Hasselblad lenses on Nikon digital

[wang]

I am coming back to this part of the forum after doing some testing, and I am going to disclose and share with you the test results.

Basically, I tested some Contax Zeiss C-Y lenses, Zeiss Nikon mount lenses and Zeiss Hasselblad H lenses on my Canon EOS 350 D. I shot many images including bank notes to give me RAW files. I viewed the RAW files on my DUO intel iMac. I used studio flash and test them all at f=6.5.

There are the groups I tested.

Hasselblad 50mm f4 CF with Zeiss F 50mm f2 Makro-Planar

Hasselblad 60mm f3.5 CF with Contax Zeiss 60mm f2.8 C-Y

Hasselblad 100mm F3.5 CF with Contax Zeiss 100mm f2.8 C-Y

After testing these lenses I gradually get the idea that they have similar performances by judging on the image quality. The result is consistent with what Gilbert quoted earlier.

"Resolutions on the same level
have been achieved with Carl Zeiss
lenses in Hasselblad medium format
cameras, proving that at Carl Zeiss,
medium format lenses, contrary to
popular belief, offer no lower
resolution than the very best 35 mm
lenses."

http://www.zeiss.com/C12567A8003B8B6F/EmbedTitelIntern/CLN02e/$File/CLN2.pdf

However, I do find an important exception to this when I am testing the following.

Hasselblad 120mm f4 Makro-Planar CF, Contax Zeiss 100mm f2.8 Makro-Planar C-Y, Zeiss Nikon F 100mm f2 Makro-Planar

What I found is the images from the Hassey 120mm is certainly inferior to the two other lenses from the smaller format. The images from Hassey simply has less punch, they stand out less from the background. The colours from the Hassy are considerable paler. They also have less contrast and sharpness. Although I would not like to admit this, the Hassey 120mm is producing images inferior to the two smaller format lenses. I did the testing at 1:2 magnification and had the same results. I thought it was unfair to the Hassey because I was using exteension tubes whereas the other two lenses had did it with floating elements. I repeat the testing at 1:5 magnification and confirm the inferiority of the Hassey.

I would be happy if someone could repeat the testing in case I am using a faulty Hassey lens but now I do believe that Hassey 120 is a bit out-dated and certainly it needs a replacement.

Although I have Contax Zeiss 120mm f4 for 645 but it is not possible to test this lens on my Canon.

In this part of the forum there are certainly some fudamental principles in optics which need to be clarified. There are different views which are opposing. I hope clever reader will get the ideas which are right.

All lenses allow light to pass. I am sure nobody will object if I say stopping down will improve the image quality. Stopping down is achieved by restricting light from passing through the lens. This is the same as the the principle of pinhole in the pinhole camera. If the pinhole is made smaller you improves the image qualities but it becomes darker. It has nothing to do with the angle of view.

Stopping down is achieved by using one aperture. What will happen if two apertures are applied,one in front and one at the back of the lenses ? If one applied apertures in this way, the angle of view is effectively reduced. If you reduce the angle of view, you are effectively converting a lens into smaller format.

It is not difficult to deduce from these principles that image quality can be improved by stopping down, reducing the size of the pinhole and reducing the format by using two apertures. These are true because I did these tricks and they work.

There are at least two reasons why stopping down leads to better image qualities. The first reason is because of the pinhole effect, and the second reason is the reducing of the effective diameter of the lens. The pinhole effect has nothing to do with lens design.

The second reason needs further explanation. The resolving power of the lens is better at the centre than the margin. Stopping down is effectively allows the light to pass the central sweet spot and cutting the light from passing the margin which is prone to aberration.

"Ever wondered why the make telescopes so very large? " One member of this forum asked.

"No, it's not to make them "faster". It is because the smaller they get, the lower their resolving power" he answered.

My answer to that question is bigger lens is faster. The faster is the lens, the less is the resolving power. Telescope is big because it is obtaining image from very dark sources, they have to be fast. The bigger the faster they are, they becomes less resolving.

"Your analogy appears to be based on the assumption that a definite amount of detail is going through a lens, and when it is distributed over a larger area, the resolution, i.e. the amount of detail per area unit, will be less, the detail less dense, than when it only has to cover a smaller area."

The bigger is the lens, the smaller is the resolving power, trust me.

Of couse, Zeiss understand this basic principle and this is why she made the quote

"Resolutions on the same level
have been achieved with Carl Zeiss
lenses in Hasselblad medium format
cameras, proving that at Carl Zeiss,
medium format lenses, contrary to
popular belief, offer no lower
resolution than the very best 35 mm
lenses."

Zeiss is great despite the fact that increasing the format tends to reduce the image quality, she maintained the standard.

 

[polypal]

Thanks for your efforts and the trouble you took to report your findings.
I especially liked your observation that results from the Hasselblad Makro-Planar
could have been due to a faulty lens.
It could be a reason although my findings are in line with yours.

Maybe another test using the Contax 120 Makro-Planar and the Hasselblad
Makro-Planar will reveal more.

What I have seen sofar from the new Contax design beats the Hasselblad lens on all counts.
Colour rendering has been improved dramatically for the Contax lens.

Many CZ lenses for Hasselblad already give optimum results at full aperture.
Stopping down does not substantially improve the image quality.

 

[evanjoe610]

Wang,

I believe that you have a Canon Digital 35mm body? If so, Do you have access to a Contax 645 to Hasselblad lenses mount adapter? You try to "pile on" the various adapters to achieve your testing.

I manage to use my MAM-1 adapter (for COntax 645 to Hasselblad lenses) on my NAM-1 adapter (Contax N to COntax 645 lenses) on my Contax N1 body. I also have a Contax 645 to Pentacon 6 lens adapter for my Schneider Exakta 66 lenses. All lenses appears to achieve Infinity focusing. I would have to locate a split image screen to confirm this, but in my viewfinder it looks good.

Evan

 

[qnu]

Wang,

Google "Rayleigh limit" or "Dawes limit".
Then you will find that the bigger a lens, the higher the resolution.
The maximum resolution of any optical system is a function of its aperture - the bigger the better - and the wavelength of the light used to create the image - the smaller the better.
That is true for telescopes and photographic lenses alike.

The reason why a particular (not so great) lens performs better when stopped down a bit is that, as you also mention, some resolution limiting lens faults are reduced, and with them their effect on resolution.
But at the same time, diffraction (the thing that makes pinhole pictures so blurry) increases, halving the resolution you can ever hope to achieve by every two stops you reduce the aperture.

So what you then need to find to get the maximum resolution out of the lens is that point at which diffraction and lens faults are equally bad, so that stopping down increases diffraction and reduces resolution even more, and that opening up increases lens faults and reduces resolution more as well.
The point that is commonly referred to as the "sweet spot" of a lens.

Many good lenses have not many residual abberations, and do not need to be stopped down to improve resolution. Their "sweet spot" is at their largest aperture.
The Sonnar f/5.6 250 mm lens is a fine example of a lens that does not get better at all by stopping down.
The Sonnar-Superachromat f/5.6 250 mm lens is an even better example.

So there is an escape from this "reducing the aperture will improve performance" thing and that is good lens design.

However, there is no (!) escape from diffraction, limiting resolution the moment the aperture is reduced, every time you reduce the aperture. It is, quite simply, a law of nature, that cannot be 'designed away'.

So telescopes are indeed large to increase resolution.
Making them smaller will reduce their capability to resolve, not details in point sized objects, but close objects far far away.

One trick, already played with radio telescopes, allowing to further increase resolution is to enlarge the telescope even beyond the size a single one can be made to be economically (and technically), and use an array.
The 'aperture' then can be hundreds or thousands of miles large. Optical telescopes and radio telescopes alike need to 'keep' the phase information of the wave fronts that hit them, and which must be brought together to interfere. And that's easier done with electrical signals than with photons (but it works) so the optical array telescopes are still hundreds, thousands of miles smaller than the radiotelescope arrays.

And equally, a good photographic lens performs better at larger apertures than it does at smaller apertures.
"Increasing the format", i.e. the lens' diameter, does not (!) "reduce the image quality".

Yes, the objects observed by telescopes are faint, and plates and digital sensors alike need long exposures. And yes making the telescopes larger will reduce that - a bit.
The objects will remain faint. The gain is small, and not very important, considering that it is very easy to increase the "shutter speed" instead, and combine the observations of many nights in a row.

 

[wang]

In response to polypal.

Contax 120 Makro-Planar is difficult to test because there is no adaptor for it to put on the Canon camera. Even if there is an adaptor the aperture is not controllable. I agree with your findings.

Hi Evan,

I am using a Canon body with 1.6 crop factor for 24X36 format. Testing is easy with Canon's body because you can see the result straight away on the monitor. I don't process the images.I look at the RAW images straight away and can tell the difference. You can tell straight away when there is a difference in colour.

I am sure you could test Hasselblad lenses and Contax lenses on a Contax N1 but in that case the testing is complicated with scanning and processing.

Q.G.

I certainly agree that the bigger a lens, the higher is the resolution, but only for the reason which has not been mentioned by your posting 1178.

[The maximum resolution of any optical system is a function of its aperture - the bigger the better] you wrote but I don't agree.

In 24X36 format, there are so many lenses around that you can play with them and learn about optical principles.

Let me explain it with less technical terms so that everyone knows what I am talking about.

There are al least two reasons why a lens can be big. You could either increase the diameter of the lens elements or increase the number of the lens elements. If you increase the diameter you have an increased aperture.If one increase the aperture from f16 to f8, I agree that there will be an increase in resolution. However, if you increase the aperture from f4 to f2 there will be a decrease in resolution. I agree that the maximum resolution is a function of its aperture, but it is not the bigger the better. It really depends.

Most lenses have an optimal aperture at f4, f5.6 or f8, those where you get maximal resolution.

On the other hand, if you increase the number of elements, you get a bigger lens, you also improve the maximum resolution.

Fine examples are Hasselblad 120mm f4 when the number of elements is increased from 6 to 8 you get the Contax 120mm f4 with much better resolution. Another good example is the comparison of the IF and non IF version of 40mm f4 CFE. The IF version has 12 elements whereas the non-IF has 11 elements.

Yes, I agree.The bigger the better, but not the aperture.

 

[qnu]

Wang,

Please do use Google (or a book on optics), and you will indeed see that the diameter of the aperture is what determines resolving power of any and all optical systems.

Yes (and as said before), stopping down helps eliminate resolution limiting lens faults.
You can also do that using a better design, and stricter manufacturing tolerances.

So far, we seem to agree.
But you keep holding on to the conclusion that "The bigger the better, but not the aperture".
And there you really are wrong.

As mentioned before, lens faults are a design problem.
Resolution limiting diffraction, and the fact that this is linked to the size of the aperture, is a given fact, a Law of Nature, something no design can get around.

So you can indeed increase resolution by making a lens less fast, but only (note!) because the design left some resolution limiting faults, that are worse in effect than diffraction.
Making a lens f/4 instead of f/2 may increase resolution by reducing their effect. But diffraction will show no mercy, and the resolution you can ever hope to reach at that f/4 aperture will be half of what it could have been at f/2.

So do trust me (or do indeed look it up): the larger the aperture, the better.
Given two lenses, both free from lens faults, the one with the larger aperture will always have greater resolving power.


The number of lens elements used, by the way, is not a direct expression (and often not an indirect one either) of how good a lens is, neither in terms of freedom of aberrations nor in terms of resolving power, but of what design solution is employed to tackle a certain design task, and how many refracting boundaries that needed.

As your examples illustrate, some better lenses have more elements.
But there are examples too of the opposite: the 100 mm Planar, for instance has 5 elements, some 30% less than the 7 found in the 80 mm Planar. The one with fewer elements clearly being the better one.

So your "the bigger (in terms of lens elements!), the better" is not generally true.

 

[wang]

Sorry, this is against my experience on photography.

(and the resolution you can ever hope to reach at that f/4 aperture will be half of what it could have been at f/2.) To me, this is fudamentally untrue. f4 always has better resolution than f2

Sorry, I would not accept your comparison neither. You are comparing lenses with different focal length and different f numbers. Look, I am comparing lenses with SAME focal length and SAME fnos.

 

[wang]

(So do trust me (or do indeed look it up): the larger the aperture, the better.) A very good example to prove this statement being wrong is

Hasselblad 50mm f2.8 FE and the Hasselblad 50mm f4 CFi

From this fine example, the smaller the aperture, the better.

 

[wang]

I can also tell you why Planar 100mm f3.5 is better than Planar 80mm f2.8, the smaller the aperture, the better.

 

[qnu]

Wang,

I see that you are reluctant to accept how things are, so we better end this discussion.

But i do urge you to look things up. I'm sure you will enjoy finding out how things are as much as i do, so treat yourself and do use Google (for starters), and (better still) find some good books on optics. You'll not regret it!

As a start, here's a link to an issue of Zeiss' Camera Lens news:
http://www.zeiss.com/C12567A8003B8B6F/EmbedTitelIntern/CLN02e/$File/CLN2.pdf

Have a look at the article titled "Resolution of Camera Lenses Where are the limits – and why?" which starts at page 2.

I believe you already quoted from the very same article, but have ignored the bit saying "The fact is: Carl Zeiss has to adhere to nature’s laws just as anybody else. So far, Carl Zeiss’s physicists have found no way around it. [...] This disc has a certain diameter, which varies with the aperture of the imaging system. The smaller the aperture (e. g. f/22) the larger the disc. And the larger the disc, the lower the resolution!"
;-)

 

[wang]

Q.G.

I am sorry to see that you are reluctant to accept the truth.

I am sure you don't understand at all what I am saying. I don't mind saying this again.

For apertures larger than f4,f 5.6 and f8, they always have a lower resolution.

For apertures smaller than f4, f5.6 and f8, they always have a lower resolution.

As a photographer, you just go and shoot. You will discover that f4 is always better than f2, in this case, the smaller the better.

When you compare f16 and f8, f8 is always better. In this case, the larger the better.