Modeling of Electrical Systems

Voltage, Current, Charge Relationship for Capacitor,

Resistor, and Inductor.

Component Symbol V-I Relation I-V Relation

v R (t )
Resistor v R (t )  i R (t )R i R (t ) 
R

1 dvc (t )
Capacitor vc (t )   ic (t )dt ic (t )  C
C dt

diL (t ) 1
Inductor v L (t )  L iL (t )   v L (t )dt
dt L
Voltage, Current, Charge Relationship for Capacitor,
Resistor, and Inductor.
Transform Impedance (Resistor, Inductor & Capacitor)

iR(t) IR(s)
+ +
Transformation
vR(t) ZR = R VR(s)

- -

IL(s)
iL(t) +
+
vL(t) ZL=Ls VL(s)

- -

ic(t) Ic(s)
+ +

vc(t) ZC(s)=1/Cs Vc(s)

- -
 Equivalent Transform Impedance (Series)

• Consider following arrangement, find out equivalent transform

impedance.

ZT  Z R  Z L  Z C
C

1 R
ZT  R  Ls 
Cs
Equivalent Transform Impedance (Parallel)

L
1 1 1 1
  
ZT Z R Z L ZC
C

1 1 1 1
  
ZT R Ls 1 R
Cs
Example: 1

The two-port network shown in the following figure has vi(t) as the
input voltage and vo(t) as the output voltage. Find the transfer
function Vo(s)/Vi(s) of the network.

vi( t) i(t) C vo(t)

 Vi(s) I(s) 1/Cs Vo(s)

1
I ( s )  Vi ( s ) /( R  )
Cs
1
Vo ( s )  I ( s ).
Cs
Vo ( s ) 1
 Vo ( s ) 1
Vi ( s ) 1 
Cs( R  ) Vi ( s ) 1  RCs
Cs
• The system has one pole at
1
1  RCs  0 s
RC
 Example: 2
The two-port network shown in the following figure has ei(t) as the
input voltage and eo(t) as the output voltage. Find the transfer
function Eo(s)/Ei(s) of the network.

Solution: The transfer function, Eo(s)/Ei(s), can be obtain by applying the voltage-divider
rule, hence
 I 2 ( s)
Example-3: Find the transfer function
V ( s)
Example-3 continue

( R1  Ls ) I1 ( s )  Ls I 2 ( s )  V ( s )    (1)
 1 
 Ls I1 ( s )   Ls  R2   I 2 ( s )  0    (2)
 Cs 
Example-3 continue
( R1  Ls ) I1 ( s )  Ls I 2 ( s )  V ( s )    (1)
 1 
 Ls I1 ( s )   Ls  R2   I 2 ( s )  0    (2)
 Cs 
 VC ( s )
Example-4: Find the transfer function
V (s)
Example-4 continue
Example-4 continue

VC ( s )

V (s)
 Vo ( s )
Example-5: Find the transfer function
Vi ( s )
by mesh and nodal method
 Vo ( s )
Example-5: Mesh method
Vi ( s )

(2s  1) I1 ( s )  I 2 ( s )  Vi ( s )    (1)
 2
 I1 ( s )   3s  1   I 2 ( s )  0    (2)
 s
Example-5: Mesh method Continue

(2s  1) I1 ( s )  I 2 ( s )  Vi ( s )    (1)
 2
 I1 ( s )   3s  1   I 2 ( s )  0    (2)
 s

Vo ( s )  I 2 ( s ).3s
Vo ( s ) 3s 2
 3
Vi ( s ) 6s  5s 2  4s  2
Example-5: Nodal method
 Vo ( S )
Example-6: Find the transfer function
Vi ( S )

Solution:
 Vo ( S )
Example-7: Find the transfer function
Vi ( S )
Example-7: Continue
Example-7: Continue
Example-3: Consider the signal flow graph below and
identify the following:

a) Determine the loop gains of the feedback loops.

b) Determine the path gains of the forward paths.
c) Determine the non-touching loop gains.
Example-3: Answers

• There are four loop gains;

• There are two forward path gains;

• Nontouching loop gains;

 Mason’s Rule
• The TRANSFER FUNCTION, C(s)/R(s), of a system represented by a
signal-flow graph is;
n
 Pi  i
C( s ) i 1

R( s ) 
Where

n = number of forward paths.

Pi = the i th forward-path gain.
∆ = Determinant of the system
∆i = Determinant of the ith forward path

• ∆ is called the signal flow graph determinant or characteristic function.

Since ∆=0 is the system characteristic equation.
 Transfer function from signal flow graph can be calculated using
MASON’S GAIN formula
n
 Pi  i
C( s ) i 1

R( s ) 
∆ = 1- (sum of all individual loop gains) + (sum of the products of the gains
of all possible two loops that do not touch each other) – (sum of the
products of the gains of all possible three loops that do not touch each
other) + … and so forth with sums of higher number of non-touching loop
gains
∆i = value of Δ for the part of the signal flow graph that does not
touch the i-th forward path.
Example-4: Construct the signal flow graph of the block diagram of the
canonical feedback control system and find the control ratio C/R.

The characteristic function

Since the loop touch the forward path

Example-5: Determine the control ratio C/R and the canonical
block diagram of the feedback control system.
Example-5:Continue. (finding the control ratio C/R )
Example-5:Continue. (finding the canonical block diagram)
Example-6: Construct the signal flow graph for the
following set of simultaneous equations.

• There are four variables in the equations (i.e., x1,x2,x3,and x4) therefore four nodes are required
to construct the signal flow graph.
• Arrange these four nodes from left to right and connect them with the associated branches.
Example-7: Determine the transfer function C/R for the block diagram below
by signal flow graph techniques.
 Example-7: Continue

• There are two forward paths. The path gains are

• The three feedback loop gains are

• No loops are non-touching, hence

• Because the loops touch the nodes of P1, hence

• Since no loops touch the nodes of P2, therefore

Example-8a: Determine C/R of each of the following
system using the signal flow graph techniques.
Example-8b: Determine C/R of each of the following system using
the signal flow graph techniques.
Example-8c: Determine C/R of each of the following system using
the signal flow graph techniques.
Example-9: Find the transfer function C/R for the system in which k is constant.
Example-9: Solution
Example-10: Find the control ratio C/R for the system given below.
 Example-10: Solution

• The two forward path gains are • There are no non-touching loops, hence

• The five feedback loop gains are

• All feedback loops touches the two forward paths, hence

Example-11: Determine C/R for the system given below using signal flow graph
techniques and then put G3 = G1G2H2.
Example-12: Obtain the transfer function C(s)/R(s), for the signal-flow graph.

No.of forward paths = 1

C ( S ) P11

Forward path gain
R( S ) 
Δ formula terms
Individual loop gains

Two nontouching loop combinations and their gains

Three nontouching loop combinations and their gains

C ( S ) P11
 
R( S ) 
Example-13: Obtain the transfer function C(s)/R(s), for the signal-flow graph.

C ( S ) P11

R( S ) 

P1  G1G2G3G4 ; 1  1
Example-14: Obtain the transfer function C(s)/R(s), for the signal-flow graph.
Example-15: Obtain the transfer function C(s)/R(s), for the signal-flow graph.

C ( S ) P11  P2  2  P3 3
No.of forward paths = 3 
R( S ) 