Resolving Power and Resolving Limit

The resolving power of an electron microscope is higher than that of an optical microscope because the wavelength of electron is _____________ as/than the wavelength of visible light.

What is the relationship between resolving power and wavelength of light?

How does the resolving power of a microscope depend on i the wavelength of the light used and II the medium used between the object and the objective lens?

How does the resolving power of a microscope depend on?

On what factors does the resolving power depend?

How does the resolving power of a microscope depend on?

The ratio of resolving powers of an optical microscope for two wavelengths ${\lambda }_1=4000 \mathrm{Å}$ and ${\lambda }_2=600 \mathrm{Å}$ is

An LED display consists of $100$ pixels per ${\mathrm{cm}}^2.$ Consider that the diameter of the pupil of the eye is $5 \mathrm{mm}$ and the average wavelength of the display is $575 \mathrm{nm}.$ What is the nearest distance from the display one can be at, such that the display does not appear pixelated?

The characteristic impedance of a coaxial cable is of the order of

Resolving power of a microscope depends upon

Assume that the light of wavelength is $6000 \stackrel{\circ }{\mathrm{A}}$ coming from a star. What is the resolution limit of a telescope whose objective has a diameter of $100$ inch?

The human eye has an approximate angular resolution of, $\mathrm{\varphi }=5.8\times {10}^{-4} \mathrm{rad}$ and a typical photo printer prints a minimum of $300 \mathrm{dpi}$ (dots per inch, $1 \mathrm{inch}$$=2.54 \mathrm{cm}$). At what minimum distance $\mathrm{z}$ should a printed page be held so that one does not see the individual dots?

Two point white dots are $1 \mathrm{mm}$ apart on a black paper. They are viewed by eye of pupil diameter $3 \mathrm{mm}$ approximately. The maximum distance at which these dots can be resolved by the eye is (take wavelength of the light  $=500 \mathrm{nm}$):

Resolving power of a microscope depends upon

Resolving power of a lens is the consequence of

The resolving power of the human eye is aprroximately-

An astronomical telescope is able to resolve two stars at an angular separation of ${10}^{–3} \mathrm{degree}$ . If wavelength of light used is $500\mathrm{nm}$,then the diameter of the objective of the telescope is

If the red light is replaced by blue light illuminating the object in a microscope, the resolving power of the microscope

An astronaut is looking down on earth's surface from a space shuttle at an altitude of $400 \mathrm{km}$. Assuming that the astronaut's pupil diameter is $5 \mathrm{mm}$ and the wavelength of visible light is $500 \mathrm{nm}$, the astronaut will be able to resolve linear objects of the size of about

Out of the following, resolving power of reflecting telescope depends on: