A parfocal lens stays in focus when the magnification / focal length changes.
Some amount of defocussing is inevitable, but the amount is so small that it is considered as insignificant.
In microscopy parfocal lenses stay in focus when the magnification is changed.
The image stays focused when the
magnification is changed from 40x to 10x
Most bright field microscoped are parfocal.
In photography, a zoom
lens is parfocal, a varifocal
lens is not.
Motor-Zoom lenses are actually varifocal. When you change the
magnification, also the focus changes. However the focus motor can work in parallel to the
focal length motor, so for the user the
lens seems to be parfocal.
= hypercentric
With pericentric lenses objects at larger distances appear larger(!) and objects at closer distances appear smaller.
Perizentric lenses allow for example to view a can from top and the sides at the same time.
This reverses our normal viewing experience.
Pericentric lenses got to be MUCH larger than the object under inspection.
see “comparison: entocentric – telecentric – pericentric”
Application : A cylinder with a drilling that is centered on one circular side and decentered on the opposite side is to be inspected for foreign parts in the drilling.
The rotation of the cylinder is not known, so we would need a
lens that can look from all sides “outside-in” at the correct angle.
Solution: DIY with the help of a Fresnel
Lens, a normal M12
lens and the graphic calculator below …
A kind of vignetting which occurs exclusively with digital cameras.
Possible causes are:
- the pixels are not completely flat due to construction on the sensor surface, but in small cavities. Too shallow light cast shadows on the edges of the pixels, like the evening sun at some point no longer reaches mountain valleys.
- The sensor uses micro-lenses (small converging lenses) to capture as much light as possible for each pixel. From a certain off axis angle lenses are no longer capable to deflect the light strong enough and the light can’t reach the pixel no more.
- With image side telecentric lenses such vignetting does not occur because the incident light rays are parallel to the optical axis.
The latest sensor technologies however try to correct the Pixelvignettierung on-chip (= directly in the sensor) or by micro lenses that have differently shape in the corners than in the center.
Thus it may happen that the image side telecentric lenses surprisingly show vignetting.
Each (rotation symmetric) lens has two principal planes. These (hypothetical) planes are perpendicular to the optical axis and are the planes on which light beams parallel to the axis coming from infinity seem to bend (and then go through the respective focal points).
The image side primary plane is formed where a light ray parallel to the optical axis enters the first lens of a lens system and intersects with the corresponding ray leaving the last lens element.
The object side primary plane is formed where a light ray parallel to the optical axis enters the last lens of a lens system and intersects with the corresponding ray leaving the first lens element.
In a single thin
lens the two principal planes merge and can be approximated by the center of the
lens.
ratio of the diameter of the exit pupil devided by the diameter of the entrance pupil
For symmetrical lenses, for example a double Gauss design, the pupil magnification is close to 1.
see also:
working F-number
Numerical Aperture