Design for Electromagnetic Compatibility (EMC) - ECE
455/655
Benjamin D. Braaten
North Dakota State University
Department of Electrical and Computer Engineering
Fargo, ND, USA.
Last updated: 1/28/2014
1
TABLE OF CONTENTS
CHAPTER 1. INTRODUCTION TO ELECROMAGNETIC COMPATIBILITY (EMC) 6
1.1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
1.2. Review of Decibel (dB) and Phasors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
1.2.1. Decibels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
1.2.2. Phasors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
1.2.3. Example 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
1.2.4. Example 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
1.2.5. Measurements using decibels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
1.3. Capacitance and Inductance of Certain Structures . . . . . . . . . . . . . . . . . . . . . . . . 11
1.3.1. Parallel plate capacitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
1.3.2. Two parallel wires . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
1.3.3. Coaxial-cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
1.3.4. Mutual inductance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
1.3.5. Example 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
1.3.6. Internal inductance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
CHAPTER 2. TRANSMISSION LINES AND COUPLING . . . . . . . . . . . . . . . . . . . . . . . . . 16
2.1. Lossless Propagation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
2.1.1. Wave velocity and characteristic impedance . . . . . . . . . . . . . . . . . . . . . . 18
2.1.2. Phase constant, phase velocity and wavelength . . . . . . . . . . . . . . . . . . . . 19
2.1.3. Voltage and current along the transmission line . . . . . . . . . . . . . . . . . . . 20
2.2. Examples: Transmission Lines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
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2.2.1. Example 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
2.2.2. Example 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
2.3. Wave Reflections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
2.3.1. Reflection coefficient and transmission coefficient . . . . . . . . . . . . . . . . . . 24
2.3.2. Reflected power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
2.4. Coupling Between Transmission Lines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
2.4.1. General Problem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
2.4.2. Capacitive coupling (low frequencies) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
2.4.3. Inductive coupling (low frequencies) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
2.4.4. Equations for both inductive and capacitive coupling . . . . . . . . . . . . . . 31
2.5. Shielding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
2.5.1. Reducing capacitive coupling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
2.5.2. Reducing inductive coupling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
2.5.3. Summary of transmission line coupling equations . . . . . . . . . . . . . . . . . . 38
2.6. Twisted pair . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
2.6.1. Inductive coupling - unbalanced . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
2.6.2. Capacitive coupling - unbalanced . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
2.6.3. Balanced case . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
CHAPTER 3. DESIGNING FOR EMC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
3.1. Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
3.1.1. Conductors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
3.1.2. Skin depth . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
3.1.3. AC parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
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3.1.4. Non-ideal capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
3.1.5. Non-ideal resistors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
3.1.6. Non-ideal inductors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
3.2. Ferrite Beads . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
3.3. Grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
3.3.1. 3-types of (signal) ground systems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
3.3.2. EMC grounding philosophy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
3.3.3. Examples of cable grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
3.3.4. The 2-types of current in EMC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
3.3.5. Common-mode choke . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
3.3.6. Balanced circuits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
3.4. Filtering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
3.4.1. Introduction to insertion loss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
3.4.2. Insertion loss example of a capacitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
3.4.3. Differential- and common-mode filters . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
3.4.4. Designing maximally flat Butterworth filters . . . . . . . . . . . . . . . . . . . . . . 60
3.4.5. Low-pass filter design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60
3.4.6. LP Butterworth filter example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
3.4.7. High-pass filter design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
3.4.8. HP Butterworth filter example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
3.4.9. Band-pass filter design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
3.4.10. BP Butterworth filter example one . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
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3.4.11. BP Butterworth filter example two . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
3.4.12. Band-stop filter design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
CHAPTER 4. DIGITAL CIRCUITS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
4.1. Noise . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
4.2. Decoupling Capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
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CHAPTER 1. INTRODUCTION TO ELECROMAGNETIC
COMPATIBILITY (EMC)
1.1. Introduction
Electromagnetic Compatibility (EMC) is the study of how electrical devices interact electromagnet-
ically. When a unit under test (UUT) is susceptible to other devices radiating in the region we call
this electromagnetic interference (EMI). When a UUT is radiating significantly into the surrounding
region, we call this radiated emissions (i.e., the UUT is the source of the noise). Overall EMC has
two major aspects (Fig. 1):
1) Emissions (source of noise)
-radiated
-conducted
2) Susceptibility
-radiated
-conducted
UUT
(EUT)
Unit Under Test
(Equipment Under Test)
Radiated emissions
Radiated susceptibility
Cable
Conducted susceptibility
Conducted emissions
Table
Figure 1. Diagram of UUT.
A definition of EMC (Henry Ott): “The ability of an electronic system to 1) functions properly
in its intended EM environment; and 2) not be a source of pollution to that environment.
For EMI to exist we must have the system illustrated in Fig. 2. When considering the channel
coupling we have the following types of coupling:
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1) Radiation
-capacitive coupling (E-field dominant).
-inductive coupling (H-field dominant).
-EM radiation.
2) Common impedance coupling
-currents from two circuits flow through the same impedance.
3) Conductively coupled noise
-noise is conductively coupled from a “noisy” to a “quiet” environment.
Noise
source
Coupling
channel“Victim”
Figure 2. Diagram of EMI.
1.2. Review of Decibel (dB) and Phasors
1.2.1. Decibels
In this section we review the use of decibels. The number of decibels is the logarithmic ratio
of the powers of interest or:
Power = 10 log
(P2
P1
). (1.1)
The units of the ratio are (2.1) is dB and referred to as decibels. Equation (2.1) can be used to
express the power gain of a circuit. For example, if P1 = 10W and P2 = 5W in Fig. 3 then the
power gain = 10 log(P2/P1) = −3.01dB.
Z1
I1
V1
+
-
V2
+
-
Z2
I2
Figure 3. Equivalent circuit.
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1.2.2. Phasors
Now we switch our focus to phasors. In this course we use the following notation:
V (z, t) = Re
[V ejωt
]= |Vm|∠ϕ = V = phasor voltage (1.2)
where V (z, t) represents the voltage in the time domain and V represents the voltage in the frequency
domain. For example, if V = 3∠30 = 3ej30 then V (z, t) = Re
[3ejωtej30
]= 3 cos(ωt+ 30).
Next, if V1 and I1 are rms quantities,
P1 = Re
[V1I1
∗]
= Re
[(I1Z1)(I1
∗)
]= Re
[|I1|2(R1 + jX1)
]= |I1|2R1
=|V1|2
R1
.
Now let V1 = |V1| and I1 = |I1|. This then gives
10 log
(P2
P1
)= 10 log
(V 22
V 21
R1
R2
)= 10 log
(V 22
V 21
)+ 10 log
(R1
R2
)= 20 log
(V2
V1
)+ 10 log
(R1
R2
).
Therefore,
10 log
(P2
P1
)= 20 log
(V2
V1
)(1.3)
only when R1 = R2. Next, we define dBm in the following manner:
P (dBm) = 10 log
(P
1mW
). (1.4)
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The values written in terms of dBm simply mean that the power value of interest is referenced to
1 mW. ⇒ P = (10P (dBm)/10)1mW .
1.2.3. Example 1
Suppose I measure 20 dB of power across 50 Ω. When just dB is written, that means that the
power is being referenced to 1 W. ⇒ 20dB = 10 log(P/1W ) ⇒ P = 102 = 100W . Next, what is 25
mW written in (a) dBm, (b) dB and (c) dBµW?
(a) 10 log(25× 10−3/1× 10−3) = 13.98dBm
(b) 10 log(25× 10−3/1) = 10 log(25) + 10 log(10−3) = −16.02dB
(c) 10 log(25× 10−3/1× 10−6) = 13.98 + 30 = 43.98dBµW
1.2.4. Example 2
Next, as another example, express 20 dB of power dissipated by a 50 Ω resistor in terms of
dBV, dBµV, dBA and dBmA.
20dB = 10 log(P/1W ) ⇒ P = 100W . If we assume rms values of voltage and current,
P = V 2/R = I2R. ⇒ V = 70.71V and I = 1.414A. Therefore,
20 log
(70.71V
1V
)= 37dBV
20 log
(70.71V
1µV
)= 157dBµV
20 log
(1.414A
1A
)= 3dBA
20 log
(1.414A
1mA
)= 63dBmA.
1.2.5. Measurements using decibels
In this section we consider the problem described in Fig. 4. In Fig. 4 a device is radiating into
the surrounding space. A biconical antenna is used to measure the frequency and magnitude of the
radiated field. To convert the measured value into the magnitude of the electric field we introduce
the Antenna Factor (AF) and it is related to the electric field in the following manner:
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AF =Einc
Vr
(1.5)
where Einc is the field radiated by the device and Vr is the voltage at the output terminals of the
antenna.
Radiating device
Biconical antenna
VrMeasured with
spectrum analyzer
E/H-field
Figure 4. Using a biconical antenna to measure the radiated fields from a device.
An alternate representation of the AF is the following:
Einc
1× 10−6= AF
[Vr
1× 10−6
]. (1.6)
Taking 20 log() of (2.6) results in the following expression:
Einc(dBµV/m) = AF (dB) + Vr(dBµV ). (1.7)
Then, if the input impedance of the spectrum analyzer is 50Ω,
Vr(dBµV ) = P (dBm) + 107. (1.8)
If we need to add the cable loss then
Einc(dBµV/m) = P (dBm) + 107 + C.L.(dB) + AF (dB) (1.9)
where C.L. is the cable loss in decibels. Note that the expression in (2.9) is at each frequency.
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1.3. Capacitance and Inductance of Certain Structures
From applied electromagnetics we know C = QV
where C is the capacitance, Q is the total
charge and V is the potential between the conductors of interest (Fig. 5). Using this expression we
can derive the equivalent capacitance between conductors of certain common structures. There are
three ways to determine C:
1) Assume ±Q on the conductors and determine V = −∫E · dl.
2) Assume V between the conductors and determine Q (maybe solve ∇2V = 0 for V (z) then
E = −∇V and Q =∮Dds).
3) Compute the energy stored in the structure by using WE = ε/2∫ ∫ ∫
|E|2dV = 1/2CV 2 ⇒
C = 2WE/V2.
+Q -Q
Conductors
V
Figure 5. Definition of the capacitance between two conductors.
1.3.1. Parallel plate capacitor
For the first structure, we consider the two large parallel plates shown in Fig. 6. Us-
ing method 1) (Fig. 7) we assume ±Q on the top and bottom plates. ⇒ V0 = −∫Edl =
−∫ d
0(ρs/ε0)(−az)(dzaz) = ρsd/ε0 = Qd/(Sε0). ⇒ C = ε0S/d.
Next, using method 2) (Fig. 8) we have ∇2V = 0 + 0 + ∂2V/∂z2 = 0. ⇒ ∂2V/∂z2 = 0.
Assuming a solution of V (z) = Az+B and applying the B.C. of B = 0 and A = V0/d gives V (z) =
V0z/d. Next, using E = −∇V = −∂V/∂zaz = (−V0/d)(az). From the boundary conditions at
z = d we get Dn = ρs ⇒ ε0En = ρs. ⇒ ε0V0/d = ρs ⇒ Q = ρsS = Sε0V0/d. ⇒ C = Q/V0 = ε0S/d.
1.3.2. Two parallel wires
Next, it can be shown that the capacitance per unit length of the two-wire TL shown in Fig.
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Large plate with area S
d (very small distance)
µ0, ε0
Free space
z
x
y
Figure 6. Parallel plate capacitors.
+Q = (+ρs)(S)
+
-
Vd
Ez = (ρs/ε0)z
-Q = (-ρs)(S)
Surface charge density
Figure 7. Charge distribution on the parallel plate capacitors.
9 is C ≈ πε/ ln(d/a) (F/m) where ε is the permittivity of the homogenious material containing
the wires and d is the separation between the center of the conductors. Similarly, for the single
conductor in Fig. 9 b), if h >> a then C ≈ 2πε/ ln(2h/a) (F/m).
1.3.3. Coaxial-cable
Next, we calculate the self inductance of the coaxial-cable TL shown in Fig. 10. The magnetic
field can be written as H = I/2πρaϕ for ρ > a and assuming the wire is along the z-axis. ⇒
L = Ψ/I. Assuming a constant current, the magnetic flux Ψ can be written as Ψ =∫ ∫
Bds =∫ 1
0
∫ b
a(µI/2πρ)(aϕ)dρdzaϕ = (µI/2π) ln(b/a). ⇒ L = (µ/2π) ln(b/a).
1.3.4. Mutual inductance
Inductance is defined to be the (ratio of the magnetic flux linked)/(the current creating the
flux). Thus, self inductance deals with the flux that links the current that created it and mutual
inductance deals with the flux that one current creates that links a second current (Fig. 11). From
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d
V = V0 at z = d
V = 0 at z = 0
ρv = 0
z
Figure 8. Potential between the plates.
d
radius r = a
ground plane
radius r = a
h
a) b)
Figure 9. a) Two parallel conductors; b) A single conductor above a ground plane.
this we can write the self-inductance as
L =NΨ
I(1.10)
and the mutual inductance as
M12 =N2Ψ12
I1(1.11)
where Ψ is the flux linking each of the turns, Ψ12 is the flux created by I1 that links each of the N2
turns and I1 is the current creating the flux.
1.3.5. Example 3
In this example we want to calculate the mutual inductance between the structures shown in
Fig. 12. If we assume that a constant current is flowing in the z-direction along the wire, then
we can write the magnetic field as H = I/(2πρ)aϕ (in cylindrical coordinates). Next we need to
13
ba
IH
Two conducting cylinders
I
Current
returns on
the shield
dielectric
(σ,ε,µ0µr)
z
Figure 10. A coaxial-TL.
I1 I2
Figure 11. Mutual inductance.
compute Ψ12 in (2.10) in the following manner:
Ψ12 =
∫ ∫B · ds =
∫ 5
0
∫ 5
3
(µ0I12πρ
aϕ
)(dρdzaϕ) =
[µ0I12π
ln
(5
3
)]5.
⇒ M12 = 5.1µH. In this case M12 = M21.
1.3.6. Internal inductance
Finally, the internal inductance of a wire (Fig. 13) can be written as Linternal = µ0/8π for a
solid wire.
14
I2
I1
2 m
5 m
3 m
z
Figure 12. Mutual inductance between a loop and a wire.
I
Solid wire
Figure 13. Internal inductance of a solid wire.
15
CHAPTER 2. TRANSMISSION LINES AND COUPLING
Next, consider the per-unit equivalent (lumped element model) circuit of a short TL shown
in Fig. 14. R represents the conductor loss, L represents the line inductance, C represents the line
capacitance and G represents the loss in the dielectric between the conductors. Now we want to
derive expressions for V (z) and I(z) on the TL shown in Fig. 14 in terms of R, L, C and G.
I
∆z
1/2L∆z 1/2L∆z 1/2R∆z1/2R∆z
G∆zC∆z
KCL
KVLG∆zC∆z KVLV
+
-
V+∆V
+
-
I+∆IIc IG
Figure 14. Per-unit equivalent circuit of a TL.
First, using KVL on the circuit shown in Fig. 14:
V =1
2R∆zI +
1
2L∆z
∂I
∂t+
1
2L∆z
∂
∂t(I +∆I) +
1
2R∆z(I +∆I) + V +∆V. (2.1)
⇒V
∆z=
1
2RI +
1
2L∂I
∂t+
1
2L
(∂I
∂t+
∂∆I
∂t
)+
1
2R(I +∆I) +
V
∆z+
∆V
∆z. (2.2)
⇒∆V
∆z= −RI − L
∂I
∂t− 1
2R∆I − 1
2L∂∆I
∂t. (2.3)
Next, evaluating the limit ∆z → 0 (i.e., lim∆z→0) we have I + ∆I → I, ∆I → 0 and ∆V∆z
→ ∂V∂z.
This then reduces 2.3 to the following:
∂V
∂z= −
(RI + L
∂I
∂t
). (2.4)
16
Next, using KCL on the circuit shown in Fig. 14:
I = IG + IC + I +∆I
= G∆z
(V +
∆V
2
)+ C∆z
∂
∂t
(V +
∆V
2
)+ I +∆I. (2.5)
⇒I
∆z= G
(V +
∆V
2
)+ C
∂
∂t
(V +
∆V
2
)+
I
∆z+
∆I
∆z. (2.6)
⇒∆I
∆z= −G
(V +
∆V
2
)− C
∂
∂t
(V +
∆V
2
). (2.7)
Next, evaluating the limit ∆z → 0 (i.e., lim∆z→0) we have V + ∆V → V , ∆V → 0 and ∆I∆z
→ ∂I∂z.
This then reduces 2.7 to the following:
∂I
∂z= −
(GV + C
∂V
∂t
). (2.8)
Equations 2.4 and 2.8 are referred to as the telegraphist’s equations. Their solutions lead to the
wave equations on the TL. Next, differentiating (2.4) w.r.t. z and (2.8) w.r.t. t we get:
∂2V
∂z2= −R
∂I
∂z− L
∂2I
∂t∂z(2.9)
and
∂2I
∂z∂t= −G
∂V
∂t− C
∂2V
∂t2. (2.10)
Next, substituting (2.8) and (2.10) into (2.9) gives
∂2V
∂z2= LC
∂2V
∂t2+ (LG+RC)
∂V
∂t+RGV. (2.11)
17
Similar substitutions result in the following expression:
∂2I
∂z2= LC
∂2I
∂t2+ (LG+RC)
∂I
∂t+RGI. (2.12)
Equations (2.11) and (2.12) represent the general wave equations for the TL in Fig. 14.
2.1. Lossless Propagation
2.1.1. Wave velocity and characteristic impedance
For lossless propagation we have R = G = 0 in Fig. 14. This then simplifies (2.11) and (2.12)
to the following:
∂2V
∂z2= LC
∂2V
∂t2(2.13)
and
∂2I
∂z2= LC
∂2I
∂t2. (2.14)
Solving the second order partial differential equations in (2.13) and (2.14) results in the following
assumed solutions:
V (z, t) = f1(t− z/ν) + f2(t+ z/ν) = V + + V − (2.15)
where ν represents the wave velocity, V + represents the forward traveling wave and V − represents
the backward traveling wave or reflected wave. The t− z/ν represents the forward traveling wave.
As t increases, z must also increase to sustain f(0) (the wave front). To solve for the wave velocity
we consider the solution of V (z, t) to ∂2V∂z2
= LC ∂2V∂t2
. With out loss of generality we consider only
f1.
⇒∂V (z, t)
∂z=
∂f1∂z
=∂f1
∂(t− z/ν)
∂(t− z/ν)
∂z=
−1
vf
′
1 (2.16)
where f′1 is the partial derivative w.r.t. the argument. Similarly we have
∂V (z, t)
∂t=
∂f1∂t
=∂f1
∂(t− z/ν)
∂(t− z/ν)
∂t= f
′
1, (2.17)
18
∂2f1∂z2
=1
ν2f
′′
1 (2.18)
and
∂2f1∂t2
= f′′
1 . (2.19)
Notice that (2.18) and (2.19) are simply derivatives of f1 w.r.t. z and t, respectively. Substituting
(2.18) and (2.19) into (2.13) results in the following expression:
∂2V
∂z2=
1
ν2f
′′
1 = LCf′′
1 = LC∂2V
∂t2(2.20)
or
1
ν2f
′′
1 = LCf′′
1 . (2.21)
Canceling f′′1 results in the following expression for the wave velocity ν:
ν =1√LC
. (2.22)
Similarly for (2.14) we have the following solution:
I(z, t) =1
Lν
[f1(t− z/ν)− f2(t+ z/ν)
]= I+ + I− =
1
Z0
V (z, t) (2.23)
where
Z0 =
√L
C. (2.24)
Z0 is referred to as the characteristic impedance of the TL. Notice the expressions for the wave
velocity and characteristic impedance are written entirely in terms of L and C. This indicates
that ν and Z0 are dependent only on the dimensions of the physical structure and not time and
frequency.
2.1.2. Phase constant, phase velocity and wavelength
In this section we derive the expressions for the voltage and current along the TL when a
19
steady-state sinusoidal source is used to drive the TL. Start by defining f1 = f2 = V0 cos(ωt + ϕ).
From the previous section we have t = t± z/νp where νp is referred to as the phase velocity.
⇒
V (z, t) = |V0| cos[ω(t+ z/νp) + ϕ]
= |V0| cos[ωt± βz + ϕ]. (2.25)
⇒
V + = Vf (z, t) = |V0| cos[ωt+ βz + ϕ] (2.26)
and
V − = Vb(z, t) = |V0| cos[ωt− βz + ϕ] (2.27)
where
β =ω
νp. (2.28)
β is called the phase constant of the TL. If t = 0 (i.e., fix time and look at the spatial variation)
then we have Vf (z, 0) = |V0| cos[βz]. Vf (z, 0) represents a periodic function that repeats w.r.t. a
value of z. Denote this value as λ and call it the wavelength of the wave. This then gives βλ = 2π.
⇒
λ =2π
β=
νpf. (2.29)
Now, if z = 0 (fix position and look at time variation) then we have V (0, t) = |V0| cos[ωt]. This is
illustrated in Fig. 15. Notice that the sinusoid repeats every 2π.
⇒
T =1
f(2.30)
where T is the period of the sinusoid.
2.1.3. Voltage and current along the transmission line
Here we want to represent the voltage along the TL as complex functions. Using Euler’s
20
2πωt
V0+
V(0,t)
Figure 15. Sinusoidal voltage along the TL.
identity we have e±jx = cos(x)± j sin(x).
⇒
cos(x) = Re
[e±jx
]=
1
2
[ejx + e−jx
](2.31)
and
sin(x) = ±Im
[e±jx
]= ± 1
2j
[ejx − e−jx
](2.32)
⇒
V (z, t) = |V0| cos[ωt± βz + ϕ]
=1
2|V0|[ej(ωt±βz+ϕ) + e−j(ωt±βz+ϕ)
]=
1
2|V0|[ejϕ + e−jϕ
][ej(ωt±βz) + e−j(ωt±βz)
]= V0
[ej(ωt±βz) + e−j(ωt±βz)
]. (2.33)
Note that V0 was used to represent the complex voltage magnitude 12|V0|[ejϕ + e−jϕ
]in (2.33).
Next, define the following
Vc(z, t) = V0e±jβzejωt (2.34)
and
Vs(z) = V0e±jβz (2.35)
where Vc(z, t) is the complex instantaneous voltage and Vs(z) is the phasor voltage. Again, from
21
the general wave equation (2.11) we have
∂2V
∂z2= LC
∂2V
∂t2+ (LG+RC)
∂V
∂t+RGV. (2.36)
In the phasor domain we also have the relation ∂∂t
⇔ jω.
⇒d2Vs
dz2= −ω2LCVs + jω(LG+RC)Vs +RGVs. (2.37)
⇒d2Vs
dz2= (R + jωL)(G+ jωC)Vs = γ2Vs (2.38)
where γ =√(R + jωL)(G+ jωC) = α + jβ is the propagation constant along the TL. Now
assume that Vs(z) = V +0 e−γz + V −
0 e+γz for a solution to d2Vs
dz2= γ2Vs. Similarly, assume Is(z) =
I+0 e−γz + I−0 e
+γz. Substituting the assumed voltage and current solutions into the transformed
expressions of (2.4) and (2.8) gives the following expressions:
dVs
dz= −(R + jωL)Is (2.39)
and
dIsdz
= −(G+ jωC)Vs. (2.40)
⇒ −γV +0 e−γz + γV −
0 e+γz = −Z
[I+0 e
−γz + I+0 eγz
]where Z0 = R + jωL. Equating the coefficients
of e−γz and eγz gives −γV +0 = −ZI+0 and γV −
0 = −ZI−0 . Therefore, the characteristic impedance
22
Z0 is
Z0 =V +0
I+0
= −V −0
I−0
=Z
γ
=Z√ZY
=
√Z
Y(2.41)
where Y = G+ jωC.
⇒
Z0 =
√R + jωL
G+ jωC= |Z0|ejθ. (2.42)
2.2. Examples: Transmission Lines
2.2.1. Example 1
Consider an 80 cm long lossless TL with a source connected to one end operating at 600 MHz.
The lumped element values of the TL are L = 0.25µH/m and C = 100pF/m. Find Z0, β and νp.
Solution: Using (2.42) we have
Z0 =
√R + jωL
G+ jωC=
√0 + jω.25× 10−6
0 + jω100× 10−12= 50Ω.
Also from (2.38) we have γ =√
(R + jωL)(G+ jωC) =√(0 + jωL)(0 + jωC) = 0+jβ = jω
√LC.
⇒ β = 2π(600× 106)√LC = 18.85rad/m. Finally, we have νp = ω/β = 2× 108m/s.
2.2.2. Example 2
A transmission line constructed of two parallel wires in air has a conductance of G = 0Ω. The
two parallel wires are made of good conductors, therefore it is assumed that R = 0Ω. If Z0 = 50Ω,
β = 20 rad/m and f = 700 MHz, find the per-unit inductance and capacitance of the TL.
Solution:
23
Since R = G = 0, β = ω√LC = 40 = 2π700MHz
√LC and Z0 =
√LC= 50. Then the ratio
of β and Z0 results in the following:
β
Z0
= ωC.
Solving for C then gives:
C =β
ωZ0
=20
2π ∗ 700MHz ∗ 50= 90.9pF/m.
Finally, solving for L gives:
L = Z20C
= 502 ∗ 90.9× 10−12
= 227nH/m.
2.3. Wave Reflections
2.3.1. Reflection coefficient and transmission coefficient
Next, expressions for describing the reflections of wave along the TL are derived. To do this,
consider the TL load in Fig. 16. Next, denote
Vi(z) = V0ie−αze−jβz (2.43)
and
Vr(z) = V0re+αze+jβz. (2.44)
⇒
VL(0) = Vi(0) + Vr(0) = V0i + V0r (2.45)
24
and
IL(0) = I0i + I0r =1
Z0
[V0i − V0r]. (2.46)
Now define the reflection coefficient at the load as
Γ =V0r
V0i
=ZL − Z0
ZL + Z0
= |Γ|ejϕΓ . (2.47)
Now using Γ we can write the voltage at the load in terms of the reflection coefficient and the
incident wave in the following manner:
VL = V0i + ΓV0i. (2.48)
ZL=RL+jXL
z = 0
Vi(z)
Vr(z)
Z0
VL
+
-
Figure 16. Voltage reflection at the load of a TL.
Now define the transmission coefficient as
τ =VL
V0i
= 1 + Γ =2ZL
Z0 + ZL
= |τ |ejϕt . (2.49)
2.3.2. Reflected power
The time averaged power can be written as
< P >=1
2Re(VsI
∗s ) =
1
2Re
(V0e
−αze−jβz V ∗0
|Z0|ejθe−αze+jβz
)=
1
2
|V0|2
|Z0|e−2αz cos θ. (2.50)
Note that θ in (2.50) refers to the angle on the characteristic impedance Z0. Then for z = L we
25
have the following expression for the incident power:
< Pi >=1
2
|V0|2
|Z0|e−2αL cos θ. (2.51)
Then, to find the reflected power at the load substitute in the reflected wave in (2.48):
< Pr > =1
2Re
(ΓV0e
−αLe−jβL (ΓV0)∗
Z0ejθe−αLejβL
)=
1
2
|Γ|2|V0|2
|Z0|e−2αL cos θ. (2.52)
This then leads to the following expression for the reflected power
< Pr >
< Pi >= ΓΓ∗ = |Γ|2. (2.53)
Similarly, for the transmitted power :
< Pt >
< Pi >= 1− |Γ|2. (2.54)
2.4. Coupling Between Transmission Lines
2.4.1. General Problem
To investigate the coupling between two TLs we start with the general problem defined in
Fig. 17. The problem insists of two parallel TLs above a common ground plane. The TL with
the source is called the generator conductor and the TL with the two resistive loads is called the
receptor conductor. Rs is the source resistance, RL is the load resistance, RNE is the near-end load
on the receptor conductor and RFE is the far-end load on the receptor conductor. The receptor
conductor has a length L.
Next, we can derive an equivalent circuit of the coupled TLs. By looking at one small section
of the coupled TLs we will be able to describe the interaction between the two TLs. The equivalent
circuit for one section of coupled TLs is shown in Figs. 18. We want to simplify the analysis of the
26
Ground plane
Receptor conductor
Generator conductor
Vs
Rs
RL
RNE
RFE
length L
Figure 17. General TL coupling problem.
coupling between the two TLs in Fig. 18 to the following two cases:
1) capacitive coupling (occurs in high impedance circuits)
2) inductive coupling (occurs in low impedance circuits)
Vs
Rs
Lg/2
Lr/2
Lg/2
Lr/2
Rg/2
Rr/2
Rg/2
Rr/2
Cgr
CgCr
Lgr/2Lgr/2
RNE RFE
RL
Figure 18. Equivalent circuit of the coupled transmission lines.
2.4.2. Capacitive coupling (low frequencies)
For this analysis, we assume that we have high impedance loads on the coupled TLs in Fig.
17. If this is the case, then the coupling between the TLs is mostly capacitive. This reduces the
equivalent circuit in Fig. 18 to the equivalent circuits shown in Figs. 19 a) and b).
Next, we want to write the voltages induced on RNE and RFE by Vs. Evaluating the equivalent
27
Ground plane
Receptor conductorGenerator conductor
Vs
Rs
RL
RNE
RFE
Cg Cr
Cgr = (cgr)L
Vs
Rs
Cgr
Cg Cr R = RNE||RFE RL
Vin
+
-
a) b)
VNE
cap
= VFE
cap
+
-VNE
cap
+
-
Figure 19. a) Capacitive coupling between the coupled transmission lines and b) the equivalent circuit ofthe capacitively coupled transmission lines.
circuit in Fig. 19 b) gives
V capNE = V cap
FE = Vin
(R|| 1
jωCr
R|| 1jωCr
+ 1jωCgr
)
= Vin
( jω Cgr
Cgr+Cr
jω + 1R(Cgr+Cr)
). (2.55)
Next, for low frequencies we have the following assumption:
ω <<1
R(Cgr + Cr). (2.56)
This then simplifies (2.55) to
V capNE = V cap
FE ≈ jωCgrVinR. (2.57)
Note again that (2.57) is for high impedance circuits. We can also write
Vin = Vs
(Zin
Zin +Rs
)(2.58)
and
Zin =
(1
jωCg
)||RL||
[1
jωCgr
+R||(
1
jωCr
)]. (2.59)
28
But, for low frequencies we can approximate a capacitor as an open. This then gives
Vin ≈ Vg(DC) ≈ Vs
(RL
RL +Rs
). (2.60)
2.4.3. Inductive coupling (low frequencies)
In this section we want to look at the low frequency inductive coupling between the TLs. For
this case we simply open all capacitors in Fig. 18. This then results in the equivalent circuit shown
in Fig. 20. The near-end voltage can be written as V indNE = IrRNE and the far-end voltage can be
Ground plane
Receptor conductorGenerator conductor
Vs
Rs
RL
RNE
RFE
Lg Lr
Lgr
VNE
ind
+
-
Ig Ir
VFE
ind
+
-
Figure 20. The equivalent circuit of the inductively coupled transmission lines.
written as V indFE = IrRFE. Next, KVL for the receptor gives IrRNE+jωLrIr+RFEIr−jωLgrIg = 0.
⇒
Ir =jωLgrIg
(RNE +RFE) + jωLr
. (2.61)
Next, KVL around the generator gives −Vs +RsIg + jωLgIg + IgRL − jωIrLgr = 0. ⇒
Ig =Vs
(Rs +RL) + jωLg
+jωLgr
(Rs +RL) + jωLg
Ir. (2.62)
Next, if we assume that ωLr << RNE +RFE, ωLg << (Rs +RL) and a weak coupling condition of
29
(ωLgr)2 << (Rs +RL)(RNE +RFE) then
Ig ≈Vs
Rs +RL
= Ig(DC) (2.63)
and
Ir ≈jωLgr
RNE +RFE
Ig(DC). (2.64)
Then
V indNE ≈ jωLgr
−RNE
RNE +RFE
Ig(DC) (2.65)
and
V indFE ≈ +jωLgr
RFE
RNE +RFE
Ig(DC). (2.66)
30
2.4.4. Equations for both inductive and capacitive coupling
Noting that both V ind and V cap are proportional to jω and Vs we can write the results as
VNE
Vs
= jω
(M ind
NE +M capNE
)(2.67)
and
VFE
Vs
= jω
(M ind
FE +M capFE
)(2.68)
where
M indNE =
RNE
RNE +RFE
Lgr
Rs +RL
, (2.69)
M indFE =
RFE
RNE +RFE
Lgr
Rs +RL
(2.70)
and
M capNE = M cap
FE = (RNE||RFE)RLCgr
Rs +RL
. (2.71)
This then results in the inductive/capacitive model shown in Fig. 21 where
Vg(DC) = VsRL
RL +Rs
(2.72)
and
Ig(DC) =Vs
Rs +RL
. (2.73)
jωLgrIg(DC)
VFE
+
-
+
-
+ -
RFE RNEVNE
jωCgrVg(DC)
Figure 21. The equivalent inductive/capacitive model of the coupled transmission lines.
31
Note that the equivalent circuit model shown in Fig. 21 breaks down for TL lengths longer
than ≈ 0.2λ. Therefore, if the frequency is high enough then a smaller segment of the TL should
be analyzed or a more accurate distributive model of the coupled TL should be used.
Next, we consider the problem in Fig. 17 for the case when the ground plane has finite
conductivity. We represent the loss with a lumped resistor Ro = rol where l is the length of the
TL and ro is the per-unit loss of the ground plane. The problem with Ro defined is shown in Fig.
22. Ro is called the common impedance and Vo is called the common impedance voltage where
Vo = roIref . ⇒ Iref = Ir + Ig ≈ Ig(DC) at low frequencies. ⇒
Vo ≈ Vs
(Ro
Rs +RL
). (2.74)
This voltage appears on the receptor circuit also. Therefore, this contributes to the near- and
far-end noise voltages at low frequencies. This then gives:
V ciNE
Vs
= M ciNE (2.75)
and
V ciFE
Vs
= M ciFE (2.76)
where
M ciNE =
RNE
RNE +RFE
Ro
Rs +RL
(2.77)
and
M ciFE = − RFE
RNE +RFE
Ro
Rs +RL
. (2.78)
With this notation, we have the following final coupling equations that include the common impedance
noise voltages:
VNE
Vs
= jω
(M ind
NE +M capNE
)+M ci
NE (2.79)
32
and
VFE
Vs
= jω
(M ind
FE +M capFE
)+M ci
FE (2.80)
This results in the equivalent circuit show in Fig. 23.
Vs
Rs
RNE RFE RLVNE
+
-
VFE
+
-
Ro
Vo
+-
Ig
Ir
Iref
Figure 22. Coupled transmission lines with a lossy reference conductor.
jωLgrIg(DC)
VFE
+
-
+
-
+ -
RFE RNEVNE
jωCgrVg(DC)
RoIg(DC)
+ -
Figure 23. The equivalent inductive/capacitive model of the coupled transmission lines with a lossyreference conductor.
2.5. Shielding
2.5.1. Reducing capacitive coupling
In this section we investigate the use of shielding to reduce the coupling between the TLs in
Fig. 17. From (2.57) we can see that we can reduce the capacitive coupling by :
1) reducing frequency
2) reducing RNE and/or RFE
3) reducing Vg(DC) by reducing Vs
4) reducing Cgr by increasing the spacing between the traces and shielding
For this section we will focus on using a shield around the receptor to reduce the capacitive
33
coupling. This problem is defined in Fig. 24 where Vs is the generator (source) open circuit voltage,
Vs,o is the output voltage of the source, Cg is the capacitance from the generator to the reference
conductor, Cgs is the capacitance from the generator to the shield, Cgr is the capacitance from
the generator to the reference conductor, Cs is the capacitance from the shield to the reference
conductor, Crs is the capacitance from the receptor conductor to the shield, Cr is the capacitance
from the receptor to the reference conductor and Vsh is the voltage between the shield and reference
conductor. If we ground the shield on the receptor conductor (at both ends), then we have the
equivalent circuit shown in Fig. 25.
Ground plane
Receptor conductorGenerator conductor
Vs
Rs
RL
RNE
RFE
Cg Cr
Cgr
VNE
+
-
Cgs
Crs
Cs
Vsh
+
-
Shield
VFE
+
-
Vs,o
+
-
Figure 24. Capacitively coupled transmission lines with a shielded receptor.
Vg
Rs
Cgr
Cg Cr R = RNE||RFE RL VNE
cap
= VFE
cap
+
-
Vs,o
+
-
CgsCrs
Figure 25. The equivalent circuit of the coupled transmission lines with a shielded receptor.
Using circuit analysis, the following expression can be evaluated from the circuit in Fig. 25:
V capNE = Vs,o
(R||(
1jω(Crs+Cr)
)R||(
1jω(Crs+Cr)
)+ 1
jωCgr
)(2.81)
or
34
V capNE = Vs,o
(jω( Cgr
Cgr+Crs+Cr
)jω + 1
R(Cgr+Crs+Cr)
). (2.82)
At low frequencies we have Vs,o ≈ VsRL/(RL + Rs) = Vg(DC) and ω << 1/(R(Cgr + Cr + Crs)).
This then simplifies (2.82) down to
V capNE = V cap
FE ≈ jωRCgrVg(DC). (2.83)
Equation (2.83) is similar to (2.57), except in (2.83) Cgr is much less than Cgr in (2.57).
2.5.2. Reducing inductive coupling
When looking at shielding for inductive coupling, we need to first consider the expressions in
(2.65) and (2.66). We can see that we can reduce the inductive coupling by :
1) reducing frequency
2) reducing Ig(DC)
3) reducing Lgr by
i) reducing the area between the trace and ground plane
ii) orientation
iii) a choke
Receptor conductor
Generator conductor
Vs
Rs
RL
RNE
RFE
Lg
Lr
Lgr
VNE
ind
+
-
Ig
Ir
VFE
ind+
-
Shield
Lsh
Ish
Rsh
Lg,sh
Lsh,r
Figure 26. Inductively coupled transmission lines with a shielded receptor.
To understand the best method of shielding for inductive coupling we need to consider the
problem in Fig. 26. We want to write the voltages across the near- and far-end resistors in
35
terms of the inductive coupling and the source voltage. First, KVL around the shield loop gives:
IshRsh + (jωLg,sh)Ig − (jωLsh)Ish − (jωLsh,r)Ir = 0. Solving for Ish gives
Ish =+jω(Lg,shIg + Lsh,rIr)
Rsh + jωLsh
. (2.84)
Next, KVL around the receptor loop gives: IrRNE−(jωLgr)Ig−(jωLsh,r)Ish+(jωLr)Ir+IrRFE = 0
where V indNE = IrRNE and V ind
FE = −IrRFE. Solving for Ir gives:
Ir =jω(LgrIg + Lsh,rIsh)
RNE +RFE + jωLr
. (2.85)
Next, substituting (2.84) into (2.85) gives
Ir =jω
RNE +RFE + jωLr
[LgrIg(Rsh + jωLsh)− jωLsh,r(Lg,shIg + Lsh,rIr)
Rsh + jωLsh
]. (2.86)
Rearranging then gives:
Ir =jω
RNE +RFE + jωLr
[Ig(LgrRsh + jωLshLgr − jωLsh,rLg,sh) + jω(Lsh,r)
2IrRsh + jωLsh
]. (2.87)
Now assume we have a uniform current distribution along the conductors in Fig. 43. This then
gives Lgr ≈ Lg,sh and Lsh ≈ Lsh,r. Rearranging (2.87) and substituting in the above assumptions
gives:
Ir
[1 +
(ωLsh,r)2
[RNE +RFE + jωLr][Rsh + jωLsh]
]= Ig
[jωLgrRsh
[RNE +RFE + jωLr][Rsh + jωLsh]
]. (2.88)
Solving for Ir gives
Ir =jωIgLgrRsh
[RNE +RFE + jωLr][Rsh + jωLsh] + (ωLsh,r)2. (2.89)
Next, if we denote the denominator of (2.89) atDEN = [RNE+RFE+jωLr][Rsh+jωLsh]+(ωLsh,r)2
36
and assume that Lr ≈ Lsh ≈ Lsh,r then DEN simplifies to DEN = (RNE+RFE)Rsh+jωLsh[RNE+
RFE +Rsh]. Next, if we assume that RNE +RFE >> Rsh then (2.89) simplifies to
Ir ≈+jωIgLgrRsh
(RNE +RFE)(Rsh + jωLsh). (2.90)
Using Ig ≈ Ig(DC) = Vs
Rs+RL. This then gives the following expressions for the near- and far-end
voltages in Fig. 43:
V indNE = −RNEIr ≈
[RNE
RNE +RFE
(jωLgrIg(DC))
][Rsh
Rsh + jωLsh
](2.91)
and
V indFE = RFEIr ≈
[−RFE
RNE +RFE
(jωLgrIg(DC))
][Rsh
Rsh + jωLsh
]. (2.92)
The [Rsh
Rsh + jωLsh
](2.93)
term in (2.92) is referred to as the Shield Factor (SF). This term is the same in both (2.91) and
(2.92). Also note that
SF =Rsh
Rsh + jωLsh
=1
1 + jω Lsh
Rsh
. (2.94)
This then implies:
SF =
1 if ω << Rsh/Lsh
Rsh/jωLsh if ω >> Rsh/Lsh
(2.95)
What we see from (2.95) is that the shield has no effect on the coupling caused by the mutual
inductance at low frequencies. The voltage w.r.t. frequency caused by mutual inductance is
plotted in Fig. 27. We can see that the shield for the inductive coupling starts to reduce V ind at
approximately Rsh/Lsh. Therefore, the shield grounded at one end does not improve the inductive
crosstalk. To do this we need to ground the shield at both ends. However, shields grounded at both
ends are susceptible to ground loop problems.
37
|V |ind
ω
High frequency
Low frequency
(response with the
shield grounded on
one end)
20 dB/decade
ω ≅ Rsh/Lsh
Figure 27. Induced voltage caused by inductive coupling.
2.5.3. Summary of transmission line coupling equations
Without a shield
For capacitive coupling without a shield we have the following equations:
V capNE = V cap
FE ≈ jωCgrVinR. (2.96)
For inductive coupling without a shield we have the following equations:
V indNE ≈ jωLgr
−RNE
RNE +RFE
Ig(DC) (2.97)
and
V indFE ≈ jωLgr
RFE
RNE +RFE
Ig(DC) (2.98)
where Ig(DC) = Vs/(Rs +RL).
Then to compute both the inductive and capacitive coupling between TLs without a shield we use
the following expressions:
VNE
Vs
= jω
(M ind
NE +M capNE
)(2.99)
38
and
VFE
Vs
= jω
(M ind
FE +M capFE
)(2.100)
where
M indNE =
RNE
RNE +RFE
Lgr
Rs +RL
, (2.101)
M indFE =
RFE
RNE +RFE
Lgr
Rs +RL
(2.102)
and
M capNE = M cap
FE = (RNE||RFE)RLCgr
Rs +RL
. (2.103)
Next, if we include the common impedance noise voltage (these expressions are valid with or without
a shield) we have:
VNE
Vs
= jω
(M ind
NE +M capNE
)+M ci
NE (2.104)
and
VFE
Vs
= jω
(M ind
FE +M capFE
)+M ci
FE (2.105)
where
M ciNE =
RNE
RNE +RFE
Ro
Rs +RL
(2.106)
and
M ciFE = − RFE
RNE +RFE
Ro
Rs +RL
. (2.107)
With a shield
For capacitive coupling with a shield we have the following equations:
V capNE = V cap
FE ≈ jωRCgrVg(DC). (2.108)
For inductive coupling with a shield we have the following equations:
V indNE =
[−RNE
RNE +RFE
jωLgrIg(DC)
]SF (2.109)
39
and
V indFE =
[RFE
RNE +RFE
jωLgrIg(DC)
]SF (2.110)
where
SF =Rsh
Rsh + jωLsh
=1
1 + jω Lsh
Rsh
. (2.111)
This then implies:
SF =
1 if ω << Rsh/Lsh
Rsh/jωLsh if ω >> Rsh/Lsh
(2.112)
Then to compute both the inductive and capacitive coupling between TLs with a shield we use the
following expressions:
VNE
Vs
= jω
(M ind
NE +M capNE
)(2.113)
and
VFE
Vs
= jω
(M ind
FE +M capFE
)(2.114)
where
M indNE =
−RNE
RNE +RFE
Lgr
Rs +RL
SF, (2.115)
M indFE =
RFE
RNE +RFE
Lgr
Rs +RL
SF (2.116)
and
M capNE = M cap
FE = (RNE||RFE)RLCgr
Rs +RL
. (2.117)
2.6. Twisted pair
The next TL coupling problem investigated is the twisted pair problem shown in Fig. 28. The
problem consists of two conductors twisted together in the presence of a single conductor carrying a
current IG. In this problem there exist capacitive and inductive coupling between the twisted pair
and the single conductor. To represent this coupling, we define the equivalent circuit shown in Fig.
29. We will evaluate this equivalent circuit to understand how the twisted affect of the wire can
reduce the inductive coupling. For this investigation we have two possible loading configurations:
40
IG
Coupling
magnetic
fields
Figure 28. Twisted pair coupling problem.
+ -
+ -
+ -
+ -
Ground reference
RNE RFE
LHT
E1 = jωlgr1LHTIg E1 = jωlgr1LHTIg
E2 = jωlgr2LHTIg E2 = jωlgr2LHTIg
I2 = jωcgr2LHTVgI1 = jωcgr1LHTVg I1 = jωcgr1LHTVg
I2 = jωcgr2LHTVg
Figure 29. Equivalent circuit of the twisted pair coupling problem.
1) Balanced configuration - both wires have the same impedance to ground.
2) Unbalanced configuration - both wires do not have the same impedance to ground.
The ind./cap. model used to investigate the crosstalk in the twisted pair will depend on how
the ground is connected (i.e., if a balanced or unbalanced system is used). First, if we assume
an unbalanced system we get the equivalent circuits in Figs. 30 and 31. The model in Fig. 30
represents the inductive coupling and the model in Fig. 31 represents the capacitive coupling.
2.6.1. Inductive coupling - unbalanced
When evaluating the equivalent circuit in Fig. 30 using KVL we get the following equation:
E1 + E2 − E1 − E2 = 0. This shows that for each unit of twisted wires along the twisted pair cable,
41
we have a zero-sum value for the KVL analysis of each twist. This indicates that the inductive
coupling between the single wire and the twisted pair in Fig. 28 is almost zero or negligible. This
then tells us that twisted pair is useful when it is desired to reduce the crosstalk due to inductive
coupling.
+ -
+ -
+ -
+ -
RNE RFE
E1 = jωlgr1LHTIg
E1 = jωlgr1LHTIgE2 = jωlgr2LHTIg
E2 = jωlgr2LHTIg
+
-
VNE
IND
Figure 30. Equivalent circuit for the inductive coupling in the twisted pair coupling problem.
2.6.2. Capacitive coupling - unbalanced
Next, for the capacitive coupling we consider the equivalent circuit in Fig. 31. If we assume
that the twisted pair is tight, then we can assume the the following: cgr1 ≈ cgr2. This assumption
states that the capacitive between the generator in Fig. 28 and both of the conductors in the twisted
pair are the same. This then reduces the circuit in Fig. 31 to the circuit in Fig. 32. We can then
write the near-end and far-end voltage as
V CAPNE ≈ jωcgr1LHTNTVg(DC)RNE||RFE (2.118)
or
V CAPNE ≈ jωCT
gr1Vg(DC)RNE||RFE (2.119)
where LHT is the length of the full-twist, NT is the number of twists and CTgr1 = cgr1LHTNT .
Therefore, using a twisted pair with unbalanced grounding reduces V IND but not V CAP . Finally,
in general we have
VNE ≈ RNE
RNE +RFE
[jω(lgr1 − lgr2)LHT
]I(DC) + jωCT
gr1Vg(DC)RNE||RFE. (2.120)
42
RNE RFE
I2 = jωcgr2LHTVg
I1 = jωcgr1LHTVg I1 = jωcgr1LHTVg
I2 = jωcgr2LHTVg
+
-
VNE
CAP
Figure 31. Equivalent circuit for the capacitive coupling in the twisted pair coupling problem.
RNE RFE2I1
+
-
VNECAP
Figure 32. Reduced equivalent circuit for the capacitive coupling in the twisted pair coupling problem.
2.6.3. Balanced case
For this section we look at the balanced case (Fig. 33). The equivalent circuit for capacitive
coupling for this case is shown in Fig. 34. The inductive coupling is the same as for the unbalanced
case. We can see that the near-end voltage is zero for an even number of twists and close to zero
for an odd number of twists. Therefore, for the balance case the capacitive coupling is essential
zero. In summary, if possible it is best to use the twisted pair in a balanced case because both the
inductive and capacitive coupling is minimized.
RNE/2
RNE/2
RFE/2
RFE/2
Figure 33. The twisted pair coupling problem with a balanced load.
43
+
-
VNE
CAP
RNE/2
RNE/2
RFE/2
RFE/2
+ -
I2N(I1+I2)I2N(I1+I2)
E1-E2
0 for an even number of twists
for an odd number of twists
Figure 34. The equivalent circuit for the capacitive coupling in the twisted pair coupling problem with abalanced load.
44
CHAPTER 3. DESIGNING FOR EMC
3.1. Components
3.1.1. Conductors
From chapter 1 we know that the capacitance between two parallel plates with area S is
C = ε0S/d where ε0 is the permittivity of the material between the plates and d is the separation
of the two parallel plates. It can also be shown that the capacitance between the two parallel wires
in Fig. 9 a) is C = πε/ ln(d/a) and the capacitance between the wire and the ground plane in
Fig. 9 b) is C = 2πε/ ln(2h/a). It can also be shown that the external inductance of the wire
above the ground plane in Fig. 9 b) is Lext ≈ µ2π
ln(2h/a) H/m. Since we have LextC = µε then
C = µεLext
= 2πε/ ln(2h/a) F/m.
Next, we want to calculate the external inductance of the rectangular conductor in Fig. 35.
The following can be shown:
Lext ≈
5 ln(2πhw
)nH/in, w << 2h and t<<w (narrow strip);
32(hw
)nH/in, 2h << w and t<<h (wide strip).
(3.1)
Next, it can be shown that the external inductance of the square conductors in Fig. 36 is
Lext ≈ 10 ln(πhw
)nH/in. (3.2)
The DC resistance can also be shown to be
Rdc =L
σS(3.3)
where L is the length of the conductor, σ is the conductivity of the conductor and S is the cross-
sectional area for a round wire.
3.1.2. Skin depth
Next we introduce the concept of skin depth. To illustrate this consider the electric field
45
Ground plane
Rectangular
conductorw
t
h
Figure 35. A single rectangular conductor over a ground plane.
Rectangular
conductorw
t
h
Rectangular
conductorw
t
Figure 36. Two rectangular conductors in free-space.
impinging on the material in Fig. 37. We define the skin depth as the value of δ such that
e−αδ = e−1. Solving for δ gives (for a good conductor)
δ =1
α=
1√πfµσ
. (3.4)
3.1.3. AC parameters
Using the definition of skin depth in 3.4 results in the following AC resistance for a conductors:
RAC ≈ L
σ(2πaδ)(3.5)
where L is the length of the conductor and a is the radius of the conductor. We can also write the
46
δβz
Eo (amplitude)
1/e
Envelope of e−αz
Impinging
electric field
(air) (material)
Figure 37. Definition of skin depth.
AC resistance in terms of the DC resistance. This then gives
RAC = [0.096(2a)√
f + 0.26]RDCΩ/in. (3.6)
For wires or conductor with different shapes, we can define an equivalent diameter of the conductor
in the following manner:
d =perimeter of cross− section
π. (3.7)
In a similar manner, we can define the AC inductance as:
Lint,AC ≈ 2δ
aLint,DC =
1
4πa
õ
πσfH/m (3.8)
where Lint,DC = µ/(8π).
3.1.4. Non-ideal capacitors
If current flows through a real conductor, then we are guaranteed to have inductance and
resistance. If we have more than one conductor at different potentials, we are guaranteed to have
capacitance. With this in mind, we will investigate non-ideal components. The first is the capacitor.
47
The impedance of a non-ideal capacitor is shown in Fig. 38. We can see that the “real” (non-ideal)
capacitor behaves similar to an ideal capacitor up to a resonant point. Then the inductance of the
component begins to dominant. This behavior leads to the equivalent circuit in Fig. 39. If R2 is
neglected, then Z = R + j(ωL− 1/(ωC)). This then gives fo =1
2π√LC
.
f
|Zc|
20 dB/decade
R1
looks like
a capacitor
looks like
an inductor
fo
Figure 38. Impedance of a non-ideal capacitor.
L R1
R2
C
Due to conductors on leads
Leakage resistance
(often neglected)
Figure 39. Equivalent circuit of a non-ideal capacitor.
3.1.5. Non-ideal resistors
There are three different types of resistors:
1) Composition - the inductance is very small.
2) Film type - the inductance is moderate - has some effect.
3) Wirewound - the inductance is very significant but can dissipate several Watts of power.
The impedance of a typical non-ideal resistor is shown in Fig. 40. The equivalent circuit is
shown in Fig. 41.
48
f
|Zr|
fo
Figure 40. Impedance of a non-ideal resistor.
L R
C
Figure 41. Equivalent circuit of a non-ideal resistor.
3.1.6. Non-ideal inductors
There are four types of inductors:
1) Wound on an open core (Fig. 42 a)):
a) permeable core - iron, etc.
b) non-permeable material as core (wood, air, .etc)
2) Wound on a closed core (Fig. 42 b)):
a) permeable core - iron, etc.
b) non-permeable material as core (wood, air, .etc)
We summarize the behavior of open- and closed-core inductors in the following table (1 is the worst
and 4 is the best):
49
AIR cause of radiated emissions susceptible to radiated fields
open core 1 2
close core 3 4
MAGNETIC
open core 2 1
closed core 4 3
a) b)
Figure 42. a) Open core inductor and b) closed core inductor.
One other aspect to consider is don’t pass to much current such that the inductor saturates.
The impedance of a typical non-ideal inductor is shown in Fig. 43. The equivalent circuit is shown
in Fig. 44.
f
|ZL|
Figure 43. Impedance of a non-ideal inductor.
3.2. Ferrite Beads
50
L R
C
Figure 44. Equivalent circuit of a non-ideal inductor.
Ferrite beads are a very useful tool for suppressing EMI in a system. Ferrite beads can be
used to provide some impedances that can be used for high-frequency filtering (Fig. 45). To avoid
saturation of ferrite beads, one may use some “rules of thumb,” such as:
1) onset of saturation is when
Ibead = 10Ri (3.9)
where Ri is the inner radius of the bead (in cm).
2) full saturation when
Ibead ≥ 10Ro (3.10)
where Ro is the outer radius of the bead (in cm).
Noise on the line
Signal line
Capacitor
for filtering
signal line
Insert ferrite bead
for filtering
Equivalent
circuit
Figure 45. Noise on a circuit.
3.3. Grounding
There are two main types of grounding. One for safety and one for signals. We can think of
a ground for signals (or the signal ground) as
51
1) a place for source/sink of charge
2) a return path for current
3) a common reference points
4) a zero potential point
5) earth.
In this section, we will think of the signal ground as a return path for current.
3.3.1. 3-types of (signal) ground systems
The three main types of grounding are listed below:
1) A single-point ground
a) series connection (Fig. 46) or a daisy chain.
b) parallel connection (Fig. 47).
1 2 3
Z1 Z2 Z3A B CI1 I2 I3
Source
Ground
Figure 46. Series connection.
1 2 3
Z1
Z2
Z3
AB
C
I1 I2 I3
Source
Ground
Figure 47. Parallel connection.
52
For the series connection in Fig. 46 we have the following node voltage values
VA = Z1(I1 + I2 + I3)
VB = VA + Z2(I2 + I3)
VC = VB + Z3I3.
For the parallel connection in Fig. 47 we have
VA = Z1I1
VB = Z2I2
VC = Z3I3.
When comparing these node voltages to the node voltages for the series connection we can see that
from a noise perspective a parallel connection is more desirable for low frequencies. This is because
a parallel ground connection has no common impedance coupling.
2) A multi-point ground
A multi-point ground is shown in Fig. 48. This is very useful at high frequencies because
this kind of grounding minimizes the capacitance between ground leads. The effect of inductance
of your ground system is minimized at high frequencies.
1 2 3I1 I2 I3
Source
Ground
Figure 48. Multi-point connection.
53
3) Hybrid ground
This system is shown in Fig. 49. This system may be a single point ground over one frequency
range and a multi-point ground system over another frequency range.
Source
Ground
Shield
Figure 49. Hybrid connection.
3.3.2. EMC grounding philosophy
1) Think of grounding as the closing of current loops.
2) Close current loops as compactly and locally as possible (including parasitic currents).
a) prevent external ground currents from flowing through your circuit.
b) provide known paths (that do not use external conductors) for your ground currents.
3) Limit currents to and from mother earth as much as possible.
a) use single point connection to AC power ground.
b) if single point AC power ground is not possible, use circuitry that can reject ground noise.
3.3.3. Examples of cable grounding
If we have a grounded load and an ungrounded source then where do we connect our shield?
Connect the shield to the common of the load.
If we have a grounded source and an ungrounded load, then were do we connect our shield?
Connect the shield to the common of the source.
How do we minimize the effect of ground loops?
1) lift the ground at one end - if possible.
2) minimize the distance from the source to the load.
3) transformer couple the source to the load.
54
4) optically couple the source to the load.
5) use hybrid grounds.
6) use common mode chokes.
3.3.4. The 2-types of current in EMC
The two types of current typically investigated in EMC are:
1) common mode currents which are currents that flow in the same direction (Fig. 50).
2) differential mode currents which are the intended currents that flows in the opposite
direction (Fig. 50).
3.3.5. Common-mode choke
We can see that if the turns of the common-mode choke in Fig. 51 are the same for each wire
and that the flux Ψ perfectly links the other windings, then the total flux in the core as a result
of differential mode currents is zero. Thus, the choke will not have any effect on the differential
mode current. On the other hand, if common mode currents are present on the conductors, then
the flux in the core created by these currents adds together in the core. And since inductance is the
ratio of the flux Ψ to the current creating the flux, the choke is introducing an inductance to the
common mode currents and essentially choking off the common mode current. In other words, the
differential mode current does not “see” an impedance in the core but the common mode current
is experiencing an inductance (or impedance).
circuit 1 circuit 2
VG
IC ID
I2
I1
Total current
Total currentCommon-mode
current
Differential-mode
current
IC ID
Figure 50. Examples of common and differential mode currents.
55
ID
ID
differential-mode currents
ψD
ψD
IC
IC
common-mode currents
ψC
ψC
Figure 51. Illustration of a common mode choke.
3.3.6. Balanced circuits
Another method to reduce common mode current is to design a balanced circuit (if possible).
Consider the problem in Fig. 52. The original problem has two conductors connecting circuit 1 to
circuit 2. In this example, the two references for each circuit are not at the same potential and vary
by a voltage denoted as VG. Because of this voltage VG, the return current through the conductors
(denoted as IN1 and IN2) travel in the same direction down each conductor. This then results in
common mode currents. This then results in a noise voltage of
VN = VGRL
Rs +RL
.
We want to eliminate VN . One way to do this is to design the balanced circuit in Fig. 53. In this
balanced case, the load resistor is split into two equal values. This then results in IN1 and IN2
traveling through each resistor in opposite directions. Thus, the resulting noise voltage VN is zero
because VN = RL
2(IN2 − IN1) = 0 if IN1 = IN2 (perfect balance).
Vs
Rs
RL
circuit 1 circuit 2
VG
VN
+
-
IN1
IN2
Figure 52. An unbalanced circuit with common-mode currents.
56
Vs/2
Rs/2
RL/2
VG
VN
+
-
IN1
IN2
RL/2Vs/2
Rs/2
Figure 53. A balanced circuit eliminating common-mode currents.
3.4. Filtering
3.4.1. Introduction to insertion loss
When we discuss EMC filtering we need to be mindful of both emissions (filtering to prevent
our noise form leaving) and immunity or susceptibility (filtering to protect our system from external
noise). We need to think of both differential mode filtering and common mode filtering. The
insertion loss (IL) is the figure of merit commonly used to gauge the effectiveness of a filter. Consider
the IL of the filter in Fig. 54. The insertion loss is defined as:
IL = 10 log
∣∣∣∣PR(ref)
PR
∣∣∣∣ = 20 log
∣∣∣∣VR(ref)
VR
∣∣∣∣ (3.11)
where PR(ref) or VR(ref) refer to the power or voltage at the load without the filter in place.
Vs Filter
Zs
ZRVin
+
-
VR
+
-
Figure 54. Insertion loss of a filter.
3.4.2. Insertion loss example of a capacitor
In this example, we want to calculate the IL of a capacitor. To do this, consider the example
57
in Fig. 55. This then gives VR(ref) = Vs
[ZR
ZR+Zs
]and
VR = Vs
[ZR||ZL
Zs + ZR||ZL
]=
VsZR
(ZR + Zs) + jωC(ZsZR).
This then gives an IL of
IL = 20 log
∣∣∣∣VR(ref)
VR
∣∣∣∣= 20 log
∣∣∣∣ ZR
ZR + Zs
ZR + Zs + jωCZsZR
ZR
∣∣∣∣= 20 log
∣∣∣∣1 + jωCZsZR
Zs + ZR
∣∣∣∣= 20 log
√1 + (ωτ)2
where τ = C(Zs||ZR). The IL is plotted in Fig. 56.
Vs
Zs
ZRVin
+
-
VR
+
-
C
Figure 55. Insertion loss of a capacitor example.
ωτ = 1
20 dB/decade
IL (dB)
ω
Figure 56. Insertion loss of a capacitor.
3.4.3. Differential- and common-mode filters
A differential mode filter is what you normally think of when you decide to design a filter. An
illustration of a differential-mode filter is in Fig. 57. A common mode filter is slightly different. An
58
illustration of a common-mode filter is in Fig. 58. The differential-mode filter supports differential-
mode currents while a common-mode filter is forced to use common-mode currents. Therefore,
a common mode filter may only affect the common-mode operation of a circuit. Several more
examples of common mode filters are shown in Fig. 59.
V0 Filter
ground
Figure 57. Differential-mode filter.
V0
Filter
Figure 58. Common-mode filter.
M
Figure 59. Examples of common-mode filters.
59
3.4.4. Designing maximally flat Butterworth filters
In this section we want to design maximally flat butterworth filters (as one example of
differential-mode filter design). Several examples of the I.L. for various filters are shown in Fig. 60.
There are 4-steps in designing butterworth filters:
1) provide specs (N dB/dec, HP, LP, BP, etc.)
2) design low frequency prototype
3) use frequency and impedance scaling to the desired problem
4) implementation (testing, simulation, etc.)
ω
I.L.
fc
Low-pass
ω
I.L.
fc
High-pass
3 dB point 3 dB point
ω
I.L.
fcL
Band-pass
ω
I.L.Band-stop
3 dB point3 dB point
fcU fcL fcU
Figure 60. The I.L. of four typical filter responses.
3.4.5. Low-pass filter design
There are two types of low frequency prototypes. Both are shown in Fig. 61. The prototype
in Fig. 61 will be used in conjunction with the table in Fig. 62. From the list above, we need to
define how many dB/dec of I.L. we want from our filter. Each element in the prototypes in Fig.
61 insert 20 dB/dec of I.L. (this was shown for a capacitor in a previous section). Therefore, if
we want 60 dB/dec of I.L., we need three elements in our prototype design. Next, we choose the
60
appropriate low frequency prototype in Fig. 61 and determine the values of An. This is done by
using the table in Fig. 62. The first step when using the tables is to calculate Rs/RL and RL/Rs
where Rs is the source resistance and RL is the load resistance. Then use these values in the second
column to determine the least number of elements and the values of An (we will do an example
shortly). The next step is to then use frequency and impedance scaling to design the appropriate
filter. The cut-off frequency for the prototype filter is ωp = 1 rad/s and the normalized prototype
load is RL,p = 1. Next, the following LP frequency scaling functions are used to determine the final
LP filter design:
C =Cp
ωcRL
(3.12)
and
L =RLLp
ωc
(3.13)
where Cp, Lp are prototype values from the table in Fig. 62, C,L are the final values of the circuit,
RL is the actual load resistor and ωc = 2πfc is the desired radian cutoff frequency. It should also
be noted that frequency scaling functions will be introduced to convert the prototype filter to LP,
HP and BS filters.
Vs
Rs
RL
Vs
Rs
RL
A1
A2
A3
A4
A1
A2
A3
A4
Figure 61. Low frequency prototypes for butterworth filters.
61
Figure 62. Design tables for butterworth filters.
62
3.4.6. LP Butterworth filter example
For this example we want to design a low-pass filter with Rs = 100Ω, RL = 50Ω, fc =
50MHz and an I.L. of 60 dB/dec in the stop band. In particular, we want a differential mode filter
(maximally flat response). This then gives Rs/RL = 2 and RL/Rs = .5. Using the least number of
elements and the table in Fig. 62 we get n = 3 and A1 = 1.181, A2 = .779 and A3 = 3.261. This
then results in the prototype in Fig. 63. Next, using the frequency scaling functions in (3.12) and
(3.13) results in the final circuit shown in Fig. 64.
Vs
Rs = 2
RL= 1A1 = 1.181
A2 = .779
A3 = 3.261
Figure 63. Low-frequency LP prototype.
Vs
Rs = 100
RL= 50.118 µH .519 µH
49.6 pF
Figure 64. Final LP filter design.
3.4.7. High-pass filter design
In this section we derive LP to HP filter transformations. To illustrate these expressions we
need to consider the responses in Fig. 65. If we use the transformation ωp = −ωc/ω or ω = −ωc/ωp
where ωc is the radian cut-off frequency of the HP response - we will transform the LP prototype
response to the desired HP response. Thus, as
ωp → 0+ ⇒ ω → −∞
ωp → 0− ⇒ ω → ∞
ωp → 1 ⇒ ω → −ωc
ωp → −1 ⇒ ω → +ωc.
63
This then gives ⇒
jωpLp → j
(−ωc
ω
)Lp =
1
jω 1ωcLp
=1
jωC
where C = 1/(ωcLp). Therefore, replace the prototype inductors (Lp) with capacitors of value
C =1
ωcLp
. (3.14)
And similarly replace the prototype capacitors (Cp) with
L =1
ωcCp
. (3.15)
When including the impedance scaling values we have
C =1
RωcLp
(3.16)
and
L =R
ωcCp
. (3.17)
ωp = 0−
ωp = 0+
ωp
IL
ωp = 1ωp
IL
Low-pass response
(prototype)
High-pass response
−ωc ωc
Figure 65. IL of LP- and HP-prototype filters.
3.4.8. HP Butterworth filter example
A circuit monitoring a 30 MHz signal is being interfered with by low frequency noise. We
64
want a HP filter with fc = 10 MHz and 80 dB/dec in the stop band. If Rs = 100, RL =50, then
design a HP filter with the listed specs.
Since we need 80 dB/dec. we need four elements. Again, Rs/RL = 2 and RL/Rs = .5. This
then gives A1 = .218, A2 = 2.452, A3 = .883 and A4 = 3.187. This then results in the LP prototype
circuit in Fig. 66. The final HP filter is shown in Fig. 67.
Vs
2
1.218
2.452
.883
3.187
Figure 66. Low-frequency LP prototype.
Vs
100
50
3.65 µH
129.8 pF 99.9 pF
.9 µH
Figure 67. Final HP filter design.
3.4.9. Band-pass filter design
In this section we introduce the design of BP filters. To do this, consider the illustration in
Fig. 68. The prototype frequency ωp can be mapped to the frequency for the BP filter as
ωp
IL
ωp
IL
Low-pass response
(prototype) Band-pass response
−ω0
3 dB
1 −ω1−ω2 ω0 ω2ω1
3 dB
Figure 68. IL of LP- and BP-prototype filters.
65
ωp =ω
ω2 − ω1
(ω
ωo
− ωo
ω
).
This then gives
ω = ωp
(ω2 − ω1
2
)±
√ω2p
(ω2 − ω1
2
)2
+ ω2o .
We usually simplify this by assuming ωo =√ω1ω2 ⇒ ω2 = ω1ω2. Then
ω = ωp
(ω2 − ω1
2
)± 1
2
√ω2p(ω2 − ω1)2 + 4ω1ω2.
If we say ∆ = ω2−ω1
ωo= f2−f1
fowhere ∆ is the fractional BW then our transformation is
ωp =1
∆
(ω
ωo
− ωo
ω
).
This then gives
jωLp → j
[1
∆
(ω
ωo
− ωo
ω
)Lp
]=
jωLp
∆ωo
− jωoLp
∆ω
= jω
(Lp
∆ωo
)+
1
jω
(∆
ωoLp
) .
Note that the term
jω
(Lp
∆ωo
)and
1
jω
(∆
ωoLp
)can be written as
jωLBPL
and
1
jωCBPL
66
where LBPL = Lp/(∆ωo) and CBP
L = ∆/(ωoLp). Therefore, we can replace a LP prototype inductor
with a series inductance and capacitance with values LBPL and CBP
L respectively. An illustration of
this is shown in Fig. 69. Therefore, including frequency scaling we have
LBPL =
RLp
∆ωo
(3.18)
and
CBPL =
∆
ωoLpR. (3.19)
Finally, we replace the capacitors with the parallel LC circuit shown in Fig. 70. To compute the
equivalent values we use:
LBPC =
∆R
ωoCp
(3.20)
and
CBPC =
Cp
∆ωoR. (3.21)
Lp LLBP CL
BP
Figure 69. LP- to BP- inductor element substitution
Cp
LCBP
CCBP
Figure 70. LP- to BP- capacitor element substitution
Finally, to pick the number of elements needed for the LP prototype we have the following
relation:
BW
BWc
=f
fc. (3.22)
67
The values of BW and BWc are shown in Fig. 71. The value of BWc is the BW desired at the
center frequency fc and the value of BW is the bandwidth at another frequency f where this other
frequency value is associated with more IL past the 3 dB cutoff. Then (3.22) along with the chart
shown in Fig. 72 will be used to determine the number of elements needed in the LP prototype
filter design.
ω
I.L.
fcL
Band-pass
3 dB point
fcU
BWc
BW
Figure 71. BW definitions for a BP-filter.
3.4.10. BP Butterworth filter example one
For this example we want to determine how many elements are needed for a filter with a 3dB
BW of 2 MHz and 40 dB of IL at a BW of 6 MHz. To determine how many elements we need in
our LP-prototype example we calculate
f
fc=
6MHz
2MHz= 3.
Then using the chart in Fig. 72 we can see that n = 4 or 5. We may need to try both and simulate
the resulting filter to determine if the requirements are met.
68
Figure 72. I.L. requirements for BP- and BS-butterworth filters.
69
3.4.11. BP Butterworth filter example two
For this example we want to design a BP filter with a center frequency of 75 MHz with a 3
dB BW of 7 MHz and an IL of 45 dB at a BW of 35 MHz. The source impedance is 50 Ω and the
load impedance is 100 Ω. Again, using (3.22) we have
BW
BWc
=f
fc=
35MHz
7MHz= 5.
From the chart in Fig. 72 we can see that we need at least 4 elements to provide 45 dB of IL. Next,
calculating the impedance ratios: Rs/RL = .5 and RL/Rs = 2. Using the table in Fig. 62 gives
A1 = .218, A2 = 2.452, A3 = .883 and A4 = 3.187. This resulted in the prototype filter design
shown in Fig. 73. Then, using the frequency and impedance scaling functions in (3.18)-(3.21) and
substituting we get the final BP design show in Fig. 74.
Vs
Rs = .5
RL= 1
A1 = .218
A2 = 2.452
A3 = .883
A4 = 3.187
Figure 73. LP-prototype for the BP example.
Vs
50
100
.496 µH 2 µH
8.1 nH
6.2 nH
9.086 pF 2.24 pF
.557 nF .72 nF
Figure 74. Final BP-filter circuit.
3.4.12. Band-stop filter design
In this section we introduce the band-stop filter design transformations. The desired insertion
loss of a band-stop filter is shown in Fig. 60. The transformation involved with the LP prototype
filter is to first replace ωp with
∆ωωo
− ωo
ω
.
70
this will then result in the following transformation equations for the prototype inductor:
LBSL =
Lp∆R
ωo
=LpBWR
2πf 2o
(3.23)
and
CBSL =
1
LpRωo∆=
1
LpR2πBW(3.24)
where
∆ =ω2 − ω1
ωo
= f2 − f1fo.
Then the LP prototype inductor is replaced with the capacitor and inductor connected in parallel
shown in Fig. 75. Next, the following transformation equations for the prototype capacitor can be
written as:
LBSC =
R
ωo∆Cp
=R
2πBWCp
(3.25)
and
CBSC =
∆Cp
Rωo
=CpBW
R2πf 2o
. (3.26)
The LP prototype capacitor is replaced with the capacitor and inductor connected in series shown
in Fig. 76.
Lp
LLBS
CLBS
Figure 75. LP- to BS- inductor element substitution
Cp LCBS CC
BS
Figure 76. LP- to BS- capacitor element substitution
71
Finally, to pick the number of elements needed for the LP prototype we have the following
relation:
BW
BWc
=f
fc(3.27)
except the values of BW and BWc are defined slightly different in Fig. 77 for the BS-filter. Then
(3.27) can be used in the chart in Fig. 72 to determine the number of elements for the filter design.
ω
I.L.
fcL
Band-stop
3 dB point
fcU
BWc
BW
Figure 77. BW definitions for a BS-filter.
72
CHAPTER 4. DIGITAL CIRCUITS
4.1. Noise
When laying out a digital circuit, we want to minimize the noise caused by digital circuitry.
In analog circuits we are often working at lower voltage levels which means we have a much lower
noise margin. With digital circuits, we are often working with much larger voltage levels. This
often results in much higher radiated noise. To start our investigation on how to reduce the noise
from digital circuits we start with the digital circuit in Fig. 78. The problem consists of four digital
gates. When the output of gate 1 changes from a logic high to a logic zero, the stray capacitance
needs to discharge before the input to gate 3 has a logic zero. This discharge happens through gate
1. The path the current takes is to ground, which is through the ground inductance. If the discharge
is fast enough a voltage will be induced across the ground inductance. Thus, if gate 2 is at a logic
0, the reference for this logic 0 changes from 0V to some other voltage proportional to the induce
voltage across the ground inductance. This then causes the output of gate 2 to rise momentarily
above zero. If this rise is high enough, then a logic 1 may be interpreted by gate 4. This could
change the output of gate 4. This wrong output is referred to as ground noise or switching noise.
Vcc
Vcc
Ground
inductance
Cstray
1
2
3
4
Idischarge
Figure 78. Noise in digital circuits.
We can minimize the effect of ground noise induced by parasitic capacitance by 1) reducing
stray capacitance (short traces, reduce fan-out); 2) reducing ground inductance (provide return
73
path directly below signal line); 3) reduce voltage levels; 4) increase ∆ t. To minimize ground
inductance we should use ground planes (if possible) or ground grids.
For the purposes of quick analysis of digital waveforms, we usually assume a trapezoidal wave
(Fig. 79). Next, we use the following equation when determining the max frequency of noise and
radiation from digital circuits:
BW =1
πtr(4.1)
where tr is the rise time defined in Fig. 79. The nth harmonic of current is written as
In = 2dIppsin(nπd)
nπd
sin(nπtr/T )
nπtr/T(4.2)
where T is the period and d is the duty cycle.
trT
Ippt
Figure 79. Digital signal approximation.
4.2. Decoupling Capacitors
When the switching circuitry is far from the power supply and the power plane inductance is
minimized, then we may provide a source of charge near the gates using decoupling capacitors. To
illustrate a decoupling capacitor we consider the digital circuit in Fig. 80. Much of the information
in this section comes from the paper “Power Bus Decoupling on Multilayer Printed Circuit Boards,”
by T. H. Hubing, J. L. Drewniak, T. P. Van Doren and D. M. Hockanson, IEEE Transactions on
Electromagnetic Compatibility, Vol. 37, No. 2, May 1995, pp. 155-166. The voltage at the board
can be written as:
Vboard(t) = Vsupply(t)− (LG + LP )di
dt. (4.3)
Now suppose that we have Lp ≈ 10µH and Lg is negligible. If we have 300 mA in 1 µS, then
∆V = (LP + LG)didt
= 3V . For this course, we usually assume a low frequency model for our
problems. For this example, our low frequency model assumes that the inductance of the traces on
74
Circuit
Cbulk = Cb
LP
LG
+
-Vsupply
PCBPower Supply
+
-
Vboard
Figure 80. Decoupling capacitor problem.
the PCB are negligible compared to LP and LG. Then we can calculate the Thevenin impedance
of the circuit shown in Fig ??. This then gives
Zth =
(1
ȷωCb
)∣∣∣∣∣∣∣∣jω(LG + LP ) (4.4)
and
Vth = Vsupply
( 1jωCb
1jωCb
+ jω(LP + LG)
). (4.5)
From (4.4) and (4.5) we can see that the supply voltage can have a significant impedance.
There are two ways to think about the role of decoupling capacitors: 1) In the time domain,
the decoupling capacitors supply a source of charge for transient loads and 2) in the frequency
domain, the decoupling capacitors provide a low impedance to the board to minimize ∆V . When
implementing decoupling capacitors, there are a few key design rules to keep in mind for minimizing
the inductance of the decoupling capacitors: 1) use short traces; 2) use surface mount parts; 3) be
careful with the size of vias on multi-layer boards and 4) might use many capacitors in parallel,
since L in parallel is reduced.
The following method is Dr. Jorgenson’s Method for choosing decoupling capacitors (both
bulk decoupling and chip decoupling):
If we are given Icc, rise time (tr) and frequency → f or 1/f = tclock, then based on i = C dVdt
⇒
C = i dtdV
we have
Cbulk =0.7Icctclock
dV(4.6)
75
and
Cchip =0.2IcctrdV
. (4.7)
76