Dear Readers, Welcome to Magnetism and Electromagnetism Objective Questions have been designed specially to get you acquainted with the nature of questions you may encounter during your Job interview for the subject of Magnetism and Electromagnetism MCQs. These objective type Magnetism and Electromagnetism Questions are very important for campus placement test and job interviews. As per my experience good interviewers hardly plan to ask any particular question during your Job interview and these model questions are asked in the online technical test and interview of many IT companies.
(a) field strength
(b) inductance
(c) flux density
(d) flux
Ans: c
(a) which is a good conductor
(6) which is a bad conductor
(c) which is a strong magnet
(d) through which the magnetic lines of force can pass very easily
Ans: d
(a) weak magnets
(b) temporary magnets
(c) permanent magnets
(d) none of the above
Ans: b
(a) iron
(b) copper
(c) aluminium
(d) moving charges
Ans: d
(a) paramagnetic
(b) diamagnetic
(c) ferromagnetic
(d) none of the above
Ans: c
(a) little
(b) lower
(c) higher
(d) zero
Ans: b
(a) from south pole to north pole
(b) from north pole to south pole
(c) from one end of the magnet to another
(d) none of the above
Ans: b
(a) Relative permeability
(b) Magnetic field intensity
(c) Flux density
(d) Magnetic potential
Ans: b
(a) proportional to 7
(b) proportional to X
(c) proportional to distance between the conductors
(d) inversely proportional to I
Ans: b
(a) ferromagnetic material
(b) diamagnetic material
(c) paramag>etic material
(d) conducting material
Ans: b
(a) the magnetic lines of force will bend away from their usual paths in order to go away from the piece
(b) the magnetic lines of force will bend away from their usual paths in order to pass through the piece
(c) the magnetic field will not be affected
(d) the iron piece will break
Ans: b
(a) direction of magnetic field due to current carrying conductor
(b) direction of flux in a solenoid
(c) direction of force on a current car¬rying conductor in a magnetic field
(d) polarity of a magnetic pole
Ans: c
(a) flux density
(b) susceptibility
(c) relative permeability
(d) none of the above
Ans: b
(a) it corrodes easily
(6) it has high permeability
(c) it has high specific gravity
(d) it has low permeability
Ans: d
(a) current, induced e.m.f. and direc¬tion of force on a conductor
(b) magnetic field, electric field and direction of force on a conductor
(c) self induction, mutual induction and direction of force on a conductor
(d) current, magnetic field and direc¬tion of force on a conductor
Ans: d
(a) henry/metre
(b) henry
(c) henry/sq. m
(d) it is dimensionless
Ans: d
(a) zero
(b) BLI
(c) B2LI
(d) BLI2
Ans: a
(a) radius of conductors
(b) current in one conductor
(c) product of current in two conduc¬tors
(d) distance between the conductors
Ans: d
(a) large area oiB-H loop
(b) high permeability and low hysteresis loss
(c) high co-ercivity and high reten-tivity
(d) high co-ercivity and low density
Ans: b
(a) Soft iron
(b) Stainless steel
(e) Hardened steel
(d) None of the above
Ans: a
(a) cobalt
(b) chromium
(c) nickel
(d) tungsten
Ans: c
(a) magnetoes
(6) energy meters
(c) transformers
(d) loud-speakers
Ans: c
(a) slightly less than uuity
(b) equal to unity
(c) slightly more than unity
(d) equal to that ferromagnetic mate rials
Ans: c
(a) removal of magnetic impurities
(b) removing gases from the materials
(c) remagnetising metallic parts
(d) demagnetising metallic parts
Ans:
(a) ferromagnetic
(b) paramagnetic
(c) diamagnetic
(d) bipolar
Ans: c
(a) 2 x 1(T2 N/m)
(b) 2 x KT3 N/m
(c) 2 x 10"5 N/m
(d) 2x 1(T7 N/m)
Ans: d
27. In the left hand rule, forefinger always represents
(a) voltage
(b) current
(c) magnetic field
(d) direction of force on the conductor
Ans: c
(a) Tungsten
(b) Aluminium
(c) Copper
(d) Nickel
Ans: d
(a) non-magnetic materials
(6) ferro-magnetic materials
(c) paramagnetic materials
(d) ferri-magnetic materials
Ans: d
(a) electromotive force
(6) magnetomotive force
(c) conductance
(d) permittivity
Ans: b
(a) meter is surrounded by strong magnetic fields
(b) a soft iron shielding is used
(c) a plastic shielding is provided
(d) a shielding of anon-magnetic material is used
Ans: b
(a) reluctivity
(b) susceptibility
(c) permittivity
(d) conductance
Ans: a
(a) ferromagnetic materials
(b) ferrites
(c) non-ferrous materials
(d) diamagnetic materials
Ans: d
(a) weber
(b) lumens
(c) tesla
(d) none of the above
Ans: c
(a) permeance
(b) residual magnetism
(c) susceptance
(d) reluctance
Ans: b
(a) Maxwell
(b) Telsa
(c) Weber
(d) All of the above
Ans: b
(a) Brass
(b) Copper
(c) Zinc
(d) Ebonite
Ans: d
(a) 1 Wb/mm2
(b) 1 Wb/m
(c) 1 Wb/m2
(d) 1 mWb/m2
Ans: c
(a) The electric intensity is a vector quantity
(b) The electric field intensity at a point is numerically equal to the force exerted upon a charge placed at that point
(c) An electric field is defined as a point in space at which an electric charge would experienc* a force
(d) Unit field intensity in the exertion of a force of one newton on a charge of one coulomb
Ans: b
(a) resistance of the coil
(b) motion of the magnet
(c) number of turns of the coil
(d) pole strength of the magnet
Ans: a
(a) 10 webers
(b) 10 webers
(c) 10 webers
(d) 10 webers
Ans: d
(a) will be zero
(b) will be infinite
(c) will depend on the amount of e.m.f. applied
(d) will depend on the radius of the circle
Ans: d
(a) non-magnetic substances
(b) diamagnetic substances
(c) ferromagnetic substances
(d) none of the above
Ans: c
(a) 100 N
(b) 10 N
(c) 1 N
(d) 0.1 N
Ans: d
(a) 240 N
(6) 24 N
(c) 2.4 N
(d) 0.24 N
Ans: c
(a) 8 N-m
(b) 0.48 N-m
(e) 0.048 N-m
(d) 0.0048 N-m
[Hint. Torque = 2BIlNr N-m]
Ans: c
(a) 2500 AT/m
(b) 250 AT/m
(c) 25 AT/m
(d) 2.5 AT/m
Ans: b
(a) 22 x 10"8 N
(b) 22 x 10"7 N
(c) 22 x 10-6 N
(d) 22 x 10"5 N
Ans: d
(a) 63.38 N/Wb
(b) 633.8 N/Wb
(c) 6338 N/Wb
(d) 63380 N/Wb
Ans: c
(a) reluctance
(b) resistance
(c) permeance
(d) pole strength
Ans: d
(a) ampere-hour
(b) watt
(c) joule
(d) coulomb
Ans: d
(a) Kirchhoffs law
(b) Lenz's law
(c) Ampere's law
(d) Faraday's laws
Ans: c
(a) placing it inside a coil carrying current
(b) induction
(c) the use of permanent magnet
(d) rubbing with another magnet
Ans: a
(a) copper
(b) aluminium
(c) soft iron
(d) brass
Ans: c
(a) less than that of disc but in opposite direction
(b) equal to that of disc and in the same direction
(c) equal to that of disc and in the opposite direction
(d) less than that of disc and in the same direction
Ans: d
(a) attracts some substances and repels others
(b) attracts all paramagnetic substan¬ces and repels others
(c) attracts only ferromagnetic sub¬stances
(d) attracts ferromagnetic substances and repels all others
Ans: a
(a) permanent magnets
(b) transformers
(c) non-magnetic substances
(d) electromagnets
Ans: a
(a) diamagnetic
(b) paramagnetic
(c) ferromagnetic
(d) insulating
Ans: c
(a) ferromagnetic
(b) paramagnetic
(c) diamagnetic
(d) dielectric
Ans: c
(a) circular
(b) triangular
(c) rectangular
(d) none of the above
Ans: c
(a) M
(6) M/2
(c) 2 M
(d) M/4
Ans: b
(a) change the direction of magnetic lines
(b) amplify flux
(c) restore lost flux
(d) provide a closed path for flux
Ans: d
(a) pole strength
(6) universal constant
(c) scalar quantity
(d) vector quantity
Ans: d
(a) reluctance of conductor
(b) resistance of conductor
(c) (a) and (b) b >th in the same way
(d) none of the above
Ans: c
(a) the field of a set of parallel conductors
(b) the field of a single conductor
(c) the field in which all lines of mag¬netic flux are parallel and equidis¬tant
(d) none of the above
Ans: c
(a) the voltage across the two ends of exciting coil
(b) the flow of an electric current
(c) the sum of all currents embraced by one line of magnetic field
(d) the passage of magnetic field through an exciting coil
Ans: c
(a) 2
(b) 4
(c) 6
(d) 8
Ans: b
(a) 2 AT
(b) 4 AT
(c) 6 AT
(d) 10 AT
Ans: b
(a) The magnetic flux inside an exciting coil is lower than its outside surface
(6) The magnetic flux inside an exciting coil is zero
(e) The magnetic flux inside the exciting coil is greater than its outside surface
(d) The magnetic flux inside the exciting coil is same as on its outside surface
Ans: d
(a) Decreases
(b) Increases
(c) Remains same
(d) First increases and then decreases depending on the depth of iron in¬sertion
Ans: b
(a) decreases with increasing cross sectional area of material
(6) increases with increasing cross-sec-tional area of material
(c) does not vary with increasing cross-sectional area of material
(d) any of the above
Ans: a
(a) the highest permeability of the iron rod
(b) the lowest permeability of the iron rod
(c) the permeability at the end of the iron rod
(d) the permeability almost in non-magnetised state
Ans: d
(a) It assures a position right angle to magnetic field
(b) It starts rotating
(c) It assures a position which follows a line of magnetic flux
(d) None of the above
Ans: c
(a) is constant and has same value in energy part of the magnetic field
(6) increases continuously from initial value to final value
(c) decreases continuously from initial value to final value
(d) first increases and then decreases till it becomes zero
Ans: d
(a) a line vertical to the flux lines
(b) the mean length of a ring shaped coil
(c) a line of magnetic flux in a non-uniform field
(d) a line of magnetic flux which does not follow the designed path
Ans: d
(a) the dipole moment
(b) monopole moment
(c) (a) and (b) both
(d) none of the above
Ans: a
(a) Silver
(b) Copper
(c) Silver and copper
(d) Iron
Ans: c
(a) Ferromagnetic
(b) Paramagnetic
(c) Diamagnetic
(d) None of the above
Ans: c
(a) KT3 and 1CT6
(b) 1CT3 and 1CT7
(c) KT4 and KT8
(d) 10"2 and KT5
Ans: a
(a) Ferromagnetic materials
(6) Paramagnetic materials
(c) Diamagnetic materials
(d) Ferrites
Ans: d
(a) orbital motion of electrons
(b) spin of electrons
(c) spin of nucleus
(d) either of these
(e) all of the above
Ans: c
(a) Diamagnetic materials
(b) Ferrimagnetic materials
(c) Antiferromagnetic materials
(d) Antiferrimagnetic materials
Ans: c
(a) core length increases i
(b) core area increases
(c) flux density decreases
(d) flux density increases
Ans: d
(a) The conductivity of ferrites is better than ferromagnetic materials
(b) The conductivity of ferromagnetic materials is better than ferrites
(c) The conductivity of ferrites is very high
(d) The conductivity of ferrites is same as that of ferromagnetic materials
Ans: a
(a) loud-speakers
(b) generators
(c) motors
(d) all of the above
Ans: d
(a) strong tendency of fan out of lami-nations at the end caused by repul¬sion among magnetic lines of force
(b) uneven bearing surface, caused by dirt or uneven wear between moving and stationary parts
(c) both of above
(d) none of the above
Ans: c
(a) increasing the cross-sectional area
(b) increasing the number of turns
(c) increasing current supply
(d) all above methods
Ans:
(a) low coercivity
(6) high susceptibility
(c) both of the above
(d) none of the above
Ans: c
(a) heating
(b) hammering
(c) by inductive action of another magnet
(d) by all above methods
Ans: d