A standing wave `y = 2A sin kx cos omegat` is set up in the wire `AB` fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field `B`. Now answer the following question:

The wire is found to vibrate in the third harmonic. The maximum emf induced is

A standing wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . Now answer the following question: In which of the following modes the emf induced in AB is always zero?

A stsnding wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . Now answer the following question: In which of the following modes the emf induced in AB is always zero?

A standing wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . The wire is found to vibrate in the third harmonic. Now answer the following question: In the above qestion, the time when the emf becomes maximum for the time is

A standing wave y=2A sinkx cos omegat is setup in the wire AB fixed at both ends by two vertical walls (see the figure). the region between the wall contains a constant magnetic field B . Now answer the following questions. In the above question, the time when the emf becomes maximum for the first time is

The four wire loops shown figure have vertical edge lengths of either L, 2L or 3L . They will move with the same speed into a region of uniform magnetic field vec(B) directed out of the page. Rank them according to the maximum magnitude of the induced emf greatest to least.

Estimation of frequency of a wave forming a standing wave represented by y = A sin kx cos t can be done if the speed and wavelength are known using speed = "Frequency" xx "wavelength" . Speed of motion depends on the medium properties namely tension in string and mass per unit length of string . A string may vibrate with different frequencies . The corresponding wavelength should be related to the length of the string by a whole number for a string fixed at both ends . Answer the following questions: A string fixed at both ends having a third overtone frequency of 200 Hz while carrying a wave at a speed of 30 ms^(-1) has a length of

Estimation of frequency of a wave forming a standing wave represented by y = A sin kx cos t can be done if the speed and wavelength are known using speed = "Frequency" xx "wavelength" . Speed of motion depends on the medium properties namely tension in string and mass per unit length of string . A string may vibrate with different frequencies . The corresponding wavelength should be related to the length of the string by a whole number for a string fixed at both ends . Answer the following questions: Speed of a wave in a string forming a stationary wave does not depend on

Estimation of frequency of a wave forming a standing wave represented by y = A sin kx cos t can be done if the speed and wavelength are known using speed = "Frequency" xx "wavelength" . Speed of motion depends on the medium properties namely tension in string and mass per unit length of string . A string may vibrate with different frequencies . The corresponding wavelength should be related to the length of the string by a whole number for a string fixed at both ends . Answer the following questions: If y = 10 sin 5 x cos 2 t m represents a stationary wave then , the possible one of the travelling waves causing this is

A fan operates at 200 volt (DC) consuming 1000W when running at full speed . It's internal wiring has resistance 1 Omega . When the fan runs at full speed , its speed becomes constant. This is because the torque due to magnetic field inside tha fan is balanced by the torque due to air resistance on the blades of the fan and torque due to friction between the fixed part and the shaft of the fan. The electrical power going into the fan is spent (i) in the internal resistance as heat, call it P_(1)(ii) in doing work against internal friction and air resistance producing heat, sound etc. call it P_(2) . When the coil of fan rotates, an emf is also induced in the coil. This opposes the external emf applied to snd the current into the fan. This emf is called back-emf,call it 'e' . Answer the following questions when the fan is running at full speed. The current flowing into the fan and the value of back emf e is

A fan operates at 200 volt (DC) consuming 1000W when running at full speed . It's internal wiring has resistance 1 Omega . When the fan runs at full speed , its speed becomes constant. This is because the torque due to magnetic field inside tha fan is balanced by the torque due to air resistance on the blades of the fan and torque due to friction between the fixed part and the shaft of the fan. The electrical power going into the fan is spent (i) in the internal resistance as heat, call it P_(1)(ii) in doing work against internal friction and air resistance producing heat, sound etc. call it P_(2) . When the coil of fan rotates, an emf is also induced in the coil. This opposes the external emf applied to snd the current into the fan. This emf is called back-emf,call it 'e' . Answer the following questions when the fan is running at full speed. The current flowing into the fan and the value of back emf e is