1	Chapter 14 Inductive Transients
2	Transients Voltages and currents during a transitional interval Referred to as transient behavior of the circuit Capacitive circuit Voltages and currents undergo transitional phase Capacitor charges and discharges
3	Transients Inductive circuit Transitional phase occurs as the magnetic field builds and collapses
4	Voltage Across an Inductor Induced voltage across an inductor is proportional to rate of change of current
5	Voltage Across an Inductor If inductor current could change instantaneously Its rate of change would be infinite Would cause infinite voltage
6	Continuity of Current Infinite voltage is not possible Inductor current cannot change instantaneously It cannot jump from one value to another, but must be continuous at all times Use observation when analyzing circuits
7	Circuit and Waveforms for Current Build-up
8	Inductor Voltage Immediately after closing the switch on an RL circuit Current is zero Voltage across the resistor is zero
9	Inductor Voltage Voltage across resistor is zero Voltage across inductor is source voltage Inductor voltage will then exponentially decay to zero
10	Open-Circuit Equivalent After switch is closed Inductor has voltage across it and no current through it Inductor with zero initial current looks like an open circuit at instant of switching
11	Open-Circuit Equivalent This statement will later be applied to include inductors with nonzero initial currents
12	Initial Condition Circuits Voltages and currents in circuits immediately after switching Determined from the open-circuit equivalent
13	Initial Condition Circuits By replacing inductors with opens We get initial condition circuit Initial condition networks Yield voltages and currents only at switching
14	Circuit Current Current in an RL circuit is an exponentially increasing function of time Current begins at zero and rises to a maximum value
15	Circuit Voltages Voltage across resistor is given by i•R Voltage across resistor is an increasing function as well (because the inductor current is passing through it)
16	Circuit Voltages By KVL,voltage across inductor is E – v_R Voltage across inductor is an exponentially decreasing function of time
17	Time Constant t = L/R Units are seconds Equations may now be written as
18	Time Constant The larger the inductance The longer the transient The larger the resistance The shorter the transient
19	Time Constant As R increases Circuit looks more and more resistive If R is much greater than L Circuit looks purely resistive
20	Interrupting Current in an Inductive Circuit When switch opens in an RL circuit Energy is released in a short time This may create a large voltage Induced voltage is called an inductive kick Opening of inductive circuit may cause voltage spikes of thousands of volts
21	Interrupting a Circuit Switch flashovers are generally undesirable They can be controlled with proper engineering design These large voltages can be useful Such as in automotive ignition systems
22	Interrupting a Circuit It is not possible to completely analyze such a circuit Resistance across the arc changes as the switch opens
23	Interrupting a Circuit In circuit shown, we see changes after switch opens:
24	Inductor Equivalent at Switching Current through an inductor Same after switching as before switching An inductance with an initial current Looks like a current source at instant of switching Its value is value of current at switching
25	De-energizing Transients If an inductor has an initial current I₀, equation for current becomes t ' = L/R. R equals total resistance in discharge path
26	De-energizing Transients Voltage across inductor goes to zero as circuit de-energizes
27	De-energizing Circuits Voltage across any resistor is product of current and that resistor Voltage across each of resistors goes to zero
28	More Complex Circuits For complex circuits Like capacitive circuits Necessary to determine Thévenin equivalent circuit using inductor as the load
29	More Complex Circuits R_Th is used to determine time constant t = L/R_Th E_Th is used as source voltage