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Bog'liq
Electric Circuit Analysis by K. S. Suresh Kumar

1.3
The second component of force is the magnetic force and arises out of motion of charges. This
component is given by
F
q q
r
v
v
u
12
0 1 2
2
2
1
12
4
m
=
×
×
(
)
m
p
N
where
m
0
is the magnetic permeability of free space (
=
4
p
×
10
-
7
H/m) and
v
1
and
v
2
are the velocities
of q
1
and q
2
respectively.
The third component of force is the induced electric force and depends on relative acceleration of
q
1
with respect to q
2
. It is given by
F
q q
t
v
r
ei
v
12
0 1 2
1
0
4
2
= −
∂
∂




=
m
p
N.
Electromagnetic disturbances travel with a finite velocity – the velocity of light in the corresponding
medium. Therefore, in general, the force experienced by q
2
at a time instant t depends on the position
and velocity of q
1
at an earlier instant. Or, equivalently, the force that will be experienced by q
2
at
t
+
r/c depends on r and
v
1
at t where c is the velocity of light. This effect is called the retardation
effect. The expressions described above ignore this retardation effect and assume that the changes in
relative position and velocity of q
1
are felt instantaneously at q
2
.
Retardation effect can be ignored if (i) the speed of charges is such that no significant change can
take place in r during the time interval needed for electromagnetic disturbance to cover the distance
and (ii) the acceleration of charges is such that no significant changes in the velocity of charges take
place during the time interval needed for electromagnetic disturbance to cover the distance between
charges. The first condition implies that the speed of charges must be small compared to velocity of
light. This condition is met by almost any circuit since the drift speed associated with current flow
in circuits is usually very small compared to velocity of light. However, though the speed of charge
motion is small, it is quite possible that the charges accelerate and decelerate rapidly in circuits such
that the second condition is not met.
Consider the two point charges in Fig. 1.1-2. q
1
is oscillating with amplitude d and angular
frequency
w
rad/sec. However, let us assume that d
<<
r. Then, neither the distance between the
charges nor the unit vector between them change much with time. Therefore, the electrostatic force
experienced by q
2
is more or less constant in time. q
2
is at rest and hence it does not experience any
magnetic force. However, it will experience a time-varying induced electric force. Let the horizontal
position of q
1
be given by x
=
d sin (
w
t) m. Then, velocity of q
1
is
v
1
=
w
d cos
w
t m/s. The time
taken by any electromagnetic disturbance to travel r meters
is r/c where c is the velocity of light in m/s. The quantity
∂
∂






t
v
r
1

that decides the induced electric force experienced
by q
2
will change by
w
w
w
2
d
r
t r c
t
sin
/
sin
+
(
)
−


in that
time interval. Retardation effect can be ignored only if this
change is negligible – i.e., only if
w
r
c
<<
1.
In the context of circuit theory,
w
is the highest angular
frequency of time-varying signals present in the circuit and
r is the largest physical dimension measured in the physical
circuit. Then, retardation effect due to finite propagation
q
1
q
2
r
v
2
→
= 0
Fig. 1.1-2

Pertainingto
retardationeffectin
atwo-chargesystem
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1.4

CircuitVariablesandCircuitElements
speed of electromagnetic waves can be ignored in the analysis of an electrical system if the highest
frequency present in the circuit and largest dimension of the system satisfy the inequality
w
r
c
<<
1.
An electrical system in which the retardation effect can be ignored is called a quasi-static electrical
system. Electric circuit theory assumes that the electrical system that is modeled by an electrical
circuit is a quasi-static system.

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