Post on 21-Jul-2020
Prof. David R. JacksonDept. of ECE
Spring 2020
Notes 27DC Currents
ECE 3318 Applied Electricity and Magnetism
1
KCL Law
10
0
N
nn
totin
i
i
=
=
=
∑or
Wires meet at a “node”
2
Note:The “node” can be a single
point or a larger region.
A proof of the KCL law is given next.
1i
2i
3i4i
Ni
KCL Law (cont.)
totin
dvi Cdt
=
C is the stray capacitance between the “node” and ground.
A = surface area of the “node.”
3
A single node is considered.
The node forms the top plate of a stray capacitor.Ground
Q+
( )v t
C
A
+
-
KCL Law (cont.)
1) In “steady state” (no time change)
2) As area of node A → 0
0
0totin
dvdti
=
=
0 00tot
in
A Ci→ ⇒ →
=
totin
dvi Cdt
=
Two cases for which the KCL law is valid:
4
KCL Law (cont.)In general, the KCL law will be accurate if the size of the
“node” is small compared with the wavelength λ0.
8
02.99792458 10c
f fλ ×
= =
f λ0
60 Hz 5000 [km]1 kHz 300 [km]1 MHz 300 [m]1 GHz 30 [cm]
5
Node
Currents enter a node at some frequency f.
KCL Law (cont.)
6
Example where the KCL is not valid
Open-circuited transmission line (ECE 3317)
( ) ( )sinI z A kz=
( )2 /k ω µε π λ λ= = = wavelength on line
2 fω π=
(phasor domain)
+-
+-
( )I z
( )I z
( )V z0Z
gZ
z
KCL Law (cont.)
7
Open-circuited transmission line
Current enters this shaded region (“node”) but does not leave.
+-
+-
( )I z
( )V z0Z
gZ
z
General volume (3D) form of KCL equation:
ˆ 0outS
J n dS i⋅ = =∫(valid for D.C. currents)
8
KCL Law (cont.)
The total current flowing out (or in) must be zero: whatever flows in must flow out.
nJ
S
KCL Law (Differential Form)
To obtain the differential form of the KCL law for static (D.C.) currents, start with the definition of divergence:
0J∇⋅ =
0
1 ˆlimV
S
J J n dSV∆ →
∆
∇ ⋅ ≡ ⋅∆ ∫
ˆ 0outS
J n dS i∆
⋅ = =∫
J
∆V
(valid for D.C. currents)
For the right-hand side:Hence
9
Important Current Formulas
Ohm’s Law
J Eσ=
Charge-Current Formula
vJ vρ=
(This is an experimental law that was introduced earlier in the semester.)
(This was derived earlier in the semester.)
These two formulas hold in general (not only at DC):
10
Resistor Formula
0
0
x
x x
x
VEL
VJ EL
VI J A AL
σ σ
σ
=
= = = =
Solve for V from the last equation:
[ ]LRAσ
= Ω
VRI
=
Hence we have
We also have that
A long narrow resistor: 0ˆ xE x E≈ Note:The electric field is constant (does not change with x)
since the current must be uniform (KCL law).
LV IAσ
=
11
σ
L
A
I
x
V
J
+ -
Joule’s Law
12
Conducting body
J Eσ=E
σ
[ ]2
2Wd
V V V
JP J E dV E dV dVσ
σ= ⋅ = =∫ ∫ ∫
The power dissipated inside the body as heat is:
(Please see one of the appendices for a derivation.)
Power Dissipation by Resistor
d x xP J E VI V VA L
IV
= ∆
= ∆
= 2d
d
P VIP RI
=
=
Hence
Note: The passive sign convention applies to the VI formula.13
ResistorPassive sign convention labeling
V AL∆ =
-
σ
+
LAI
V
x
Assume a uniform current.
RC Analogy
Goal:Assuming we know how to solve the C problem (i.e., find C), can we solve the R problem (find R)?
“C problem” “R problem”
14
( ) ( )r F rε =
A
+ -VAB
B EC
Insulating material
( ) ( )r F rσ =
A
-VAB
B ER
I
+
Conducting material
(same conductors)
C Gε σ→→
RC Analogy
Recipe for calculating resistance:
1) Calculate the capacitance of the corresponding C problem.
2) Replace ε everywhere with σ to obtain G.
3) Take the reciprocal to obtain R.
In symbolic form:
15
(Please see one of the appendices for a derivation.)
This is a special case: A homogeneous medium of conductivity σsurrounds the two conductors (there is only one value of σ).
RC Formula
RC εσ =
16
σ = conductivity in resistor problemε = permittivity in capacitor problem
The resistance R of the resistor problem is related to the capacitance Cof the capacitor problem as follows:
(Please see one of the appendices for a derivation.)
Example
Find R
C problem:
C Gε σ→→
AChε
=
AGhσ
=
Method #1 (RC analogy or “recipe”)
hRAσ
=
AChε
=
17
Hence
σA
h
εA
h
ExampleFind R
C problem:
AChε
=
Method #2 (RC formula)
RC εσ =
hRAσ
=AR
hε ε
σ =
18
σA
h
εA
h
Example
Find the resistance
Note:We cannot use the RC formula, since there is more than one region
(not a single conductivity).
19
A
2h1h1σ
2σ
Example (cont.)
C problem:
1 2
1 1 1C C C= + 1
11
AChε
= 22
2
AChε
=
20
A
2h1h1ε
2ε
Example (cont.)
1 2
1 1 1G G G= + 1 2
1 21 2
A AG Gh hσ σ
= =
C Gε σ→→
21
→
1 2
1 1 1C C C= + 1 2
1 21 2
A AC Ch hε ε
= =
↓ ↓
A
2h1h1σ
2σ
A
2h1h1ε
2ε
1 2R R R= + 11
1
hRAσ
=
Hence, we have
22
2
hRAσ
=
Example (cont.)
22
A
2h1h1σ
2σ
Lossy Capacitor
AChε
=
hRAσ
=
This is modeled by a parallel equivalent circuit (the proof is in one of the appendices).
Note:The time constant is
RCτ =
23
,ε σ+ + + + + + + + + + + + + + + + + +
- - - - - - - - - - - - - - - - - - - - - - - - - -
+
-
2A m
hE J( )v t( )i t
+
-
( )i t
( )v tR
C
Appendix
24
Derivation of Joule’s Law
Joule’s Law
( )
( )
( )
ABB
vA
v
v v
W Q V
V E dr
V E r
rV r E V E tt
ρ
ρ
ρ ρ
∆ = ∆
≈ ∆ ⋅
≈ ∆ ⋅∆
∆ = ∆ ∆ ⋅ = ∆ ⋅ ∆ ∆
∫
∆W = work (energy) given to a small volume of charge as it moves inside the conductor
from point A to point B.This goes to heat!
(There is no acceleration of charges in steady state, as this would cause
current to change along the conductor, violating the KCL law.)
25
Conducting body
ρv = charge density from electrons in conduction band
- -- -
- -- -
J Eσ=
r∆
A Bv
Evρ
V∆
Joule’s Law (cont.)
( )1v
W v Et V
J E
ρ∆ = = ⋅ ∆ ∆ = ⋅
power / volume
[ ]WdV
P J E dV= ⋅∫
We can also write2
2W[ ]d
V V
JP E dV dVσ
σ= =∫ ∫
( )v vrW V E t V v E tt
ρ ρ∆ ∆ = ∆ ⋅ ∆ = ∆ ⋅ ∆ ∆
The total power dissipated is then
26
Appendix
27
Derivation of RC Analogy
RC Analogy
“C problem” “R problem”
28
( ) ( )r F rε =
A
+ -VAB
B EC
Insulating material
( ) ( )r F rσ =
A
-VAB
B ER
I
+
Conducting material
(same conductors)
RC Analogy (cont.)
Theorem: EC = ER (same field in both problems)
“R problem”
29
(same conductors)
“C problem”
( ) ( )r F rε =
+ -
CEA B
ABV
( ) ( )r F rσ =
+ -I
REA B
ABV
“C problem” “R problem”
( )0
0D
Eε∇ ⋅ =
∇ ⋅ = ( )0
0J
Eσ∇⋅ =
∇ ⋅ =
Same differential equation since ε (r) = σ (r) Same B. C. since the same voltage is applied
RC Analogy (cont.)Proof of “theorem”
Hence,
30
(They must be the same function from the uniqueness of thesolution to the differential equation.)
C RE E=
A
A
AB
sSB
A
QQCV V
dS
E dr
ρ
= =
=⋅
∫
∫
“C Problem”
RC Analogy (cont.)
ˆAS
B
A
E n dSC
E dr
ε ⋅
=⋅
∫
∫
Hence
ˆ ˆs D n E nρ ε= ⋅ = ⋅Use
31
( ) ( )r F rε =
+ -
CEA B
ABV
ˆA
AB
AB
A
S
VVRI I
E dr
J n dS
= =
⋅
=⋅
∫
∫
RC Analogy (cont.)
ˆA
B
A
S
E drR
E n dSσ
⋅
=⋅
∫
∫
Hence
“R Problem”
J Eσ=Use
32
( ) ( )r F rσ =
+ -I
REA B
ABV
Hence
( ) ( ) ( )r r F rσ ε= =
C G=
ˆAS
B
A
E n dSC
E dr
ε ⋅
=⋅
∫
∫
ˆ1 AS
B
A
E n dSG
RE dr
σ ⋅
= =⋅
∫
∫
RC Analogy (cont.)
Recall that
33
Compare:
This is a special case: A homogeneous medium of conductivity σsurrounds the two conductors (there is only one value of σ).
RC Formula
ˆASB
A
E n dSC
E drε
⋅
=⋅
∫
∫
ˆAS
B
A
E n dSG
E drσ
⋅
=⋅
∫
∫
G C σε
=
Hence,
RC εσ =
or
34
Appendix
35
Equivalent Circuit for Lossy Capacitor
36
Lossy Capacitor
Therefore,
( ) ( )Ain x
dQi t i t J Adt
= − =
Total (net) current entering top (A) plate:
( ) xdQi t J Adt
= +
Derivation of equivalent circuit
,ε σ+ + + + + + + + + + + + + + + + + +
- - - - - - - - - - - - - - - - - - - - - - - - - -
+
-
2A m
hE J( )v t( )i t
x
37
Lossy Capacitor (cont.)
( ) x
As
x
x
x
dQi t J Adt
dE A AdtdDv A A
h dtdEv A
h dtA
ρσ
σ
ε
σ
= +
= +
= +
= +
( ) xdEvi t Ah dtA
v A dvR h dtv dvCR dt
ε
σε
= +
= +
= +
,ε σ+ + + + + + + + + + + + + + + + + +
- - - - - - - - - - - - - - - - - - - - - - - - - -
+
-
2A m
hE J( )v t( )i t
x
38
Lossy Capacitor (cont.)
( ) ( ) ( )v t dv ti t C
R dt= +
This is the KCL equation for a resistor in parallel with a capacitor.
,ε σ+ + + + + + + + + + + + + + + + + +
- - - - - - - - - - - - - - - - - - - - - - - - - -
+
-
2A m
hE J( )v t( )i t
x
+
-
( )i t
( )v tR
C
39
Lossy Capacitor (cont.)
We can also write the current as
( ) xx
dDi t J A Adt
= +
Conduction current Displacement current
DH Jt
∂∇× = +
∂
Ampere’s law:
Conduction current (density)
Displacement current (density)
,ε σ+ + + + + + + + + + + + + + + + + +
- - - - - - - - - - - - - - - - - - - - - - - - - -
+
-
2A m
hE J( )v t( )i t
x
Note on displacement current: