a) Frequency: 62.7 Hz
b) Resistance: [tex]186.3\Omega[/tex]
c) Average power: 38.6 W
Explanation:
a)
An alternating current can be written in the form
[tex]I(t)=I_0 sin(\omega t)[/tex]
where
[tex]I_0[/tex] is the maximum current in the bulb
[tex]\omega=2\pi f[/tex] (1) is the angular frequency, where f is the frequency
t is the time
Here the current in the bulb is
[tex]I(t)=(0.644 A)(sin (394 rad/s\cdot t)[/tex]
This means that
[tex]\omega=394 rad/s[/tex]
And therefore by using formula (1), we can find the frequency:
[tex]f=\frac{\omega}{2\pi}=\frac{394}{2\pi}=62.7 Hz[/tex]
b)
The resistance of the bulb's filament can be found by using Ohm's law:
[tex]V=RI[/tex]
where
V is the voltage
R is the resistance
I is the current
Here we have:
[tex]V_0 = 120.0 V[/tex] (maximum voltage)
[tex]I_0 = 0.644 A[/tex] (maximum current)
Therefore, the resistance of the bulb is
[tex]R=\frac{V_0}{I_0}=\frac{120}{0.644}=186.3 \Omega[/tex]
c)
In this circuit, the average power delivered to the light bulb is equal to the average power dissipated by the resistor.
For an AC circuit, the average power dissipated on a resistor is given by
[tex]P=I_{rms}^2 R[/tex]
where
[tex]I_{rms}[/tex] is the rms current
The rms current can be calculated as
[tex]I_{rms}=\frac{I_0}{\sqrt{2}}[/tex]
where in this case
[tex]I_0 =0.644 A[/tex] is the peak current
Here the resistance is
[tex]R=186.3 \Omega[/tex]
Therefore, the average power is:
[tex]P=(\frac{I_0}{\sqrt{2}})^2R=(\frac{0.644}{\sqrt{2}})^2(186.3)=38.6 W[/tex]
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