4) A long solenoid has n=900 turns per meter and a current I = 3.2 sin(wt). Inside the solenoid with a= 0.5 m and coaxial with it is a coil that has a radius of b = 0.2 m and consists of Nc = 100 turns in Figure. Circuit has a variable resistor, and at t=2 s resistor has 5 2. (a) Find the induced emf in the coil as a function of time if f=10 Hz. (b) Find the self-inductance of solenoid. (c) Find the current Irms of the circuit. (d) Write the expressions for E and B generated by solenoid in the form E = 8 sin(kx – wt) and B = Bmax sin(kx – wt) with numerical values for B, m, and the period T=4 s. (Ho = 4n × 10-7 T. m/A, c = 3 × 108 m/s) k, and w when the wavelength 2 = 50 max> Coil, Ne turns with radius b = 0.2 m Solenoid, n turns per meter 1 = 3.2 sin(wt) I = 3.2 sin(wt) %|

Transcribed Image Text:

with a= 0.5 m and coaxial with it is a coil that has a radius of b = 0.2 m and consists of N. = 100 turns in Figure. Circuit has a variable resistor, and at t=2 s resistor has 5 Q. (a) Find the induced emf in the coil as a function of time if f=10 Hz. (b) Find the self-inductance of solenoid. (c) Find the current Irms of the circuit. (d) Write the expressions for E and B generated by solenoid in the form E = 8 sin(kx – wt) and B = Bmax sin(kx – wt) with numerical values for Bmax, k, and w when the wavelength A = 50 m, and the period T=4 s. (µo = 4T × 10-7 T. m/A, c = 3 × 10® m/s) та Coil, No turns with radius b = 0.2 m %3D Solenoid, n turns per meter 1 = 3.2 sin(wt)| I = 3.2 sin(wt) V = 16 sin(wt) 5Ω Variable resistor

Transcribed Image Text:

4) A long solenoid has n=900 turns per meter and a current I = 3.2 sin(wt). Inside the solenoid with a= 0.5 m and coaxial with it is a coil that has a radius of b = 0.2 m and consists of N, = 100 turns in Figure. Circuit has a variable resistor, and at t=2 s resistor has 5 2. (a) Find the induced emf in the coil as a function of time iff=10 Hz. (b) Find the self-inductance of solenoid. (c) Find the current Irms of the circuit. (d) Write the expressions for E and B generated by solenoid in the form E = 8 sin(kx – wt) and S В Bmax sin(kx – wt) with numerical values for Bmax, k, and w when the wavelength 1 = 50 - m, and the period T=4 s. (µo = 47T × 10-7 T. m/A, c = 3 × 10® m/s) Coil, No turns with radius b = 0.2 m Solenoid, n turns per meter I = 3.2 sin(wt). I = 3.2 sin(wt)