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Counter-Strike: Source (2004)

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In an a.c. circuit containing ohmic \( E=E_{0} \sin \omega t \), then \( I=I_{0} \sin (\omega t+\phi) \) resistance \( R \) only, voltage and current are in the same phase.
If \( \quad E=E_{0} \sin \omega t \), \( \phi=\tan ^{-1} \frac{\left(X_{C}-X_{L}\right)}{R} \)
then \( I=I_{0} \sin \omega t \)
Effective resistance in \( a \).c. circuit \( =R \).
The effective resistance of \( R L C \) circuit is
In an a.c. circuit containing inductance \( (L) \) only, \( Z=\sqrt{R^{2}+\left(X_{L}-X_{C}\right)^{2}} \) alternating current \( I \) lags behind the alternating voltage \( Z \) is called impedance of the circuit. ( \( E \) ) by a phase angle of \( \pi / 2 \). If \( E=E_{0} \sin \omega t \);
Fig. 7.5 shows what is called impedance then \( I=I_{0} \sin (\omega t-\pi / 2) \)
Inductive reactance, \( X_{L}=\omega L=2 \pi v L \)
In an a.c. circuit containing a capacitor of capacitance \( C \), alternating current is ahead of alternating voltage by a phase angle of \( \pi / 2 \).
If \( E=E_{0} \sin \omega t \), then \( I=I_{0} \sin (\omega t+\pi / 2) \) triangle.
Capacitative reactance, \( X_{C}=\frac{1}{\omega C}=\frac{1}{2 \pi v C} \)
In an a.c. circuit containing ohmic resistance \( R \),
- an inductance \( L \) and a capacitance \( C \) in series if
FIGURE \( 7.5 \)
When frequency of a.c. is doubled, the ratio of inductive reactance to capacitative reactance becomes
(a) 1
(b) 2
(c) 3
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