V = IZ
V = rms voltage, I = rms current, Z = total circuit impedance
The impedance Z of a device is sometimes expressed as the sum of a real and imaginary component:
Z = R + jX
R = resistance, j = [tex]\sqrt{-1}[/tex], X = reactance
The impedance of a capacitor is -j/(ωC)
ω = ac source frequency, C = capacitance
We can see that the impedance of a capacitor has no real component and has a negative imaginary component, that is to say:
Z = -jX, where we're given X = 100Ω, so Z = -j100Ω
The impedance of an inductor is jωL, ω = source frequency, L = inductance
We can see that the impedance of an inductor has no real component and has a positive imaginary component, that is to say:
Z = jX, where we're given X = 80Ω, so Z = j80Ω
The impedance of a resistor is simply R, R = resistance
WE can see that the impedance of a resistor has a positive real component and no imaginary component, that is to say:
Z = R, where we're given R = 40Ω, so Z = 40Ω
Add up the impedances to get the total impedance:
Z = 40Ω + j80Ω - j100Ω = (40-j80)Ω
To get the rms source voltage, we multiply the rms current I and the impedance Z. These two quantities will be complex numbers, and the math behind multiplying two complex numbers involves multiplying their magnitudes. We already have the magnitude of the rms current 2.2A, so let's calculate the magnitude of the impedance:
|Z| = √(40²+(-80)²)Ω = 89.44Ω
Now let's calculate the rms source voltage V = IZ:
V = 2.2A(89.44Ω)
V = 197V
