponding equivalent values it does not make much of a difference whether you use APS-C or FF unless there is a significant difference in fill factor or dark current and read noise become important.
JoFT said:
The ISO itself for me is a kind of artificial factor in the game. It is well defined to match film and digital to come to comparable values f.i. on light meters camera settings etc. At the end it is a calibration value set by the camera manufacturer....
We are comparing two cameras of the same manufacturer that do not have a huge age difference, so the ISO values should be roughly consistent between the 7D2 and the 5D3.
