A flux of 1m Wb passes through a strip having an area `A=0.02 m^(2)`. The plane of the strip is at an angle of `60^(@)` to the direction of a uniform field B. The value of B is-

A flux of 10^(-3)Wb passes through a strip having an area A = 0.02m^(2) . The plane of the strip is at an angle of 60^(@) to be direction of a uniform field B. The value of B is

A flux of 10^(-3)Wb passes through a strip having an area A = 0.02m^(2) . The plane of the strip is at an angle of 60^(@) to be direction of a uniform field B. The value of B is

A coil of 100 turns and area 5 square centimetre is placed in a magnetic field B = 0.2 T . The normal to the plane of the coil makes an angle of 60^(@) with the direction of the magnetic field. The magnetic flux linked with the coil is

A coil of 100 turns and area 5 square centimetre is placed in a magnetic field B = 0.2 T . The normal to the plane of the coil makes an angle of 60^(@) with the direction of the magnetic field. The magnetic flux linked with the coil is

A coil of 100 turns and area 5 square centimetre is placed in a magnetic field B = 0.2T. The normal to the plane of the coil makes an angle of 60^(@) with the direction of the magnetic field. The magnetic flux linked with the coil is

Fig shown below represents an area A = 0.5 m^(2) situated in a uniform magnetic field B = 2.0 "weber"//m^(2) and making an angle of 60^(@) with respect to magnetic field. The value of the magnetic flux through the area would be equal to

A coil of area 5cm^(2) and having 20 turns is placed in a uniform magnetic field of 10^(3) gauss. The normal to the plane of the coil makes an angle of 60^(@) with the magnetic field. The flux in Maxwell through the coil is: