Difference between revisions of "RC and RL Exponential Responses"

Revision as of 20:03, 15 June 2006

Summary of Equations

Exponential responses of C and L
	Discharging	Charging	Time Constant
Capacitor	$v_{C}(t)=V_{0}e^{-{\frac {t}{RC}}}$	$v_{C}(t)=V_{s}(1-e^{-{\frac {t}{RC}}})$	$RC\,$
Inductor	$i_{L}(t)=I_{0}e^{-{\frac {R}{L}}t}$	$i_{L}(t)=I_{0}(1-e^{-{\frac {R}{L}}t})$	${\frac {L}{R}}$

RC Circuits

Discharging

Consider the following circuit:

File:RC discharge schematic.jpg

In the circuit, the capacitor is initially charged and has voltage $V_{0}$ aross it, and the switch is initially open. At time $t=0$ , we close the circuit and the capacitor will discharge through the resistor. The voltage across a capacitor discharging through a resistor as a function of time is given as:

$v_{C}(t)=V_{0}e^{-{\frac {t}{RC}}}$

Charging

If the capacitor is initially uncharged and we want to charge it by inserting a voltage source $V_{s}$ in the RC circuit:

File:RC charge schematic.jpg

The voltage across the capacitor is given by:

$v_{C}(t)=V_{s}(1-e^{-{\frac {t}{RC}}})$

The term RC is the resistance of the resistor multiplied by the capacitance of the capacitor, and known as the time constant, which is a unit of time. The value of the function will be 63% of the final value at $t=1RC$ , and over 99.99% of the final value at $t=5RC$ .

The magnitudes of the voltage and current of the capacitor in the circuits above are shown in the graphs below:

Capacitor
	Voltage	Current
Charge	File:RC charge voltage.jpg	File:RC charge current.jpg
Discharge	File:RC discharge voltage.jpg	File:RC discharge current.jpg

RL Circuits

Discharging

In the following circuit, the inductor initially has current $I_{0}=V_{0}/R$ flowing through it; we replace the voltage source with a short circuit at $t=0$ .

File:RL discharge schematic.jpg

The current flowing through the inductor at time t is given by:

$i_{L}(t)=I_{0}e^{-{\frac {R}{L}}t}$

Charging

If the inductor is initially uncharged and we want to charge it by inserting a voltage source $V_{s}$ in the RL circuit:

File:RL charge schematic.jpg

The current through the inductor is given by:

$i_{L}(t)=I_{0}(1-e^{-{\frac {R}{L}}t})$

The time constant for the RL circuit is equal to $L/R$ .

The magnitudes of the voltage and current of the inductor for the circuits above are given by the graphs below:

Inductor
	Voltage	Current
Charge	File:RL charge voltage.jpg	File:RL charge current.jpg
Discharge	File:RL discharge voltage.jpg	File:RL discharge current.jpg

@@ Line 18: / Line 18: @@
 [[Image:RC_discharge_schematic.jpg]]
-In the circuit, the capacitor is initally charged and has voltage <math>V_0</math> aross it, and the switch is initially open.  At time <math>t=0</math>, we close the circuit and the capacitor will discharage through the resistor.  The voltage across a capacitor discharging through a resistor as a function of time is given as:
+In the circuit, the capacitor is initially charged and has voltage <math>V_0</math> aross it, and the switch is initially open.  At time <math>t=0</math>, we close the circuit and the capacitor will discharge through the resistor.  The voltage across a capacitor discharging through a resistor as a function of time is given as:
 <math>v_C(t)=V_0e^{-\frac{t}{RC}}</math>
 ===Charging===
-If the capacitor is initially uncharged and we want to charge it by inserting a voltage source <math>V_s</math> in the RC cicuit:
+If the capacitor is initially uncharged and we want to charge it by inserting a voltage source <math>V_s</math> in the RC circuit:
 [[Image:RC_charge_schematic.jpg]]
@@ Line 33: / Line 33: @@
 The term ''RC'' is the resistance of the resistor multiplied by the capacitance of the capacitor, and known as the ''time constant'', which is a unit of time.  The value of the function will be 63% of the final value at <math>t=1RC</math>, and over 99.99% of the final value at <math>t=5RC</math>.
-The magnitudes of the voltage and current of the capacitor in the circuit above are shown in the graphs below:
+The magnitudes of the voltage and current of the capacitor in the circuits above are shown in the graphs below:
 {| border="1" cellspacing="0" cellpadding="5" align="center"
@@ Line 48: / Line 48: @@
 ==RL Circuits==
 ===Discharging===
-In the following circuit, the inductor initally has current <math>I_0=V_0/R</math> flowing through it; we replace the voltage source with a short circuit at <math>t=0</math>.
+In the following circuit, the inductor initially has current <math>I_0=V_0/R</math> flowing through it; we replace the voltage source with a short circuit at <math>t=0</math>.
 [[Image:RL_discharge_schematic.jpg]]
@@ Line 57: / Line 57: @@
 ===Charging===
-If the inductor is initially uncharged and we want to charge it by inserting a voltage source <math>V_s</math> in the RL cicuit:
+If the inductor is initially uncharged and we want to charge it by inserting a voltage source <math>V_s</math> in the RL circuit:
 [[Image:RL_charge_schematic.jpg]]

Difference between revisions of "RC and RL Exponential Responses"

Revision as of 20:03, 15 June 2006

Contents

Summary of Equations

RC Circuits

Discharging

Charging

RL Circuits

Discharging

Charging

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