Electronics/Electronics Formulas/Series Circuits/Series RL

The total Impedance of the circuit

${\displaystyle Z=Z_R+Z_L}$

${\displaystyle Z=R+j\omega L}$

${\displaystyle Z=\frac{1}{R}(1+j\omega T)}$

${\displaystyle T=\frac{L}{R}}$

The 1st order Differential equation of the circuit in equilibrium

${\displaystyle L\frac{di}{dt}+iR=0}$

${\displaystyle \frac{di}{dt}+i\frac{R}{L}=0}$

${\displaystyle \int \frac{di}{i}=-\frac{R}{L}\int dt}$

${\displaystyle Lni=-\frac{t}{T}+c}$

The root of the equation is a Exponential Decay function characterised the Natural Response of the circuit

${\displaystyle i=A{e}^{(}-\frac{t}{T})}$

${\displaystyle Z=Z_R+Z_L}$

${\displaystyle Z=R\mathrm{\angle }0+\omega L\mathrm{\angle }90}$

${\displaystyle Z=|Z|\mathrm{\angle }\theta }$

${\displaystyle Z=\sqrt{R^2+(\omega L{)}^2}\mathrm{\angle }\omega \frac{L}{R}}$

Phase Shift , Change in Frequency relate to change in RL value

${\displaystyle Tan\theta =\omega \frac{L}{R}=2\pi f\frac{L}{R}=2\pi \frac{1}{t}\frac{L}{R}}$

Series RL is characterised by

1st ordered Differential equation of the circuit at equilibrium.

${\displaystyle \frac{di}{dt}+\frac{1}{T}=0}$

Natural Reponse of the circuit is the Exponential Decay

${\displaystyle i=A{e}^{(}-\frac{t}{T})}$

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