Magnification of the microscope

The magnification of the microscope can be found on the eyepiece and objective of the microscope. Knowing these data, the total magnification of the microscope can be calculated.

Light microscope overall magnification
The total magnification of the microscope corresponds to the product of the transverse magnification of the objective (Z ob ) and the angular magnification of the eyepiece (β ok ). Therefore, the relation applies to its calculation
 * $$\Gamma = Z_{ob}\cdot\beta_{ok} = \frac{\Delta }{f_{ob}} \cdot \frac{250}{f_{ok}}$$

while it is true that
 * $$Z_{ob} = \frac{\Delta}{f_{ob}}$$ is the transverse magnification of the lens;
 * βok is the angular magnification of the eyepiece;
 * fob and fok are the focal lengths of the objective and the eyepiece (in mm);
 * Δ is the optical interval of the microscope (in mm). Expresses the focal distance of the objective and the eyepiece;
 * 250 is the conventional visual distance of the human eye expressed in mm.

The relationship for microscope magnification can also be derived from the laws of geometric optics, as far as it is possible in practice to calculate it as the product of the individual magnifications indicated on the eyepiece and objective.

Zoom effects
The desired result of the magnification obtained by the eyepiece and objective is the observation of the object being examined with the possibility of observing more details. In the case of inappropriate eyepiece and lens combinations, however, magnifications may occur that do not show us more details. More details on this topic can be found in the article on Abbe's theory, in which these relationships are described in more detail.

From a practical point of view, it is optimal for the observer to achieve a useful overall magnification that leads to the observation of new details.

On the contrary, if we do not observe any new details with the enlargement, but only an enlarged image, this is an empty enlargement.

Related Articles

 * Optical microscope
 * The principle of imaging with an optical microscope
 * Microscope depth of field
 * Abbe's theory