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 p.5 #11 · M glass on Leica SL3 (or SL SL2) | |
RustyBug wrote:
The basic premise of "out-resolves" (for many) is when the size of the pixel is smaller than the airy disc of the optical projection. That is something that does occur, and by that prescribed definition, it does occur. There are also those who ascribe to outresolving a scenario that occurs relative to frequency and moire', et al. But, consider when the projection is supposed to be other than LL contrasts.
However ... I still find that the optical projection is a continuum of values. As such, no matter how small the sensor pixels become (i.e. smaller than the airy disc, etc.), they never achieve continuum. Thus, incapable of achieving continuum does not outresolve continuum. The best the sensor (theoretically) could do is present the full continuum of values, yet it does not.
And yes, I understand MTF's and LL, etc. ... which are also influenced by the amount and quality (specular vs. diffuse, etc.) of light illuminating a subject. While testing does offer a consistent reference point (within a given set), a lens can actually perform "above" it's advertised MTF with sufficient light amount / quality providing illumination greater than the "test standard".
We often look at the level of detail in lined pairs, but what about the tonality continuum in bokeh, fog or open sky (where no LL exists). Can a sensor outresolve the tonality of continuous tones projected by the lens? Even though I know that the sky or fog or bokeh, etc. is a continuous tone projected by the lens, pixel peeping will reveal the pixelation ... i.e. the sensor cannot outresolve the continuum.
So, depending on how you choose to "define" the term of "outresolve" (i.e. airy disc, frequency, moire', mtf from standardized light or tonality, the last of which rarely is spoken to), a person's stance on the matter may vary.
In the end, the lens provides a continuous optical projection, but the sensor provides a S/N response in the form of a sliced / diced matrix (i.e. not continuous).
And, yes ... the mathematical formula (can't find it right now) that is used to represent the system capability is a combination of both the limits of the lens and sensor in combination, where a rising tide lifts all boats, no matter whether it is the lens lifting the sensor or the sensor lifting the lens. Here again, the concept of the sensor "outresolving" the lens ... is kinda moot. A higher MP sensor doesn't outresolve the lens, it just does a better job (approaching, yet never achieving, continuum) of resolving the optical projection from the lens (whatever lens / light capability may be).
Just for fun ... here's one from the archives. 
https://www.fredmiranda.com/forum/topic/504107/1/
Still trying to find the formula jcolwell provided us, many years back. If anyone has it ... 
 ...Show more →
I don't question all the formula-based description - but I question how it matters for a real-world photo. I still don't see one which shows that a sensor outresoved a lens independent on specific lens properties (light falloff, vignetting, low contrast etc).
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