Consider the following diagram representing magnitude of magnification against image distance for a convex lens:

`{:("Column I","Column II"),((A)"Focal length of the lens",(p)"Inverse of slope of line"),((B)"Intercept on x- axis",(q) "Unity"),((C)"Intercept on y-axis" , (r) "Focal length") , ((D) "Magnitude of slope of the line(s)", (s) "Inverse of the focal length"):}`

The following graph depicts the inverse of magnification versus the distance between the object and lens data for a setup. The focal length of the lens used in the setup is

An object of height 4.25 mm is placed at a distance 10 cm from a convex lens of power +5 D. Find (i) focal length of the lens, and ii) size of the image.

The distance between the object and the real image formed by a convex lens is d. If the linear magnification is m, find the focal length of the lens in terms of d and m.

A simple telescope used to view distant objects has eyepiece and objective lens of focal lengths f_(e) and f_(0) , respectively. Then {:("Column I","Column II"),("(A)Intensity of light","(P)Radius of aperature R"),("received by lens",),("(B)Angular magnification","(Q) Dispersion of lens"),("(C) Length of telescope","(R) focal length "f_(0)"," f_(e)),("(D) Sharpness of image","(S) spherical aberration"):}

The graph in Fig. shows how the inverse of magnification 1//m produced by a convex thin lens varies with object distance u . What was the focal length of the lens used ? .

A small pin of size 5 mm is placed along principal axis of a convex lens of focal length 6cm at a distance 11cm from the lens. Find the size of image of pin. [7.2 mm]

When an object is at distances x and y from a lens, a real image and a virtual image is formed respectively having same magnification. The focal length of the lens is