Leica Digital Camera R Lenses User Manual

Leica R-Lenses  
by Erwin Puts  
January 2004  
Chapter 7: 28-90 mm lens  
__ LEICA VARIO-ELMARIT-R 28-90 MM F/2.8-4.5 ASPH  
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Chapter 7  
Leica R-Lenses  
2
__ LEICA VARIO-ELMARIT-R 28-90 MM F/2.8-4.5 ASPH  
__Zoomrange  
The choice of focal lengths is very practical. Many years  
ago Canon has analysed thousands of photographs and  
concluded that the most often used apertures and speeds  
are 1:8 and 1/125 and that the most used focal lengths  
were within the 28 mm and 90 mm range. If we believe  
these studies, the new Leica lens would cover the most  
used range of focal lengths with one zoom movement.  
wish would have clashed with the desire for a compact lens.  
Remember that the famous Vario-Elmarit-R 35-70 mm f/2.8  
had a front diameter of 88 mm and extrapolating this to the  
90 mm position, one would have to live with a lens with a  
diameter in the neighbourhood of 120 mm and a much hig-  
her weight due to the proportionally heavier glass lenses.  
The aperture ring has numbers from 2.8 to 22 and one  
should be aware that this range only holds for the focal  
lengths from 28 to35 mm.  
This Leica lens is a fine addition to the expanding range of  
Vario-lenses, but it cannot be a jack of all trades.  
The 50 mm aperture starts at 3.4 and the 90 mm at 4.5.  
If you are at the 90 mm position, the aperture setting of 2.8  
corresponds to 4,5 and the 22 is in fact 36.  
A macro facility is not available, but can be found in the  
companion lens Vario-Elmar-R 35-70 mm f/4 . And for most  
applications, the near focus limit of 0.6 meter on the 90  
mm position may suffice. The aperture range from 1:2.8 to  
1:4.5 has enough speed for current high quality medium  
speed films. One would have hoped for a slightly wider  
aperture at the telephoto side of the zoomrange. But that  
One should be careful when using a handheld meter or  
when one uses the A-setting and wants to select a specific  
aperture. It is easiest to use the aperture indication in the  
finder.  
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Chapter 7  
Leica R-Lenses  
3
__Optical demands and mechanical con-  
struction  
The design has 11 elements in 8 groups and employs two  
aspherical surfaces, one at the first surface of the front ele-  
ment and one at the second surface of the last element,  
incidentally the same as in the original Noctilux 50 mm  
f/1.2.  
the accuracy of assembly is a jump from nanometer scale  
to micrometer scale (0.001 mm), but this micrometer scale  
is still incredibly small. And the designer must be aware of  
this jump to assure that his calculations can be met in the  
realm of manual assembly, even when using sophisticated  
instruments to check the precision of the assembly. The  
new zoomlens has more than 40 main mechanical parts  
(excluding the elements and electronics and the aperture  
mechanism) that have to be assembled with a precision of  
0.010 to 0.005 mm.  
The lens has three moving groups that are being guided in  
milled slots with a precision of 0.010 to 0.005 mm.  
One of the biggest problem areas in lens assembly is the  
possible decentring of lens elements. Decentring of lens  
elements can be a tilt or a lateral displacement (relative to  
the optical axis) and will occur almost always during lens  
assembly unless one can work with very narrow tolerances.  
Most optical programs have a special module to study the  
effects of decentring and can indicate how much decen-  
tring is allowable before one sees a deterioration of the  
image quality.  
The challenge for the Leica engineers was to design a lens  
that had to fit into three dimensions of requirements: per-  
formance, haptics and cosmetics. These dimensions are  
partly at conflict with each other. And we have to add anot-  
her dimension, that is the manufacture of the lens. In this  
area Leica has learned a lot from the previous designs. The  
main problem area is the narrow tolerance band for the  
manufacture and assembly. The lens consists of eleven lens  
elements, that are precision grinded and have a surface tre-  
atment to reduce surface irregularities to a sub micron  
level, in fact here we are talking about tolerances at the  
nanometer scale (0.001 micron). To deliver the required and  
calculated performance, the lens element must be fitted  
into the mount without any stress, as the slightest strain on  
the lens will deform the surface and produce unwanted  
optical aberrations. One should be aware that the accurate  
and strain free mounting of the lens elements is a big chal-  
lenge. There are additional challenges too: a lens element  
needs to be blackened at the sides to reduce the possibility  
of flare. This is accomplished by painting the sides of the  
lens with a black paint, still done by hand by experienced  
workers. But a thick (relatively speaking!) elastic layer  
implies that the lens could move ever so slightly within the  
mount. One solution might be to press the glass element  
into its mount, but too much pressure is not good at all. So  
one has to carefully balance the thickness of the layer of  
paint with the requirement of a strain free fitting.  
Decentring in general brings loss of contrast and more  
astigmatism. A special construction is required to ensure  
that the very tight tolerances that this lens demand (due to  
the mechanical and optical constraints of a 1:3 zoomrange).  
The manufacture of parts can never be done in a zero-tole-  
rance environment. Therefore a certain amount of tolerance  
in the system must be accepted. In general one can appro-  
ach this problem in three ways: one can allow for adjust-  
ments during the assembly process and try to pair  
plus/minus parts to get the correct fit (old Leitz method),  
one can do a Monte Carlo statistical analysis to investigate  
where the most sensitive problem areas are and distribute  
the problematic aspect through the system by relaxing the  
constraint (Zeiss method of relaxation) and now Leica uses  
a third method. This is the method of mechanical compen-  
sators that are part of the mechanical construction and are  
already taken into account at the stage of optical design  
and calculation. This is the novel idea. Compensators them-  
selves are not new as a technique. In this case the lens ele-  
ment can be displaced by a small amount by a mechanical  
movement before being fixed in place. The displacement is  
controlled by a MTF measurement at a very high scale of  
magnification  
New too is the approach to design the lens optically and  
mechanically at the same time and in full interaction. The  
designer must be aware what is possible at the assembly  
stage as he cannot demand the impossible from the people  
during their work. The optical calculations are optimized to  
In the area of lens grinding and shaping we are operating  
on a nanometer dimension. The jump from this optical  
dimension to the mechanical dimension of the mount and  
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Chapter 7  
Leica R-Lenses  
4
allow the people at the assembly line to hand adjust the  
compensator mechanism in such a way that the lens is  
always at optimum performance. Every single lens is being  
checked to perform as designed and especially the aspheri-  
cal elements are very carefully adjusted. The result is a  
much lower tolerance band than would normally be possi-  
ble. The care that is being lavished on the quality of the  
assembly can be read off from the time needed: it takes a  
worker more than two hours to assemble the lens. This  
close cooperation between design and assembly is one of  
the main causes for the consistently high quality of the  
Leica lenses and has now been brought to a new level. The  
assembly and adjustment instructions are part of the final  
lens design and the design is adapted to what is the best  
assembly practice.  
selected because the surface reacts quite well to the black  
anodizing process (see image 1).  
No two lenses that leave the factory are absolutely identi-  
cal. There is always some tolerance during manufacture.  
The factory must set the lower limits of the performance  
that they can accept as being within the requirements as  
specified by the designers. A long as these requirements  
are met, a lens will be accepted by quality assurance. With  
the construction of the LEICA VARIO-ELMARIT-R 28-90 MM  
F/2.8-4.5 ASPH the statistical distribution within the tole-  
rance range is significantly reduced.  
Zoomlenses are difficult to manufacture to narrow toleran-  
ces because of the lens groups that have to move in a com-  
plicated path. Normally one uses a mount with guiding slots  
that govern the movements of the lens groups in relation to  
each other.  
(image 1)  
The result of all this effort is a lens with a very smooth  
movement of the focusing ring and focal length selection.  
With quite sensitive fingers one can feel some instances of  
friction when you go from 90 mm to 28 mm, so perfection  
is always relative.  
In most cases there are two or three slits and they are mil-  
led in the mount as open holes, in which the guiding rollers  
move. With open slits, however, the structural integrity of  
the mount can suffer, but with two slits and sufficiently  
thick walls, there is no problem. The price you have to pay  
is a heavy lens. One of the requirements for the new lens  
was its low weight. In this LEICA VARIO-ELMARIT-R 28-90  
MM F/2.8-4.5 ASPH we have three moving groups and the-  
refore three guiding grooves. Now we cannot use the nor-  
mal construction. (too heavy and/or too fragile). To ensure  
the necessary stability, one cannot use the open slit  
method, but must use internal grooves that can only be cut  
by special CNC machinery that Leica developed in coopera-  
tion with Weller, the leading manufacturer of this type of  
CNC tools. The milling movement creates a surface rough-  
ness that has to be smoothed to a tolerance depth of 0.01  
mm to ensure that the guiding rollers move with the same  
resistance over the whole range. The mount of the new lens  
is made of quite thin and very high-grade aluminium that is  
specially selected to have the required stability. It is also  
__Optical considerations  
The general image quality of this lens is of a very high  
order. Leica characterizes the lens as a travel and general  
purpose lens. This is undoubtedly true, but I would add that  
the performance of the LEICA VARIO-ELMARIT-R 28-90 MM  
F/2.8-4.5 ASPH does support professional photography of  
a very high calibre.  
At 28 mm and full aperture (2.8) we have a high contrast  
image that can record above 150 Lp/mm in the centre of  
the image and more than 80 lp/mm in the outer zones (see  
image 2). Only the corners are weak with a soft recording  
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Chapter 7  
Leica R-Lenses  
5
of fine detail. Stopping down to 5.6 the performance of the  
centre now extends over an image circle of 12 mm diameter  
(see image 3). There is no trace of astigmatism and a  
slight field curvature. Some colour fringing is visible at very  
high magnifications. Distortion is visible with -3% (barrel  
distortion) and so is vignetting at 2.5 stops (see image 4).  
Aperture Stop 2.8  
[%]  
100  
80  
60  
40  
20  
0
At 35 mm and full aperture (2.8) there is a small improve-  
ment in the outer zones where the lens now records 100  
lp/mm with good micro-contrast (see image 5). Distortion  
now is about -1%. At 5.6 we have optimum performance  
with a crisp rendition of very fine detail over most of the  
image area (see image 6). Vignetting is practically gone  
(see image 7).  
0
5
10  
15  
20  
Y'[mm]  
image 2  
Aperture Stop 5.6  
At 50 mm and full aperture (3.4) we see a very high con-  
trast and an exceptionally high resolving power of more  
than 150 lp/mm over a large section of the negative. There  
is still some faint colour fringing, but in practice one would  
be very hard pressed to note it (see image 8 and 10). At  
5.6 we have impeccable performance that easily surpasses  
the quality of the Summicron 50 mm lens, especially in the  
outer zones of the field (see image 9).  
[%]  
100  
80  
60  
40  
20  
0
At 70 mm and full aperture (4) the image quality becomes  
superb and we have an extremely high contrast and a very  
crisp definition of the finest details (see image 11).  
Stopping down to 5.6 does improve edge contrast and now  
the corners are quite good too (see image 12). Distortion  
is 1% (pincushion) and vignetting negligible (see image 13).  
0
5
10  
15  
20  
Y'[mm]  
image 3  
Relative Distortion  
[%]  
5
4
At 90 mm and full aperture (4.5) the best performance is  
reached and compared to the 70 mm position the outer  
zones and corners are now as good as the centre of the  
image (see image 14). Vignetting is gone and distortion is  
very low with 1%. The low distortion at the tele side of the  
zoomrange is quite remarkable. Often the behaviour of  
zoomlenses can be characterized as good in the middle  
range and weaker at both extremes (see image 15 and  
16).  
3
2
1
0
-1  
-2  
-3  
-4  
-5  
0
5
10  
15  
20  
Y'[mm]  
image 4  
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Chapter 7  
Leica R-Lenses  
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Aperture Stop 3.4  
Aperture Stop 2.8  
[%]  
[%]  
100  
80  
60  
40  
20  
0
100  
80  
60  
40  
20  
0
0
5
10  
15  
20  
0
5
5
5
10  
15  
20  
Y'[mm]  
image 5  
image 8  
Y'[mm]  
Aperture Stop 5.6  
Aperture Stop 5.6  
[%]  
[%]  
100  
80  
60  
40  
20  
0
100  
80  
60  
40  
20  
0
0
5
10  
15  
20  
0
10  
15  
20  
Y'[mm]  
image 6  
image 9  
Y'[mm]  
Relative Distortion  
Relative Distortion  
[%]  
[%]  
5
4
5
4
3
3
2
2
1
1
0
0
-1  
-2  
-3  
-4  
-5  
-1  
-2  
-3  
-4  
-5  
0
10  
15  
20  
0
5
10  
15  
20  
Y'[mm]  
Y'[mm]  
image 7  
image 10  
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Chapter 7  
Leica R-Lenses  
8
Aperture Stop 4.5  
Aperture Stop 4.0  
[%]  
[%]  
100  
80  
60  
40  
20  
0
100  
80  
60  
40  
20  
0
0
5
10  
15  
20  
0
5
10  
15  
20  
Y'[mm]  
Y'[mm]  
image 11  
image 14  
Aperture Stop 5.6  
Aperture Stop 5.6  
[%]  
[%]  
100  
80  
60  
40  
20  
0
100  
80  
60  
40  
20  
0
0
5
10  
15  
20  
0
5
10  
15  
20  
Y'[mm]  
image 12  
Y'[mm]  
image 15  
Relative Distortion  
Relative Distortion  
[%]  
[%]  
5
4
5
4
3
3
2
2
1
1
0
0
-1  
-2  
-3  
-4  
-5  
-1  
-2  
-3  
-4  
-5  
0
5
10  
15  
20  
0
5
10  
15  
20  
Y'[mm]  
Y'[mm]  
image 13  
image 16  
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Chapter 7  
Leica R-Lenses  
9
This is a lens with amazing characteristics. It offers outstan-  
ding quality and can be compared very favourably to the  
fixed focal lengths. A detailed comparison with the equiva-  
lent fixed focal lengths is possible based on the published  
graphs in earlier chapters and in the lens data sheets, avai-  
lable separately. The reader can do this him/herself.  
and if you have not yet tried slide film, the acquisition of  
this lens might be a good incentive to try these films.  
The wide zoomrange from 28 to 90 mm highlights another  
property of the reflex system: the normal finder screen of  
the R8/9 is a bit too dark at the 90 mm position and it is  
difficult to focus accurately at the 28 mm position. Here  
lies a new job for the engineers at Solms! Focussing at the  
wide angle range is often not very critical as depth of field  
will cover slight errors. If accurate focus is required, it is  
best to focus at 70 mm and zoom to 28 mm (or 90 mm and  
zoom to 35 mm).  
The comparison with the Apo-Summicron-R 90 mm f/2  
ASPH is interesting and does indicate where the advantages  
of fixed focal lengths may be found. A careful study of the  
properties of the individual lenses does help making the  
correct selection. The Apo-Summicron-R delivers at full  
aperture (1:2) the same performance as the Vario-Elmarit-R  
at the 90 mm focal length at f/4.5.  
The Apo lens has a two stop advantage here. The greater  
depth of field and the more effective reduction of internal  
reflections (smaller lens diameters!) give the pictures with  
the Vario lens a smoother quality. With the Apo lens the  
sharpness plane is clearly isolated from the rest of the  
image and the unsharpess gradient is steeper. Stopping  
down the Apo-Summicron-R to 1:4 will make the differen-  
ces disappear of course.  
In this range, focus constancy is abolutely spot on. Current  
Leica lenses score high marks in the areas of contrast and  
definition and reproduction of very fine detail. These cha-  
racteristics can be inferred from the published MTF graphs,  
as long as you try not to read too much out of these  
graphs. One very critical area where the MTF can not provi-  
de information is the propensity to flare in its several  
aspects.  
In general the fixed focal lengths will be more compact and  
offer a higher speed per focal length. Stopped down there  
is no longer a big difference and compared to older lens  
generations, the zoomlens often has better imagery in the  
outer zones of the image.  
The images made with the LEICA VARIO-ELMARIT-R 28-90  
MM F/2.8-4.5 ASPH have a very good colour fidelity, a very  
fine pictorial depth and realism. This is a lens for slide film  
LEICA VARIO-ELMARIT-R 28-90 MM F/2.8-4.5 ASPH  
image: Oliver Richter  
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Chapter 7  
Leica R-Lenses  
10  
__Flare properties  
I made a special study of the flare properties of the lens, as  
this is the one area where lenses have to go 'a bout de  
souffle'. Veiling glare is hardly visible at all focal lengths,  
implying there is no loss of contrast when the background  
is much brighter than the subject itself. When the sun is  
obliquely shining into the lens, and is behind the subject,  
one can see some secondary reflections of small extent in  
the picture, but the well-known diaphragm blade reflections  
are not visible. With the sun flooding the image, there is of  
course a bleaching out of the picture details, but in such a  
situation one would change the position slightly to evade  
this direct confrontation with the sun.  
The image quality of the LEICA VARIO-ELMARIT-R 28-90  
MM F/2.8-4.5 ASPH is generally above what one expects  
from high grade fixed focal lengths and the focal length  
range secures it a premium role in the Leica R lens range.  
In general I would say that for veiling glare the lens is better  
than the average Leica lens, and for secondary reflections it  
is slightly better.  
__Conclusion  
The new lens is an outstanding performer at all focal  
lengths. The compact size, the ergonomics and the perfor-  
mance are all balanced into what economists call a Pareto  
optimum. Any change in one of the parameters will degrade  
the quality of the whole. This actual image quality can only  
be guaranteed during production and assembly where the  
very tight tolerances and adjustment methods demand  
workmanship of the highest level.  
LEICA VARIO-ELMARIT-R 28-90 MM F/2.8-4.5 ASPH  
image: Oliver Richter  
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