Depth of field (DOF) is the distance along the optical axis either side of the focus point that remains in acceptable focus. DOF can normally be improved by closing the aperture on the objective, yet only at the expense of optical resolution and with a significant loss of light - not an acceptable method when using microscopes.
Depth of Field or Depth of Focus?
Depth of Field is sometimes referred to as Depth of Focus although the exact definition of both is slightly different and there has been some discussion as to if we should instead be talking about Depth of Focus instead of Depth of Field. We are using the term Depth of Field on this site as that term specifically defines the distance in front of the objective which remains sharp above and below the object being imaged.
Wikipedia on Depth of Field and Depth of Focus
The Olbrich Lens System, used in the Ergonom range of microscopes, allows for a variable depth of field of between zero and considerably greater than would normally be expected with light microscopes while maintaining maximum aperture on the objective and full resolution thereby avoiding the pitfalls closing the aperture would have.
Our DOF system is entirely based on an optical process in real time and does not require or use any computer processing systems, etc.
Using a special control, on the Ergonom microscopes, it is possible to vary the DOF independent of magnification, resolution or the focus setting with no loss of resolution.
The variable depth of field allows you to see uneven surfaces in sharp contrast or alternatively to see individual layers of living tissues without the higher or lower layers interfering with the image quality. Even at high magnifications, we can still maintain a greater than normal working distance (typically 1-3mm), it is rarely necessary for the objective lens to actually touch the object.
The discovery of how to increase Depth of Field up to levels significantly beyond normal limits is of profound importance in microscopy. Extended depth of field is a vital component in the ability to observe nanometer size objects, live and in natural color - something that cannot be done with conventional light microscopes mainly due to their inability to solve the depth of field and resolution issues.
Whereas there are other microscope manufacturer who have also managed to achieve higher resolution beyond the Abbe limit, the Ergonom series of microscopes remain the only light microscopes capable of combining significantly better resolution with enhanced depth of field and the Grayfield color contrast method.
It is only the combination of these 3 factors which allows for the viewing and filming of living unstained specimens in full natural color and real time without any damage to the samples even after prolonged viewing.
Without Depth of Field
With Depth of Field
Part of a computer chip seen under the Ergonom microscope. Adding depth of field provides significantly more details
allowing a better understanding of the structure with a 3 dimensional appearance (not oblique).