ee155/255 green electronics - stanford...
TRANSCRIPT
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EE155/255 Green Electronics
Power Circuits10/4/17
Prof. William DallyComputer Systems Laboratory
Stanford University
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Course Logistics• HW2 due Monday 10/9• Lab groups have been formed• Lab1 signed off this week• Lab2 out
EE155/255 Lecture 4 - Power Circuits
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Course at a GlanceNo Date Topic HWout HWin Labout Labck Lab HW
1 9/25/17 Intro(basicconverters) 1 1 IntrotoST32F3 PeriodicSteadyState2 9/27/17 EmbeddedProg/PowerElect.3 10/2/17 PowerElectronics-1(switches) 2 1 2 1 ACEnergyMeter PowerDevices4 10/4/17 PowerElectronics-2(circuits)5 10/9/17 Photovoltaics 3 2 3 2 PVMPPT MotorcontrolMatlab6 10/11/17 FeedbackControl7 10/16/17 ElectricMotors 4 3 4 3 Motorcontrol-Lab/ Feedback8 10/18/17 IsolatedConverters9 10/23/17 SolarDay 5/PP 4 5 4 PS IsolatedConverters10 10/25/17 Magnetics11 10/30/17 SoftSwitching 6 5/PP 6 5 Magnetics MagneticsandInverters12 11/1/17 ProjectDiscussions13 11/6/17 Inverters,Grid,PF,andBatteries 6 P 6 Project14 11/8/17 Thermal&EMI15 11/13/17 QuizReview C116 11/15/17 Grounding,andDebuggingQ 11/15/17 Quiz-intheevening
11/20/17 ThanksgivingBreak C211/22/17 ThanksgivingBreak
17 11/27/17 Wrapup18 11/29/17 GuestLecture C319 12/4/17 GuestLecture20 12/6/17 NoClass
TBD Projectpresentations P12/15/17 Projectwebpagedue
EE155/255 Lecture 4 - Power Circuits
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Test SetupMulti-Level PV System
EE155/255 Lecture 4 - Power Circuits
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Prim
ary
and
Seco
ndar
y PC
Bs
EE155/255 Lecture 4 - Power Circuits
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Course to Date• We need sustainable energy systems• At the core they are voltage converters• Periodic steady-state analysis, buck and boost• Intelligent control + power path• Intelligent control done with event-driven embedded software• Real devices have switching and conduction loss – and parasitics
EE155/255 Lecture 4 - Power Circuits
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Last Time• DC and AC characteristics of MOSFETs, Diodes, and IGBTs• Switches in pairs• One switch does the work• Turn on transient• Diode reverse recovery• Parasitics• Gate drive and Miller capacitance
EE155/255 Lecture 4 - Power Circuits
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Turn-On and Turn-Off Loss
EE155/255 Lecture 4 - Power Circuits
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Turn-On Loss
EE155/255 Lecture 4 - Power Circuits
IP
ILQRR QD
ID
VDS
s
t1 t2 t3
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Turn-OffBuck with Diode
Excess current charges drain node.
Integrate to get switching energy
E =VDDtr16IL +
13I1
!
"#
$
%&
ID
VDS
IL
trtc
I1
EE155/255 Lecture 4 - Power Circuits
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Turn-OffBuck with Diode
If current ramps faster than voltage nearly ZVSID
VDS
IL
tr
tc
V1
E = 16V1ILtc
EE155/255 Lecture 4 - Power Circuits
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Parasitic Losses
LP
C2
CL
L1D1
M1
C1
EE155/255 Lecture 4 - Power Circuits
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Gate Drive
EE155/255 Lecture 4 - Power Circuits
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Gate Driver
RGH
RGL
M1
source
drain
Control &Protection+
-VGH
in
Gate-driver IC
SH
SL
EE155/255 Lecture 4 - Power Circuits
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Effect of Miller Cap on Rise Time
M1
iG
CDG
EE155/255 Lecture 4 - Power Circuits
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Effect of Miller Cap on Rise Time
M1
iG
CDG
dVDdt
=iGCDG
Δt = ΔVDCDG
iG
Example: i = 0.5A, C = 100pF, DV = 400V
EE155/255 Lecture 4 - Power Circuits
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Bootstrap Supply
M1
i
M2
V1
+-
High-SideGate Drive
Low-SideGate Drive
VGL
+-
inH
inL
GND
X
G1
G2
CB
RB DB V
EE155/255 Lecture 4 - Power Circuits
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Dead Time
EE155/255 Lecture 4 - Power Circuits
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Too Little Dead Time (11.6kW loss)
1.6µs 1.7µs 1.8µs 1.9µs 2.0µs 2.1µs 2.2µs 2.3µs 2.4µs 2.5µs 2.6µs 2.7µs 2.8µs 2.9µs 3.0µs 3.1µs 3.2µs-5V
0V
5V
10V
15V
20V
25V
30V
35V
40V
45V
50V0V
2V
4V
6V
8V
10V
12V
14V
16V-3.0KA
-2.5KA
-2.0KA
-1.5KA
-1.0KA
-0.5KA
0.0KA
0.5KA
1.0KA
1.5KA
2.0KA
2.5KA
3.0KA-10KW
0KW
10KW
20KW
30KW
40KW
50KW
60KW
70KW
80KW
90KW
100KW
110KW
V(m1)
V(p1l) v(p1h)-v(m1) V(1:gl) V(1:gh)-v(m1)
Ix(1:h:1) Ix(1:l:3)
ix(1:h:1)*(v(d)-v(m1)) ix(1:l:1)*v(m1)
4mJ3.4mJ
2500A
3.4mJ3.7mJ
EE155/255 Lecture 4 - Power Circuits
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0.6 0.8 1 1.2 1.4 1.6 1.8v G
(V)
0
10
0.6 0.8 1 1.2 1.4 1.6 1.8
v X (V
)
0
20
40
0.6 0.8 1 1.2 1.4 1.6 1.8
i M1 (k
A)
0
1
2
3
t (µ s)0.6 0.8 1 1.2 1.4 1.6 1.8
P M1 (k
W)
0
50
100
0
5
10
15
0
5
10
15
The “Real” Gate Signal
EE155/255 Lecture 4 - Power Circuits
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Too Much Dead-Time (340W loss)(Still pretty good)
1.6µs 1.7µs 1.8µs 1.9µs 2.0µs 2.1µs 2.2µs 2.3µs 2.4µs 2.5µs 2.6µs 2.7µs 2.8µs 2.9µs 3.0µs 3.1µs 3.2µs-5V
0V
5V
10V
15V
20V
25V
30V
35V
40V
45V
50V-2V
0V
2V
4V
6V
8V
10V
12V
14V
16V-700A
-600A
-500A-400A
-300A
-200A
-100A
0A100A
200A
300A
400A
500A600A
700A
800A-4KW
0KW
4KW
8KW
12KW
16KW
20KW
24KW
28KW
32KW
36KW
40KW
V(m2)
V(p2l) V(p2h)-v(m2) V(2:gl) V(2:gh)-v(m2)
Ix(2:h:1) Ix(2:l:3)
ix(2:h:1)*(v(d)-v(m2)) ix(2:l:1)*v(m2)
700mV diode drop
740A
0.27mJ
EE155/255 Lecture 4 - Power Circuits
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Just Right (310W loss)
1.6µs 1.7µs 1.8µs 1.9µs 2.0µs 2.1µs 2.2µs 2.3µs 2.4µs 2.5µs 2.6µs 2.7µs 2.8µs 2.9µs 3.0µs 3.1µs 3.2µs-5V
0V
5V
10V
15V
20V
25V
30V
35V
40V
45V
50V-2V
0V
2V
4V
6V
8V
10V
12V
14V
16V-350A
-280A
-210A
-140A
-70A
0A
70A
140A
210A
280A
350A
420A-0.3KW
0.0KW
0.3KW
0.6KW
0.9KW
1.2KW
1.5KW
1.8KW
2.1KW
2.4KW
2.7KW
V(m4)
V(p4l) v(p4h)-v(m4) v(4:gh)-v(m4) V(4:gl)
Ix(4:h:1) Ix(4:l:3)
IX(4:l:1)*v(m4) ix(4:h:1)*(v(d)-v(m1))
0.19mJ3uJ
Conduction loss is I2R = 502 x 1m ~ 25W
Slower gate rise
Short duration diode drop
EE155/255 Lecture 4 - Power Circuits
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Too much dead time is better than too little
EE155/255 Lecture 4 - Power Circuits
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Snubbers
EE155/255 Lecture 4 - Power Circuits
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LD
G 50V
+-
40A
RS
CS
D
Cj
M
Dampen Ringing Nodes
LD and Cj resonate when M is on
Parallel RS dampens tank
Series CS limits dissipation
EE155/255 Lecture 4 - Power Circuits
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Inductance on Drain
8uJ turn-on
42uJ turn-off
EE155/255 Lecture 4 - Power Circuits
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With Snubber (1nF, 5W)
8uJ turn-on
2uJ in snubber
42uJ turn-off
EE155/255 Lecture 4 - Power Circuits
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LD
G 50V
+-
40A
RS
CS
D
Cj
M
Design Procedure
Pick RS ~ 1/wCj
Pick CS so t >= p/w
OrEs = CSV2/2
EE155/255 Lecture 4 - Power Circuits
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Example Cycle
EE155/255 Lecture 4 - Power Circuits
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IGBT Half Bridge
EE155/255 Lecture 4 - Power Circuits
VS+-
GD
QH
QL
CCGH
GD
CCGL
DH
DL
SL
X
CH
RX
CX
IL
LSL
LS
![Page 31: EE155/255 Green Electronics - Stanford Universityweb.stanford.edu/class/ee152/lecture_slides/Power_Circuits_100417.pdfEE155/255 Green Electronics Power Circuits 10/4/17 Prof. William](https://reader035.vdocument.in/reader035/viewer/2022071406/60fd515b4fc4b639b978ebae/html5/thumbnails/31.jpg)
0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 20
50
i QH
(A)
0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2−20
0
20
40
i DL (A
)
0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 20
100
200
300
400
v x (V)
t (µs)
0
200
400
v CEH
(V)
One Switching Cycle
EE155/255 Lecture 4 - Power Circuits
1
2
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Turn-On Transient
EE155/255 Lecture 4 - Power Circuits
60 80 100 120 140 160 1800
50
i QH
(A)
60 80 100 120 140 160 180−20
0
20
40
i DL (A
)
60 80 100 120 140 160 1800
200
400
v X (V)
60 80 100 120 140 160 180390
400
410
v CH
(V)
60 80 100 120 140 160 180−10−5
05
1015
v GEH
(V)
t (ns)
0
200
400
v CEH
(V)
−20
0
20
40
i QL (A
)
0
10
20
P QH
(kW
)
−10−5051015
v GEL
(V)
1 2
2
𝐸~60𝑛𝑠×22𝑘𝑊
2 = 660µ𝐽
𝐸 = 773µ𝐽
𝐿𝑑𝑖𝑑𝑡
Hig
h-Si
de T
urn
On
![Page 33: EE155/255 Green Electronics - Stanford Universityweb.stanford.edu/class/ee152/lecture_slides/Power_Circuits_100417.pdfEE155/255 Green Electronics Power Circuits 10/4/17 Prof. William](https://reader035.vdocument.in/reader035/viewer/2022071406/60fd515b4fc4b639b978ebae/html5/thumbnails/33.jpg)
EE155/255 Lecture 4 - Power Circuits
Hig
h-Si
de T
urn
Off
1.55 1.6 1.65 1.7 1.750
20
40
i QH
(A)
1.55 1.6 1.65 1.7 1.750
10
20
30
40
i DL (A
)
1.55 1.6 1.65 1.7 1.750
200
400v X (V
)
1.55 1.6 1.65 1.7 1.75
400
405
410
415
v CH (V
)
t (µs)
0
200
400
v CEH
(V)
0
2
4
6
8
P QH
(kW
) 𝐸 = 230𝜇𝐽
𝐿𝑑𝑖𝑑𝑡
1
2
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Lab Half-Bridge Module
EE155/255 Lecture 4 - Power Circuits
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The Half-Bridge Module
1
2
Hin
IRS21834
ComVss
LO
S
HO
COM
Out
VDVB
M1
M2
R14.7
R24.7
U1
����
VCC
3
DT
GND
4
Hin
����
V12
C14.7 F
2.2 F200V
D356V5W
D1
R3 1
C21 F
VBCSupply
VDCFilter
D215V
C3
7
6
5
13
12
11
EE155/255 Lecture 4 - Power Circuits
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Bootstrap Supply
1
2
Hin
IRS21834
ComVss
LO
S
HO
COM
Out
VDVB
M1
M2
R14.7
R24.7
U1
����
VCC
3
DT
GND
4
Hin
����
V12
C14.7 F
2.2 F200V
D356V5W
D1
R3 1
C21 F
VBCSupply
VDCFilter
D215V
C3
7
6
5
13
12
11
EE155/255 Lecture 4 - Power Circuits
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Bootstrap Supply
EE155/255 Lecture 4 - Power Circuits
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Drain Voltage Filter
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EE155/255 Lecture 4 - Power Circuits
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Drain Voltage Filter300nH Input Inductance
EE155/255 Lecture 4 - Power Circuits
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SPICE
EE155/255 Lecture 4 - Power Circuits
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SPICE Example – A Voltage Doubler
EE155/255 Lecture 4 - Power Circuits
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A Voltage Doubler* Simple voltage "doubler".include "gel.lib".param td=100n tr=100n tf=100n tw=2.5u tcy=5u ncy=2.param l1=22uH c1=10uF r1=10
* call half-bridge subcircuitxhb vd mid g g 0 v12 gel_hb
* circuitl1 vin mid {l1}c1 vd 0 {c1}r1 vd 0 {r1}
* suppliesv12 v12 0 12vin vin 0 24
* stimulusVG g 0 PULSE(0 5 {td} {tr} {tf} {tw} {tcy} {ncy})
.ic i(l1)=9.2
.ic v(vd)=42.8
.tran {ncy*tcy}
EE155/255 Lecture 4 - Power Circuits
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Turn-On Transient
EE155/255 Lecture 4 - Power Circuits
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Steady State
EE155/255 Lecture 4 - Power Circuits
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Close up of Drain Current
EE155/255 Lecture 4 - Power Circuits
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With PID Control
EE155/255 Lecture 4 - Power Circuits
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A Warning• SPICE (or any simulator) is a Verification tool, not a Design tool• Design your circuit first
– Use Excel, Matlab, a calculator etc… to calculate component values• Then simulate your circuit to check operation and fine-tune parameters• Don’t try to design your circuit using SPICE
• Simulation is not a substitute for thinking
EE155/255 Lecture 4 - Power Circuits
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Summary of Power Circuits• Real switches have limitations
– Conduction losses (RON for FETs, VCE for IGBTs, Diode drop)– Switching losses (finite ton, toff, trr)
• With current source load, current ramps, then voltage falls • And voltage rises before current falls• May be dominated by reverse recovery time• Complicated by inductance
– Parasitic L and C• Power MOSFETs
– Switch quickly, have linear I-V, integral diode• IGBTs
– Diode-like I-V, slower switching• Diodes
– Have reverse recovery time• Switches operate in pairs
– For one-way converters, one switch may be a diode– Synchronous rectification – make both switches FETs to reduce loss– Need “dead time” to avoid “shoot through” current
• Gate-drive circuits control rise and fall times– Supply Miller capacitance
• Bootstrap supply needed for high-side driver• Snubbers dampen voltage and current transients• Use SPICE as a verification tool, not a design tool
EE155/255 Lecture 4 - Power Circuits
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Course at a GlanceNo Date Topic HWout HWin Labout Labck Lab HW
1 9/25/17 Intro(basicconverters) 1 1 IntrotoST32F3 PeriodicSteadyState2 9/27/17 EmbeddedProg/PowerElect.3 10/2/17 PowerElectronics-1(switches) 2 1 2 1 ACEnergyMeter PowerDevices4 10/4/17 PowerElectronics-2(circuits)5 10/9/17 Photovoltaics 3 2 3 2 PVMPPT MotorcontrolMatlab6 10/11/17 FeedbackControl7 10/16/17 ElectricMotors 4 3 4 3 Motorcontrol-Lab/ Feedback8 10/18/17 IsolatedConverters9 10/23/17 SolarDay 5/PP 4 5 4 PS IsolatedConverters10 10/25/17 Magnetics11 10/30/17 SoftSwitching 6 5/PP 6 5 Magnetics MagneticsandInverters12 11/1/17 ProjectDiscussions13 11/6/17 Inverters,Grid,PF,andBatteries 6 P 6 Project14 11/8/17 Thermal&EMI15 11/13/17 QuizReview C116 11/15/17 Grounding,andDebuggingQ 11/15/17 Quiz-intheevening
11/20/17 ThanksgivingBreak C211/22/17 ThanksgivingBreak
17 11/27/17 Wrapup18 11/29/17 GuestLecture C319 12/4/17 GuestLecture20 12/6/17 NoClass
TBD Projectpresentations P12/15/17 Projectwebpagedue
EE155/255 Lecture 4 - Power Circuits