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Question
Draw a ray diagram to show the working of a compound microscope. Deduce an expression for the total magnification when the final image is formed at the near point.
In a compound microscope, an object is placed at a distance of 1.5 cm from the objective of focal length 1.25 cm. If the eye piece has a focal length of 5 cm and the final image is formed at the near point, estimate the magnifying power of the microscope.
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Solution
Ray diagram for a compound microscope
Total angular magnification, `m = beta/alpha`
β → Angle subtended by the image
α → Angle subtended by the object
Since α and β are small,
`tan alpha ≈ alpha and tan beta ≈ beta`
`m= (tanbeta)/(tanalpha)`
`tan alpha = (AB)/D`
And
`tan beta = (A''B'')/D`
`m = (tanbeta)/(tanalpha) = (A''B'')/D xx D/(AB) = (A''B'')/(AB)`
On multiplying the numerator and the denominator with A′B′, we obtain
`m = (A''B'' xx A'B')/(A'B' xx AB)`
Now, magnification produced by objective, `m_0 = (A'B')/(AB)`
Magnification produced by eyepiece, `m_e = (A''B'')/(AB)`
Therefore,
Total magnification, (m) = m0 me
`m_0 = ( V_0) / (u_0) =(\text { Image distance for image produced by objective lens})/(\text { Object distance for the objective lens})`
`m_e = (1+D/(f_e))`
fe → Focal length of eyepiece
`m = m_0m_e`
`= V_0/u_0(1+D/f_e)`
`V_0 ≈ L`(Separation between the lenses)
`u_0 ≈ -f_0`
`therefore m = (-L)/(f_0) (1 +D/f_e)`
`u_0 = -1.5 cm`
`f_0 = +1.5cm`
`1/f_0 = 1/v_0 - 1/u_0`
`1/1.25 =1/v_0 + 1/1.5`
`1/v_0=1/1.25 - 1/1.5`
`= 100/125 - 10/15`
`= (1500 -1250)/1875`
`1/v_0 = 250/1875`
`v_0 = + 7.5 cm`
`f_e = + 5cm`
`m =v_0/u_0 (1+D/f_e)`
`= 7.5 / - 1.5 (1+25/5)`
`= - 7.5/1.5 xx 6`
`m =-30`
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Which of the following is not correct in the context of a compound microscope?
