Ray Optics And Optical Instruments MCQs With Answers – Part 3 (Class 12 Physics)
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Ray Optics and Optical Instruments MCQs with Answers – Part 3 (Class 12 Physics)

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201. A spherical refracting surface is convex as seen by incident light from the left. Its centre of curvature lies to the right of the pole. Under the usual Cartesian sign convention, \(R\) is
ⓐ. negative
ⓑ. zero
ⓒ. not assigned any sign
ⓓ. positive
202. A concave spherical refracting surface is seen by light incident from the left, and its centre of curvature is on the left of the pole. The sign of \(R\) is
ⓐ. positive because the surface is curved
ⓑ. zero because refraction occurs at one surface only
ⓒ. positive only if the second medium is glass
ⓓ. negative; the centre is opposite to incident light
203. A real object is placed in medium \(1\) on the left side of a spherical refracting surface, and light travels from left to right. The object distance \(u\) is generally
ⓐ. positive
ⓑ. zero
ⓒ. negative
ⓓ. equal to \(R\) for every object
204. The refraction formula at a spherical surface is different from the mirror formula mainly because
ⓐ. refractive indices multiply the distance terms
ⓑ. reflection and refraction always produce the same image position
ⓒ. the object distance is never signed in refraction
ⓓ. the radius of curvature is not used in refraction
205. A ray diagram for a spherical refracting surface is drawn using only paraxial rays. This restriction is used because
ⓐ. paraxial rays keep the simple formula valid
ⓑ. refraction does not occur for rays far from the axis
ⓒ. all rays far from the axis are absorbed by glass
ⓓ. the refractive index becomes zero near the principal axis
206. An object is placed \(45\,cm\) in front of a convex spherical glass surface. Light travels from air \((n_1=1.0)\) into glass \((n_2=1.5)\), and the radius of curvature of the surface is \(R=+30\,cm\). The image distance \(v\) is
ⓐ. \(+270\,cm\)
ⓑ. \(+90\,cm\)
ⓒ. \(-90\,cm\)
ⓓ. \(-270\,cm\)
207. A small object in air is placed \(30\,cm\) in front of a convex spherical glass surface of radius \(20\,cm\). For light travelling from air \((n_1=1.0)\) into glass \((n_2=1.5)\), the image distance is
ⓐ. \(-180\,cm\)
ⓑ. \(+180\,cm\)
ⓒ. \(-30\,cm\)
ⓓ. \(+60\,cm\)
208. In refraction from air \((n_1=1.0)\) into glass \((n_2=1.5)\) at a convex spherical surface of radius \(30\,cm\), a real object is placed \(90\,cm\) in front of the surface. The image distance is
ⓐ. \(-270\,cm\)
ⓑ. \(+90\,cm\)
ⓒ. \(+270\,cm\)
ⓓ. \(-45\,cm\)
209. A student is using \(\frac{n_2}{v}-\frac{n_1}{u}=\frac{n_2-n_1}{R}\) for a spherical refracting surface. Consider the statements: I. \(n_1\) belongs to the medium from which light is incident. II. \(n_2\) belongs to the medium into which light refracts. III. \(R\) is positive or negative according to the side of the centre of curvature. IV. The signs of \(u\), \(v\), and \(R\) may be ignored if distances are written in \(cm\). The suitable set is
ⓐ. I and IV only
ⓑ. II, III, and IV only
ⓒ. I, II, III, and IV
ⓓ. I, II, and III only
210. The sign of \(R\) is recorded for different spherical refracting surfaces with incident light travelling from left to right:
RowPosition of centre of curvatureSign of \(R\)
PRight of the polepositive
QLeft of the polenegative
RAt infinity for a plane surface\(R=\infty\)
SRight of the polenegative
The correct rows are
ⓐ. P and S only
ⓑ. P, Q, and R only
ⓒ. Q, R, and S only
ⓓ. P, Q, R, and S
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