Archived posting to the Leica Users Group, 2010/10/31
[Author Prev] [Author Next] [Thread Prev] [Thread Next] [Author Index] [Topic Index] [Home] [Search]Your point seems well taken, but that process would be in addition to what I
was talking about.
I believe that when the shutter button is pushed, what happens first, and
without noticeable pause, is that the sensor is flushed of all thermal
electrons (noise) accumulated since the last readout. Then during the
exposure, both thermal electrons and the electrons freed by image photons
accumulate at each photosite. Finally, when the shutter closes, the
electrons are read out by the electronics and the corresponding numbers
stored as the image file. This file contains contributions from thermal
electrons (and other sources of noise, such as read noise). The longer the
exposure (and therefore the interval between the pre-exposure flush and the
post-exposure read), the more thermal electrons will accumulate at each
photosite. Part of the thermal noise is random from one photosite to the
next and so is not unambiguously removable, though statistical and
contextual algorithms can be applied to make the picture look less noisy
(Noise Ninja etc).
So longer exposures produce more noise, and this is invariant with the
number of "image" electrons that accumulate (unless a photosite saturates).
If two images are made, one with a short exposure and low f/ratio and the
other with long exposure and high f/ratio, both accumulating the same number
of image electrons, you can see why the image made with a long exposure will
contain more noise electrons than the short exposure. What I don't know is
whether this difference is noticeable under usual working conditions, i.e.
whether 1/60 or 1/30-sec exposures accumulate noticeably more noise than
1/1000 sec in an image that is adequately exposed?in the middle of the
histogram. Certainly it's important as exposures get longer. I suspect it's
noticeable in dark areas of subject matter in ordinary exposures at high
ISOs. (Higher ISOs are obtained simply by amplifying the signal being read
off the CCD, and some of the noise inherent in the process gets amplified
too, so the image is noisier than one taken at low ISO?though not all of the
noise, otherwise what's the point?)
The random part of the thermal noise cannot be removed by the automatic
dark-frame subtraction that digital cameras perform after a long exposure,
because it's unpredictable and variable from one photosite to another and
from exposure to exposure at each individual photosite. But there is another
component to thermal noise, one that depends on fixed, unique
characteristics of each individual photosite, and is therefore consistent
from one exposure to the next. These systematic aspects include almost
atomic-level differences in the photosites acquired during manufacturing,
differences in temperature across the sensor produced by the camera's
electronics ("amplifier glow"), and other factors. This systematic thermal
noise can be replicated by exposing a dark frame of the same duration and
subtracting its values pixel-to-pixel from the image file. These things are
well known to "astroimagers", who count practically every single photon from
extraordinarily faint deep-sky objects using CCD cameras that are cooled to
30-60 degrees below ambient and apply dark frames, bias frames, flat-field
frames, etc, to refine the result. Professional astronomers cool their CCDs
for spectroscopy and imaging to the temperature of liquid nitrogen!
And as you said, selectively bringing up the raw signal from
under-represented pixels will selectively bring up noise of that color.
I'll do some high-ISO comparison shots of short exposure at high f/ratio and
longer exposure at low f/ratio and post them.
?howard
On Oct 31, 2010, at 5:11 AM, Jeff Moore wrote:
> 2010-10-30-22:32:57 Howard Ritter:
>> In answer to your question about the low noise level in bright-light
>> exposures at ISO 2500, here's my suspicion: The amount of noise in a
>> given exposure depends on a number of variables, one of which is the
>> duration of the exposure.
>
> Well, maybe. But I also note that when there's bright light, it's
> usually sunlight, while dim light is often something with a warmer
> color balance like incandescent lights (or candles). When I
> particularly notice noise, it's often when I start with something with
> very little blue energy in it naturally, and try to balance the color
> temperature out to look not-entirely-orange. That requires cranking
> up the underexposed blue pixels, which respond by peppering the frame
> with blue noise.
>
> Or is it some entirely diffrent phenomenon you're talking about?
>
> -Jeff
>
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