2011 CBSE CBSE Board Previous Year Question Paper 2011 for Class 12 Physics Question paper
Are you looking for the old question papers of CBSE 2011? Here is the previous year question paper of Central Board of School Education. This is the original question paper CBSE Board Previous Year Question Paper 2011 for Class 12 Physics exam conducted by CBSE in year 2011. Feel free to download the question paper from here and use it to prepare for your upcoming exams.
CBSE Board Previous Year Question Paper 2011 for Class 12 Physics
Time: 3 hours
1. All questions are compulsory.
2. There is no overall choice. However, an internal choice has been pro vided in one question of
two marks, one question of three marks and all three questions of five marks. You have to
attempt only one of the choices in such questions.
3. Question numbers 1 to 5 are very short answer type questions, carrying one mark each.
4. Question numbers 6 to 12 are short answer type questions, carrying two marks each.
5. Question numbers 13 to 24 are also short answer type questions, carrying three marks each.
6. Question numbers 25 to 27 are long answer type questions, carrying five marks each.
7. Use of calculators is not permitted However, you may use log tables, f necessary.
8. You may use the following values of physical constants wherever necessary.
Q. 1. Write two properties of a material used as a suspension wire in a moving coil galvanometer. 1
Q. 2. Name the experiment which establishes the wave nature of a particle. 1
Q. 3. Write the S.I. unit for the activity of a radioactive nuclide. 1
Q. 4. The a.c. current gain of a transistor is 120. What is the change in the collector current in the
transistor whose base current changes by 1
Q. 5. Name the underlying principle of the working of an optical fibre. 1
Q. 6. Define dielectric constant of a medium. Briefly explain why the capacitance of a parallel plate
capacitor increases, oii introducing a dielectric medium between the plates. 2
Q. 7. Why does a paramagnetic substance display greater magnetisation for the same magnetising
field when cooled? How does a diamagnetic substance respond to similar temperature changes? 2
Q. 8. Explain how electron mobility changes for a good conductor when (i) the temperature of the
conductor is decreased at constant potential difference and (ii) applied potential difference is
doubled at constant temperature. 2
Q. 9. A capacitor and a resistor are connected in series with an a.c. source. If the potential difference
across C, R are 120 V, 90 V rspectively and if the r.m.s. current of the circuit is 3 A, calculate the (i)
impedance, (ii) power factor of the circuit. 2
An inductor 200 mH, a capacitor C and a resistor 10 ohm are connected in series with a 100 V, 50 s
a.c. source. If the current and voltage arc in phase with each other, calculate the capacitance of the
capacitor. Q. 10. Draw the curve showing variation of binding energy/nucleon with mass number of different
nuclei. Briefly state, how nuclear fusion and nuclear fission can be explained on the basis of this
Q. 11. Give r for the following:
(a) Rainbow is never observed on the surface of the Moon.
(b) The Sun looks reddish at sunrise and sunset as viewed from Earth. 2
Q. 12. The following figure shows the input waveforms (A, B) and the output waveform (Y) of a gate.
Identify the gate and write its truth table. 2
Q. 13. What are eddy currents? How are these minimised? Mention two applications of eddy
Q. 14. Draw the graphs showing the variation of photoelectric current with an ode potential of a
photocell for (i) the same frequencies but different intensities I1 > I2 > I3, of incident radiation, (ii) the
same intensity but different frequencies V1 > V2 > V3 of incident radiation.
Explain why the saturation current is independent of the anode potential. 3
Q. 15. State Faradays laws of electrolysis. Deduce the relation connecting Faraday constant,
chemical equivalent and electrochemical equivalent. 3
Q. 16. 4 cells of identical emf E, internal resistance r, are connected in series to a variable resistor.
The following graph shows the variation of terminal voltage of the combination with the current
output: (i) What is the emf of each cell used?
(ii) For what current from the cells, does maximum power dissipation occur in the circuit?
(iii) Calculate the internal resistance of each cell. 3
Q. 17. What is pulse modulation? Distinguish between pulse amplitude modulation and pulse
duration modulation by drawing suitable modulated signals. 3
Q. 18. Write any two criteria required for a detector of an optical communication system.
A photo-detector is made from a semiconductor having Eg = 0.73 eV. What is the maximum
wavelength which it can detect? 3
Q. 19. Using Gauss theorem, deduce an expression for the electric field intensity at any point due to a
thin, infinitely long wire of charge/length 3
Using Gauss theorem, derive an expression for the electric field intensity at any point outside a
charged spherical shell of radius R and of charge density
Q. 20. A metallic square loop ABCD of size 15 cm and resistance is moved at a uniform velocity
of v m/s, in a uniform magnetic field of 2 Tesla, the field lines being normal to the plane of the paper.
The loop is connected to an electrical network of resistors, each of resistance Calculate the
speed of the loop, for which 2 m A current flows in the loop. 3
Q. 21. Sketch a graph showing the variation of potential energy of a pair of nucleons as a function of
their separation. Write three characteristic properties of nuclear force which distinguish it from the
electrostatic force. 3
Q. 22. Explain, using Huygen principle, how diffraction is produced by a narrow slit which is
illuminated by a monochromatic light. Show that central maximum is twice as wide as the other
maxima and the pattern becomes narrower as the width of the slit is increased. 3
Q. 23. Draw a labelled diagram o the experimental set-up used by Hertz to produce electromagnetic
waves. Explain how the electromagnetic waves are detected. 3
Q. 24. Define the term electric potential due to a point charge.
Calculate the electric potential at the centre of a square of side having charges
at the four corners of the square. 3
Q. 25. Derive an expression for the magnetic field along the axis of an air-cored solenoid, using
Amperes circuital law. Sketch the magnetic field lines for a finite solenoid. Explain why the field at
the exterior mid-point is weak while at the interior it is uniform and strong. 5
Explain with the help of a labelled diagram the working principle of a cyclotron.
Show that the cyclotron frequency does not depend on the speed of the particle. Write one of the
uses and point out one of the drawbacks of a cyclotron.
Q. 26. Draw a labelled circuit diagram of a transistor oscillator. Briefly explain its principle and state
how the oscillations are sustained. 5
Draw the energy band diagrams of p-type, n-type semiconductors. Explain with a circuit diagram the
working of a full wave rectifier.
Q. 27. (i) Draw a labelled ray diagram of a compound microscope, showing the formation of image at
the near point of the eye.
(ii) A compound microscope uses an objective lens of focal length 4 cm and eye lens of focal length
10cm. An object is placed at 6 cm from the objective lens.
(a) Calculate magnifying power of the compound microscope, if the final image is formed at the near
(b) Calculate the length of the compound microscope also. 5
Draw a labelled ray diagram of an astronomical telescope, forming the image at infinity.
As astronomical telescope uses two lenses of powers 10 diopter, 1 diopter.
(i) State with reason, which lens is preferred as objective and eye-piece.
(ii) Calculate the magnifying power of the telescope, if the final image is formed at the near point.
(iii) How do the light gathering power and resolving power of a telescope change, if the aperture of
the objective lens is doubled ?
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