If one wants more light at large distances, assuming the wattage is the same, will one use a point source or a cylindrical tubelight ?

At a finite distance from the source, a point source of light produces

The intensity of light at a distance r from the axis of a long cylindrical source is inversely proportional to r .

The intensity of light at a distance 'r' from the axis of a long cylindrical source is inversely proportional to 'r'

Near an infinitely large flat plate with a surface charge density o on each side, the field strength is** E=delta/(in n^delta), while the field produced by a point charge at a distance r frorn the chargo is Prove that for a uniformly charged disk with a surface charge density a (on each side), the electric field strength on the axis of the disk is the same as for an infinitely large flat plate if the distances arc small in comparison with the disk's radius R, and is the same as for a point charge if the distances are large ** Usually the value of the field strength given in textbooks is half the one given here, since there it is assumed that the charge is on a geometric plane

The source is at some distance from an obstacle. Distance between obstacle and the point of observation is b and wavelength of light is lambda . Then the average distance of nth Fresnel zone will be at a distance …from the point of observation.

In Young's double experiment , in air interference pattern second minimum is observed exactly in front of one slit. The distance beween the two coherent source is 'd' and the distance between source and screen 'D'. The wavelength of light source used is

A point source of light is placed at distance h below the surface of a large and deep lake. What fraction of light will escape through the surface of water?