EUPEC 2ED020I12-F

Datasheet and Application
Prepared by: Andreas Volke
Approved by: Michael Hornkamp
S/N: 010-04
Date of publication: 2003-12-05
Status: Target Data
EiceDRIVER
2ED020I12-F
Dual IGBT Driver IC
for eupec Low and Medium Power IGBT Modules
eupec GmbH
Max-Planck-Straße 5
D-59581 Warstein
Tel. +49 (0) 29 02 7 64-0
Fax + 49 (0) 29 02 7 64-12 56
[email protected]
www.eupec.com
www.eicedriver.com
Author: Andreas Volke
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
0
History
Revision 1.0
Revision 1.2
Revision 1.5
2003-01-24
2003-05-16
2003-12-05
First release
Updated electrical characteristics
New paper design
Updated functional description
Updated electrical characteristics
New chapter “Diagrams”
New chapter “Applications”
For questions on technology, delivery and prices please contact the eupec offices in Germany or the eupec companies and representatives
worldwide:
See our web pages at http://www.eupec.com and http://www.eicedriver.com
Published by
eupec GmbH,
Max-Planck-Str. 5,
D-59581 Warstein
© eupec GmbH 2003. All Rights Reserved.
Attention please!
The information herein is given to describe certain components and shall not be considered as warranted characteristics.
Terms of delivery and rights to technical change reserved.
We hereby disclaim any and all warranties, including but not limited to warranties of non-infringement, regarding circuits, descriptions and
charts stated herein.
eupec GmbH is an approved CECC manufacturer.
Information
For further information on technology, delivery terms, conditions and prices please contact your nearest eupec office in Germany or our eupec
representatives worldwide.
Warnings
Due to technical requirements components may contain dangerous substances. For information on the types in question please contact your
nearest eupec office.
eupec components may only be used in life-support devices or systems with the express written approval of eupec, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system, or to affect the safety or effectiveness of that
device or system. Life support devices or systems are intended to be implanted in the human body, or to support and/or maintain and sustain
and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may be endangered.
Exclusion Clause
The eupec IGBT driver 2ED020I12-F is only intended for control of eupec IGBT modules. The company eupec GmbH cannot warrant against
damage and/or dysfunction if IGBT modules used not produced by eupec.
www.eupec.com - www.eicedriver.com
Page 2/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
Table of Contents
0
History.................................................................................................................................................................................2
1
Overview.............................................................................................................................................................................4
1.1
Coreless transformer (CLT) technology....................................................................................................................4
2
Pin configuration and package outline ................................................................................................................................6
3
Block diagram .....................................................................................................................................................................7
4
Functional description .........................................................................................................................................................8
4.1
Power supply ............................................................................................................................................................8
4.2
Logic inputs ..............................................................................................................................................................8
4.2.1
5
Gate driver ...........................................................................................................................................................8
4.3
General purpose operational amplifier......................................................................................................................8
4.4
General purpose comparator....................................................................................................................................8
4.5
CLT...........................................................................................................................................................................8
Electrical parameters ..........................................................................................................................................................9
5.1
Absolute maximum ratings .......................................................................................................................................9
5.2
Operating range......................................................................................................................................................10
5.3
Electrical characteristics .........................................................................................................................................10
5.3.1
Voltage Supply...................................................................................................................................................10
5.3.2
Logic inputs .......................................................................................................................................................11
5.3.3
Gate drivers .......................................................................................................................................................11
5.3.4
Dynamic characteristics .....................................................................................................................................11
5.3.5
General purpose operational amplifier...............................................................................................................12
5.3.6
General purpose comparator .............................................................................................................................12
6
Diagrams ..........................................................................................................................................................................13
7
Application Notes..............................................................................................................................................................15
7.1
Power Supply .........................................................................................................................................................15
7.2
Ground reference ...................................................................................................................................................15
7.3
Operational Amplifier ..............................................................................................................................................16
7.4
Comparator ............................................................................................................................................................17
7.5
Logic inputs ............................................................................................................................................................18
www.eupec.com - www.eicedriver.com
Page 3/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
1
Overview
The 2ED020I12-F is a high voltage, high speed power IGBT and MOSFET driver of the eupec EiceDRIVER™ family with
interlocking high and low side referenced output channels. The floating high side driver may be supplied directly or by means
of a bootstrap diode and capacitor. In addition to the logic input of each driver the 2ED020I12-F is equipped with a dedicated
shutdown input. All logic inputs are compatible with 3.3 V and 5 V TTL. The output drivers feature a high pulse current buffer
stage designed for minimum driver cross-conduction. Propagation delays are matched to simplify use in high frequency applications. Both drivers are designed to drive an n-channel power IGBT or MOSFET which operates up to 1200 V. In addition, a
general purpose operational amplifier and a general purpose comparator are provided, which may be used e.g. for current
measurement or over current detection.
Product Highlights
• Fully operational to ±1200 V
• Gate drive supply range from 13 to 18 V
• Gate drive currents of +1 A / –2 A
• Matched propagation delay for both channels
• High dV/dt immunity
• General purpose operational amplifier
• General purpose comparator
Features
• Floating high side driver
• Under-voltage lockout for both channels
• 3.3 V and 5 V TTL compatible inputs
• CMOS Schmitt-triggered inputs with internal pull-down
• CMOS Schmitt-triggered shutdown with internal pull-up
• Non-inverting inputs
• Interlocking inputs
• Dedicated shutdown input with internal pull-up
• IEC compliant (pending)
• UL recognized (pending)
1.1
Coreless transformer (CLT) technology
In various IGBT and power MOSFET driver stages are optocoupler, level shifter or discrete transformer included to overcome
the isolation barrier between the low side input and high side output. All of them have their typical advantages and disadvantages. As an alternative for low and medium power applications the coreless transformer technology combines almost all
advantages and at the same time avoiding almost all disadvantages of these devices by a very cost efficient way and high
voltage isolation capability.
The principle function of the CLT is realized by two coils which are compounded on silicon within one integrated circuit. The
isolation between these coils can withstand in the current design at least up to 1200 V whereby a functional isolation is
achieved. Figure 1 shows a schematic of the internal stages of the IC.
Figure 1
IC schematic
www.eupec.com - www.eicedriver.com
Page 4/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
Each EiceDRIVER™ has a type number, which can be resolved by the following schemata:
EiceDRIVER™ 2 ED 020 I 12 - F
Isolation class
F = Function isolation
S = Safety isolation
ST = Safety isolation / Traction application
Voltage class:
06 = 600 V
12 = 1200 V
17 = 1700 V
33 = 3300 V
65 = 6500 V
Type:
C = Board
I = IC (Coreless Transformer)
L = IC (Level Shifter)
Peak output current for Driver:
020 = 2 A
300 = 30 A
Maximum Sampling Rate for ADC/DC
Function:
EC = Analog-Digital-Converter/Digital-Coupler
ED = IGBT/MOSFET Driver
Driver Channels:
1 = Driver for one IGBT
2 = Driver for Half-Bridge
6 = Driver for Six-Pack
ADC/DC Channels:
1 = Single Input/Single Output
www.eupec.com - www.eicedriver.com
Page 5/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
2
Pin configuration and package outline
P-DSO-18-1 (300 mil)
1)
2)
Figure 2
Pin
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
Pin configuration (top view)
Symbol
InH
InL
/SD
GND
/CPO
CPCP+
OPO
OPOP+
GNDL
OutL
VS
n.c.
n.e.
n.e.
GNDH
VSLH
OutH
GNDH
Does not include plastic or metal protrusions of 0.15 max per side
Does not include dambar protrusion of 0.05 max per side
Figure 3
Package outline (all measures in mm)
Function
Logic input for high side driver
Logic input for low side driver
Logic input for shutdown of both drivers
Common ground
Open drain output of general purpose comparator
Inverting input of general purpose comparator
Non-inverting input of general purpose comparator
Output of general purpose operational amplifier
Inverting input of general purpose operational amplifier
Non-inverting input of general purpose operational amplifier
Low side supply ground
Low side gate driver output
Low side supply voltage
(not connected)
(not existing)
(not existing)
High side supply ground
High side supply voltage
High side gate driver output
High side supply ground
www.eupec.com - www.eicedriver.com
Page 6/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
3
Block diagram
Figure 4
Block diagram
www.eupec.com - www.eicedriver.com
Page 7/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
4
4.1
Functional description
Power supply
The power supply of both sides, VSL and VSH, is monitored by an under-voltage lockout block (UVLO) which enables operation of the corresponding side when the supply voltage reaches the “on” threshold of 12 V. Afterwards the internal voltage
reference and the biasing circuit are enabled. When the supply voltage (VSL, VSH) drops below the “off” threshold of 11 V the
circuit is disabled.
4.2
Logic inputs
The logic inputs InH, InL and /SD are fed into Schmitt-Triggers with thresholds compatible to 3.3 V and 5 V TTL. When /SD is
enabled (low), InH and InL are disabled. If InH is high (while InL is low), OutH is enabled and vice versa. However, if both
signals are high, they are internally disabled until both signals get low again. This is due to the interlocking logic of the device
(see also Figure 5).
4.3
Gate driver
2ED020I12-F features two hard-switching gate drivers with n-channel output stages capable to source 1 A and to sink 2 A
peak current. Both drivers are equipped with active-low-clamping capability. Furthermore, they feature a large ground bounce
ruggedness in order to compensate ground bounces caused by a turn-off of the driven IGBT.
4.4
General purpose operational amplifier
This general purpose operational amplifier can be applied for current measurement of the driven low-side IGBT. It is dedicated for fast operation with a gain of at least 10. The OP is equipped with a -0.1 V to 2 V input stage and a rail-to-rail output
stage which is capable to drive ±5 mA and is dedicated to drive an A/D converter.
4.5
General purpose comparator
The general purpose comparator can be applied for over-current detection of the low side IGBT. A dedicated offset as well as
a pull-up and pull-down resistor has been introduced to its inputs for security reasons.
4.6
CLT
In order to enable signal transmission across the isolation barrier between low-side and high-side driver, a coreless transformer is employed. Signals, that are to be transmitted, are specially encoded by the transmitter and correspondingly restored
by the receiver. In this way EMI due to variations of GNDH (dVGNDH/dt) or the magnetic flux (dΦ/dt) can be suppressed. To
compensate the additional propagation delay of transmitter, coreless transformer and receiver, a dedicated propagation delay
is introduced into the low-side driver.
www.eupec.com - www.eicedriver.com
Page 8/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
5
5.1
Electrical parameters
Absolute maximum ratings
Absolute maximum ratings are defined as ratings, which when being exceeded may lead to destruction of the integrated circuit. Unless otherwise noted all parameters refer to GND. The pins GND and GNDL have to be connected externally through the shortest possible way.
Parameter
High side ground
High side supply voltage
High side gate driver output
Low side ground
Low side supply voltage
Low side gate driver output
Logic input voltages
(InH, InL, /SD)
OP input voltages
(OP-, OP+)
OP output voltage
CP input voltages
(CP-, CP+)
CP output voltage
CP output max. sink current
High side ground, voltage transient
Package power dissipation
@TA=25°C
Thermal resistance (both chips
active), junction to ambient
Thermal resistance (high side
chip), junction to ambient
Thermal resistance (low side
chip), junction to ambient
Junction temperature
Storage temperature
VGNDH
VVSH
VOutH
VGNDL
VVSL
VOutL
VIn
Limit values
min.
-1200
-0.3
-0.3
-0.3
-0.3
-0.3
-0.3
max.
1200
20
VVSH + 0.3
5.3
20
VVSL + 0.3
5.3
V
V
V
V
V
V
V
VOP
-0.3
5.3
V
VOPO
VCP
-0.3
-0.3
5.3
5.3
V
V
V/CPO
I/CPO
dVGNDH/dt
-0.3

-50
5.3
5
50
V
mA
V/ns
PD

2
W
5)
RTHJA

60
K/W
6)
RTHJA(HS)

110
K/W
6)
RTHJA(LS)

110
K/W
6)
TJ
TS

-55
150
150
°C
°C
Symbol
Unit
Remark
1)
1)
2)
3)
4)
4)
1)
with reference to high side GNDH
with reference to both GND and GNDL
3)
with reference to low side ground GNDL
4)
please note the different specifications for the operating range
5)
considering RTHJA = 60 K/W, e.g. both chips active
6)
device soldered to reference PCB without cooling area
2)
www.eupec.com - www.eicedriver.com
Page 9/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
5.2
Operating range
Within the operating range the IC operates as described in the functional description. Unless otherwise noted all parameters refer to GND.
Parameter
High side ground
High side supply voltage
Low side supply voltage
Logic input voltages
(InH, InL, /SD)
OP input voltages
(OP-, OP+)
CP input voltages
(CP-, CP+)
Ambient temperature
Symbol
Unit
VGNDH
VVSH
VVSL
VIn
Limit values
min.
-1200
13
13
0
max.
1200
18
18
5
V
V
V
V
VOP
-0.1
2
V
VCP
-0.1
2
V
TA
-40
105
°C
Remark
1)
2)
1)
with reference to high side ground GNDH
2)
with reference to both GND and GNDL
5.3
Electrical characteristics
The electrical characteristics involve the spread of values for the supply voltages, load and junction temperature given below. Typical values
represent the median values, which are related to production processes. Unless otherwise noted all voltages are given with respect to ground
(GND).
1)
VSL = 15 V, VSH = 15 V , CL = 1 nF, TA = 25°C. Positive currents are assumed to be flowing into pins.
5.3.1
Voltage Supply
Parameter
1)
Symbol
Limit Values
min.
typ.


Unit
Test condition
max.
1
µA
1.7

12

500
tbd
mA
µA
V
VGNDH = 1.2 kV
VGNDL = 0 V
1)
VVSH = 15 V
1)
VVSH = 10 V
High side leakage current
IGNDH
High side quiescent supply current
IVSH
High side under-voltage lockout,
upper threshold
High side under-voltage lockout
hysteresis
Low side quiescent supply current
VVSH1)


tbd
∆VVSH
tbd
1
tbd
V
IVSL
Low side under-voltage lockout,
upper threshold
Low side under-voltage lockout
hysteresis
VVSL


tbd
2.4

12

500
tbd
mA
µA
V
∆VVSL
tbd
1
tbd
V
VVSL = 15 V
VVSL = 10 V
with reference to high side ground GNDH
www.eupec.com - www.eicedriver.com
Page 10/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
5.3.2
Logic inputs
Parameter
Logic “1” input voltages
(InH, InL, /SD)
Logic “0” input voltages
(InH, InL, /SD)
Logic input voltages hystersis
(InH, InL, /SD)
Logic “1” input current
(InH, InL)
Logic “0” input current
(InH, InL)
Logic “1” input current
(/SD)
Logic “0” input current
(/SD)
5.3.3
VIn
Limit Values
min.
typ.
2

max.

V
VIn


0.8
V
∆VIn

0.6

V
IIn

40
tbd
µA
VIn = 5 V
IIn

0

µA
VIn = 0 V
IIn

0

µA
VIn = 5 V
IIn
tbd
-40

µA
VIn = 0 V
Symbol
Test condition
Gate drivers
High side high level output voltage
VVSH – VOutH
Limit Values
min.
typ.
1.4

High side low level output voltage
VOutH1)


0.1
V
Low side high level output voltage
VVSL – VOutL

1.4
tbd
V
Low side low level output voltage
VOutL


0.1
V
Output high peak current
(OutL, OutH)
Output low peak current
(OutL, OutH)
High side active low clamping
IOut


-1
A
IOut
2


A
VOutH1)


3
V
Low side active low clamping
VOutL


3
V
Parameter
1)
Unit
Symbol
Unit
Test condition
max.
tbd
V
IOutH = -1 mA
VInH = 5 V
IOutH = 1 mA
VInH = 0 V
IOutH = -1 mA
VInH = 0 V
IOutH = 1 mA
VInH = 0 V
VIn = 5 V
VOut = 0 V
VIn = 0 V
VOut = 15 V
VInH = 0V
VSH open
IOutH = 200 mA
VInL = 0V
VSL open
IOutL = 200 mA
with reference to high side ground GNDH
5.3.4
Dynamic characteristics
Parameter
Turn-on propagation delay
Turn-off propagation delay
Shutdown propagation delay
Turn-on rise time
Turn-off rise time
Delay mismatch (high and low side
turn-on/off)
Symbol
ton
toff
t/SD
tr
tf
∆t
Limit Values
min.
typ.
50

50

50

40

40

-10
0
www.eupec.com - www.eicedriver.com
max.
tbd
tbd
tbd
tbd
tbd
10
Unit
Test condition
ns
ns
ns
ns
ns
ns
ref. to Figure 6
ref. to Figure 6
ref. to Figure 7
ref. to Figure 6
ref. to Figure 6
ref. to Figure 8
Page 11/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
5.3.5
General purpose operational amplifier
OP input offset voltage
OP input offset voltage drift
OP input high currents
(OP-, OP+)
OP input high currents
(OP-, OP+)
OP high output voltage
∆VIn
VDrift
IIn
Limit Values
min.
typ.
-15
0
tbd
tbd
0

IIn
-5
0

µA
VIn = 0 V
VOPO
4.9


V
OP low output voltage
VOPO


0.1
V
OP output source current
IOPO


-5
mA
OP output sink current
IOPO
5


mA
VOP- = 0 V
VOP+ = 2 V
VOP- = 2 V
VOP+ = 0 V
VOP+ = 2 V
VOP- = 0 V
VOPO = 0V
VOP+ = 0 V
VOP- = 2 V
VOPO = 5V
OP open loop gain
OP gain-bandwidth product
OP phase margin
AOL
A x BW
Φ



120
60
70



dB
MHz
°
Symbol
Unit
Test condition
max.



0.2
mV
µA
µA
V
VCP+ = VCPVCP- = 5 V
VCP+ = 0 V
VCP+ = 2 V
I/CPO = 1 mA
VCP+ = 0 V
VCP- = 2 V
V/CPO = 5 V
R/CPO = 4.7 kΩ
Vres = 5 V
V/CPO = 0.8 V
R/CPO = 4.7 kΩ
Vres = 5 V
V/CPO = 2 V
Parameter
1)
2)
Symbol
Unit
Test condition
max.
15
tbd
5
mV
µV/K
µA
VIn = 2 V
1)
1), 2)
design value
the minimum gain A ≥ 10 is recommended
5.3.6
General purpose comparator
CP input offset voltage
CP input high current
CP input low current
CP low output voltage
∆VIn
ICPICP+
V/CPO
Limit Values
min.
typ.
-30

20

-20



CP output leakage current
I/CPO


5
µA
CP switch-on delay
td

100

ns
CP switch-off delay
td

300

ns
Parameter
www.eupec.com - www.eicedriver.com
Page 12/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
6
Diagrams
InH
InL
/SD
OutH
OutL
Figure 5
Input/Output timing diagram
Figure 6
Switching time waveform definition
Figure 8
Delay matching waveform definitions
Figure 7
www.eupec.com - www.eicedriver.com
Shutdown waveform definition
Page 13/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
Junction Temperature [°C]
FS75R12KM4 (Rg = 2.4 Ω, VDC-Link = 100 V)
Frequency [kHz]
Figure 9
Junction Temperature vs. Frequency (VVSH = VVSL = 15 V, TA = 25°C)
www.eupec.com - www.eicedriver.com
Page 14/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
7
7.1
Application Notes
Power Supply
The floating high side driver may be supplied directly or by means of a bootstrap diode and capacitor. Either way, for a correct
power-up it is recommended to put at the pins VSH and VSL an electrolytic or tantalum capacitor and additionally a ceramic
capacitor of approximately 100 nF. The size of the electrolytic or tantalum capacitor depends on the gate capacitances of the
driven IGBT or MOSFET, the switching frequency and additional gate resistors and/or capacitors.
For a safe start-up with a bootstrap diode and capacitor it is recommended first to switch on the low-side IGBT. Thus, the
capacitor can be charged through the diode and provides sufficient gate voltage.
Figure 10
7.2
Bootstrap circuit
Ground reference
The pins GND and GNDL have to be connected externally through the shortest possible way. Thus, different ground references result for different applications as shown for instance in Figure 11.
Figure 11
Ground reference
www.eupec.com - www.eicedriver.com
Page 15/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
7.3
Operational Amplifier
To minimize the current consumption when the operational amplifier is not used, it is necessary to connect both inputs properly. For instance connect pin OP+ to 5 V and pin OP- to 0 V or vice versa.
Figure 12
OPA not used
The operational amplifier is designed to operate with a minimum gain of 10, so that its output OPO has a stable behavior.
Figure 13
Minimum OPA gain
www.eupec.com - www.eicedriver.com
Page 16/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
7.4
Comparator
The comparator has a designed input offset voltage of typical -30 mV to prioritize the CP+ input against the CP- input. If both
input signals have the same potential, the output /CPO goes to low impedance.
In the following some example circuits using the general purpose comparator:
Figure 14
Over-current detection
Figure 15
Figure 16
Over-current detection with Window Comparator
www.eupec.com - www.eicedriver.com
Comparator with hysteresis
Page 17/18
Datasheet and Application
EiceDRIVER™ 2ED020I12-F
7.5
Logic inputs
The input pins InH, InL and /SD should be protected against EMI by ceramic capacitors according to Figure 17.
Figure 17
Logic inputs
eupec Headquarter
eupec GmbH
Max-Planck-Strasse 5
D-59581 Warstein
Phone +49 2902 764-0
Fax
+49 2902 1256
[email protected]
www.eupec.com - www.eicedriver.com
Page 18/18