Archived posting to the Leica Users Group, 1999/05/20
[Author Prev] [Author Next] [Thread Prev] [Thread Next] [Author Index] [Topic Index] [Home] [Search]The practical method for lens evaluation that has been proposed on this list recently, has a long history. It has been in vogue since the thirties and has found extensive descriptions in all kinds of articles since then. In fact such a practical test is not a lens test, but a system test (as it involves subject, lens, camera,film, exposure, development etc). This means that many variables will influence the system result. If for instance one lens has 100 lines/mm and another one 200 l/mm (optically a very big difference), but the system uses a film with 100l/mm (which is mostly the case) then the resulting resolving power of the object at the film plane will be 50 and 67 l/mm. Thus only really big differences in optical performance will be detected by this kind of testing, IF all is done properly and consistently AND the object to be photographed is a suitable one AND the focus setting is at its optimum position. Many of these conditions are not met in practise. Still this practical method has one big advantage: it shows the limit of acceptability of a certain system for this individual photographer, given his/her needs and experience. and systemsetup. It makes sense that a photographer should be happy with a systems performance and not worry too much if (s)he should consider another lens to use or buy. This method is mostly opposed to the analytical method of testing lenses (not systems) which is based on a variety of equipment and methods and training. These analytical tests are mostly electronic now. Most industry tests shy away from visual inspections as too unreliable. The most popular electronic one is the MTF test. This test comes in two flavours. The reading of the areal image of a slit by a scanning device and the subsequant computer analysis of the contrast transfer and edge contrast. Again this method has many versions. The PopPhoto, Photodo, Chasseur's d'Image and BAS and ColorPhoto are some examples. The second version is the computer generated MTF: this works very (simplified) as follows: he optical aberrations of the lens will deform the wavefronts of the incoming light bundles as reflected from the object point. These deformations will be measured as optical path differences which after much number juggling and Fourier Transforms will generate the OTF. from which is derived the MTF. This one is the most accurate and most revealing of a lens performance. (Leica, Zeiss use this version). So the MTF of Leica can not be compared to the ones of Photodo etc. This MTF is not complete: it gives no info about flare, distortion, colour correction, close up performance etc. It is also difficult to interprete without a thorough optical background. The best and most complete testing cycle of a lens would be composed of three different methods, that complement each other: an analysis of MTF graphs of the second type, a study of an aeral projection of a test pattern to show distortion, curvature of field, astigmatism etc and practical field testing to show colour correction, flare, close up performance, out of focus behaviour etc. This combination of results should be weighed and reported upon in a meaningful and understandable way for a practical photographer. The system test, however conducted can never be a substitute for the analytical testing.It is a matter of choice which one a photographer should use as a basis for buying lenses. A simple dichotomy will not work. The practical and analytical methods both have merits for photographers. One should be carefull not to try to prove one to be superior above the other. They are too different for a direct comparison. BTW: we talked about QC and lenses some time ago. Here are some figures from the Japanese Camera and Optical Instrument Inspection and Testing Centre. Mass production of lenses require a statistical approch to testing. How is this done. Assume a production run of 3000 to 5000 lenses. Then the Institute requires that a batch is choosen at random. This batch must be 85 lenses. These 85 are thoroughly tested. If 10 defects are found the whole production run is accepted. At 11 the run is rejected. If the total number is 181 to 500, the sample is 40 items and the rejection number is 5 (passed by 4). These numbers are for Japanese lenses. It does show that this Institute accepts a certain failure rate (sometimes even of 10%) when lenses are mass produced. When lenses are hand assembled the same laws apply. More rigorous inspection and testing will reduce the failure rate, but can never eliminate it. Erwin