GA03JT12-247 - GeneSiC Semiconductor

GA03JT12-247
Normally – OFF Silicon Carbide
Junction Transistor
VDS
RDS(ON)
ID @ Tc=150°C
hFE Tc=25°C
Features
Package
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 RoHS Compliant
175 °C Maximum Operating Temperature
Gate Oxide Free SiC Switch
Exceptional Safe Operating Area
Excellent Gain Linearity
Temperature Independent Switching Performance
Low Output Capacitance
Positive Temperature Coefficient of RDS,ON
Suitable for Connecting an Anti-parallel Diode
D
=
=
=
=
1200 V
470 mΩ
3A
54
D
G
D
G
S
S
TO-247AB
Advantages
Applications
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Compatible with Si MOSFET/IGBT Gate Drive ICs
> 20 µs Short-Circuit Withstand Capability
Lowest-in-class Conduction Losses
High Circuit Efficiency
Minimal Input Signal Distortion
High Amplifier Bandwidth
Down Hole Oil Drilling, Geothermal Instrumentation
Hybrid Electric Vehicles (HEV)
Solar Inverters
Switched-Mode Power Supply (SMPS)
Power Factor Correction (PFC)
Induction Heating
Uninterruptible Power Supply (UPS)
Motor Drives
Absolute Maximum Ratings
Parameter
Drain – Source Voltage
Continuous Drain Current
Continuous Gate Current
Symbol
VDS
ID
IGM
Turn-Off Safe Operating Area
RBSOA
Short Circuit Safe Operating Area
SCSOA
Reverse Gate – Source Voltage
Reverse Drain – Source Voltage
Power Dissipation
Storage Temperature
VSG
VSD
Ptot
Tstg
Conditions
VGS = 0 V
TC = 150 °C
TVJ = 175 oC, IG = 1 A,
Clamped Inductive Load
TVJ = 175 oC, IG = 1 A, VDS = 800 V,
Non Repetitive
TC = 150 °C
Value
1200
3
1
ID,max = 3
@ VDS ≤ VDSmax
Unit
V
A
A
Notes
Fig. 6
Fig. 19
A
Fig. 16
20
µs
30
25
15
-55 to 175
V
V
W
°C
Fig. 14
Electrical Characteristics
Parameter
Symbol
Conditions
Drain – Source On Resistance
RDS(ON)
ID = 3 A, Tj = 25 °C
ID = 3 A, Tj = 125 °C
ID = 3 A, Tj = 175 °C
Gate Forward Voltage
VGS(FWD)
IG = 500 mA, Tj = 25 °C
IG = 500 mA, Tj = 175 °C
hFE
VDS = 5 V, ID = 3 A, Tj = 25 °C
VDS = 5 V, ID = 3 A, Tj = 175 °C
Drain Leakage Current
IDSS
VR = 1200 V, VGS = 0 V, Tj = 25 °C
VR = 1200 V, VGS = 0 V, Tj = 125 °C
VR = 1200 V, VGS = 0 V, Tj = 175 °C
Gate Leakage Current
ISG
VSG = 20 V, Tj = 25 °C
Min.
Value
Typical
Max.
Unit
Notes
mΩ
Fig. 5
V
Fig. 4
–
Fig. 5
μA
Fig. 6
On State Characteristics DC Current Gain
470
530
730
3.3
3.1
54
32
Off State Characteristics Aug 2014
0.1
0.2
0.5
20
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10
50
100
nA
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Electrical Characteristics
Parameter
Symbol
Conditions
Ciss
Crss/Coss
EOSS
VGS = 0 V, VD = 800 V, f = 1 MHz
VD = 800 V, f = 1 MHz
VGS = 0 V, VD = 1000 V, f = 1 MHz
RG(INT-ZERO)
RG(INT-ON)
td(on)
tf
td(off)
tr
td(on)
tf
td(off)
tr
Eon
Eoff
Etot
Eon
Eoff
Etot
f = 1 MHz, VAC = 25 mV, Tj = 175 ºC
VGS > 2.5 V
Min.
Value
Typical
Unit
Notes
315
15
6.1
pF
pF
µJ
Fig. 7
Fig. 7
Fig. 8
18.0
0.9
17
20
29
30
14
19
23
33
84
9
93
79
10
89
Ω
Ω
ns
ns
ns
ns
ns
ns
ns
ns
µJ
µJ
µJ
µJ
µJ
µJ
1.64
°C/W
Max.
Capacitance Characteristics Input Capacitance
Reverse Transfer/Output Capacitance
Output Capacitance Stored Energy
Switching Characteristics1 Internal Gate Resistance, Zero Bias
Internal Gate Resistance, On
Turn On Delay Time
Fall Time, VDS
Turn Off Delay Time
Rise Time, VDS
Turn On Delay Time
Fall Time, VDS
Turn Off Delay Time
Rise Time, VDS
Turn-On Energy Per Pulse
Turn-Off Energy Per Pulse
Total Switching Energy
Turn-On Energy Per Pulse
Turn-Off Energy Per Pulse
Total Switching Energy
1
Tj = 25 ºC, VDS = 800 V, ID = 3 A,
RG(EXT) = 40 Ω, CG = 9 nF,
VG = 25/-5 V, Load = 267 Ω
Refer to Fig. 20 for IG Waveform
Tj = 175 ºC, VDS = 800 V, ID = 3 A,
RG(EXT) = 40 Ω, CG = 9 nF,
VG = 25/-5 V, Load = 267 Ω
Refer to Fig. 20 for IG Waveform
Tj = 25 ºC, VDS = 800 V, ID = 3 A,
RG(EXT) = 40 Ω, CG = 9 nF,
VG = 25/-5 V, Load = 1.05 mH
Tj = 175 ºC, VDS = 800 V, ID = 3 A,
RG(EXT) = 40 Ω, CG = 9 nF,
VG = 25/-5 V, Load = 1.05 mH
Fig. 9, 11
Fig. 10, 12
Fig. 9
Fig. 10
Fig. 9, 11
Fig. 10, 12
Fig. 9
Fig. 10
– All times are relative to the Drain-Source Voltage VDS
Thermal Characteristics Thermal resistance, junction - case
RthJC
Fig. 17
Figures
Figure 1: Typical Output Characteristics at 25 °C
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Figure 2: Typical Output Characteristics at 125 °C
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Figure 3: Typical Output Characteristics at 175 °C
Figure 4: Typical Gate Source I-V Characteristics vs.
Temperature
Figure 5: Normalized On-Resistance and Current Gain vs.
Temperature
Figure 6: Typical Blocking Characteristics
Figure 7: Input, Output, and Reverse Transfer Capacitance
Figure 8: Output Capacitance Stored Energy
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2
Figure 9: Typical Turn On Energy Losses and Switching
Times vs. Temperature
Figure 10: Typical Turn Off Energy Losses and Switching
Times vs. Temperature
Figure 11: Typical Turn On Energy Losses and Switching
Times vs. Drain Current
Figure 12: Typical Turn Off Energy Losses and Switching
Times vs. Drain Current
Figure 13: Typical Hard Switched Device Power Loss vs.
2
Switching Frequency
Figure 14: Power Derating Curve
– Representative values based on device switching energy loss. Actual losses will depend on gate drive conditions, device load, and circuit topology.
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Figure 15: Forward Bias Safe Operating Area at Tc = 25 °C
Figure 16: Turn-Off Safe Operating Area
Figure 17: Transient Thermal Impedance
Figure 18: Drain Current Derating vs. Pulse Width
Figure 19: Drain Current Derating vs. Temperature
Figure 20: Typical Gate Current Waveform
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Driving the GA03JT12-247
A: Gate Drive Theory of Operation
The SJT is a current controlled transistor which requires a positive gate current for turn-on as well as to remain in on-state. An ideal gate
current waveform for ultra-fast switching of the SJT, while maintaining low gate drive losses, is shown in Figure 21.
Figure 21: Idealized Gate Current Waveform A:1: Gate Currents, IG,pk/-IG,pk and Voltages during Turn-On and Turn-Off
An SJT is rapidly switched from its blocking state to on-state, when the necessary gate charge, QG, for turn-on is supplied by a burst of high
gate current, IG,on, until the gate-source capacitance, CGS, and gate-drain capacitance, CGD, are fully charged.
,
The IG,pon pulse should ideally terminate, when the drain voltage falls to its on-state value, in order to avoid unnecessary drive losses during
the steady on-state. In practice, the rise time of the IG,on pulse is affected by the parasitic inductances, Lpar in the TO-247 package and drive
circuit. A voltage developed across the parasitic inductance in the source path, Ls, can de-bias the gate-source junction, when high drain
currents begin to flow through the device. The applied gate voltage should be maintained high enough, above the VGS,ON level to counter
these effects.
A high negative peak current, -IG,off is recommended at the start of the turn-off transition, in order to rapidly sweep out the injected carriers from
the gate, and achieve rapid turn-off. While satisfactory turn off can be achieved with VGS = 0 V, a negative gate voltage VGS may be used in
order to speed up the turn-off transition.
A:2: Steady On-State
After the device is turned on, IG may be advantageously lowered to IG,steady for reducing unnecessary gate drive losses. The IG,steady is
determined by noting the DC current gain, hFE, of the device.
The desired IG,steady is determined by the peak device junction temperature TJ during operation, drain current ID, DC current gain hFE, and a
50 % safety margin to ensure operating the device in the saturation region with low on-state voltage drop by the equation:
,
,
1.5
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Pg6 of 10 GA03JT12-247
B: Gate Drive Implementation Examples
B:1: Using the IXYS IX2204 Gate Driver
The IXYS IX2204 is a dual output gate drive integrated circuit which can be used to drive an SJT by supplying the required gate drive current
IG in a low-power gate drive solution. This configuration features an external gate capacitor, CG, which creates the brief current peak IG,on
during device turn-on and IG,off during turn-off for fast switching and an external gate resistor RG(EXT) to set the continuous gate current IG,steady
required for the device to remain on. This configuration is shown in Figure 1 with further details provided below.
Figure 1: Gate drive configuration using an IXYS IX2204 gate drive IC.
Table 1: Recommended Component List for implementing the IX2204 based Gate Drive for the GA03JT12-247
Reference
Component
RG(EXT)
CG
RCG
DRG
Rb
QHA, QHB
QLA, QLB
U1
Gate Resistance, External
Gate Capacitance
Damping Resistor
Silicon Schottky Diode
BJT Base Resistor
Current Boost NPN
Current Boost PNP
Signal Isolator
X1
DC/DC Converter, VGH Supply
X2
X3
DC/DC Converter, VGL Supply
DC/DC Converter, VEE Supply
Description
2.0 Ω, 2 W
10 nF
1.0 Ω, 0.5 W
40 V, 2 A
1.0 Ω, 0.5 W
40 V, 8 A, Silicon NPN BJT
40 V, 8 A, Silicon PNP BJT
Opto-Isolator –or– Transformer Isolator
VOUT = +20 V, VIN = +12 V, 2 W, VISO = 5.2
kV
VOUT = +5 V, VIN = +12 V, 3 W, VISO = 3.0 kV
VOUT = -5 V, VIN = +12 V, 2 W, VISO = 5.2 kV
Suggested Part
CRM2512-JW-2R2ELF
C1812C103J1GACTU
ERJ-1TYJ1R0U
SS24T3G
ERJ-1TYJ1R0U
MJD44H11
MJD45H11
ACPL-4800 / ADUM3210
MGJ2D122005SC
MEV3S1205SC
MGJ2D122005SC
B:2: Voltage Supply Selection
The IX2204 gate drive design requires three supply voltages VGH, VGL, and VEE (listed in Table 2) optionally supplied through DC/DC
converters. During device turn-on, VGH charges the external capacitor CG thereby delivering the narrow width, high current pulse IG,on to the
SJT gate and charges the SJT’s internal terminal capacitances CGD and CGS. For a given level of parasitic inductance in the gate circuit and
SJT package, the rise time of IG,on is controlled by the choice of VGH and CG. During the steady on-state, VGL in combination with the internal
and external gate resistances provides a continuous gate current for the GA03JT12-247 to remain on. The VEE supply sets the gate negative
during turn-off and steady off-state for faster switching and to avoid spurious turn-on which may be caused by external circuit noise. The
power rating of the voltage supplies should be adequate to meet the gate drive power requirements as determined by
,
,
,
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2
1
2
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Pg7 of 10 GA03JT12-247
Table 2: IX2204 Gate Drive Example Component List
Values
Parameter
Symbol
Range
Typical
VGH
Supply Voltage, Driver Output A
15 – 20
+ 20.0
VGL
Supply Voltage, Driver Output B
5.0 – 7.0
+ 5.0
VEE
Negative Supply Voltage
-10 – GND
- 5.0
B:3: Gate Capacitor CG Selection
VGH / VEE
RCG
CG
Rch
D
IG
G
RG(INT)
S
VGL / VEE
DRG
RG(EXT)
Figure 23: Primary gate drive circuit passive components with series gate resistance Schottky rectifier.
An external gate capacitor CG connected directly to the device gate pin delivers the positive current peak IG,on during device turn-on and the
negative current peak IG,off during turn-off. A low value resistor RCG is connected in series with CG to damp potential high-frequency oscillation.
A high value resistor Rch in parallel with CG sets the SJT gate to a defined potential (-VEE) during steady off-state.
At device turn-on, CG is pulled to VGH which produces a transient peak of gate voltage and current. This current peak rapidly charges the
internal SJT CGS and CGD capacitances. A Schottky diode, DRG, in series with RG(EXT) blocks any CG induced current from draining out through
RG(EXT) and ensures that all of the charge within CG flows only into the device gate, allowing for an ultra-fast device turn-on. During steady onstate, a potential of VGH - VGS = VGH – 3 V is across CG. When the device is turned off, CG is pulled to negative VEE and VGS is pulled to a
transient peak of VGS,turn-off = VEE – (VGH – 3 V), this induces the negative current peak IG,off out of the gate which discharges the SJT internal
capacitances.
B:4: External Gate Resistor RG(EXT) Selection
An external gate resistor RG(EXT) connected directly to the SJT gate pin acts to deliver a continuous current IG,steady during steady on-state. The
gate current is determined by:
,
The on-state gate-source voltage VGS(FWD) can be approximated to 3 V and the Schottky on-state voltage VSch can be approximated to 0.3 V
which simplifies the equation to:
3.3
,
The desired IG,steady is determined by the peak device junction temperature TJ during operation, drain current ID, DC current gain hFE, and a 50
% safety margin to avoid operating the device in saturation. IG,steady may also be approximated from the temperature dependent on-state curves
of the device in Figures Error! Reference source not found. – Error! Reference source not found., provided that a 50 % increase is given.
Symbol
CG
RCG
Rch
RG(EXT)
RG(INT-ON)
DRG
Table 3: Passive Output Component List
Values
Range
Typical
Gate Capacitor, External
5 – 20
10
Damping Resistor of Gate Capacitor
0.5 – 2.0
1.0
Charging Resistor
500 – 10k
1k
Gate Resistor, External
0.4 – 5
2.0
Gate Resistance, Internal, On-State
0.8 – 1.5
0.9
Schottky Diode of Gate Resistor
--Parameter
Units
nF
Ω
Ω
Ω
Ω
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B:5: Optional Gate Current Boost Network
An optional output totem-pole network may be attached to the IX2204 output pins as shown in Figure 22 using either silicon BJTs (shown) or
MOSFETs. This configuration allows the IX2204 to directly drive the BJT bases or MOSFET gates and not supply the full peak and steady
state gate current entering the SJT gate. The primary gate current delivery device is transferred to the discrete components which have higher
power dissipation ratings than the IX2204.
B:6: Voltage Supply Isolation
The DC/DC supply voltage converters are suggested to provide isolation at a minimum of twice the working VDS on the SJT transistor during
off-state to provide adequate protection to circuitry external to the gate drive circuit. Suggested DC/DC converters have an isolation of 3.0 kV
or greater. Alternatively, DC/DC converter galvanic isolation may be bypassed and direct connection of variable voltage supplies may be done,
this may be convenient during testing and prototyping but carries risk and is not suggested for extended usage.
Figure 24: Typical DC/DC converter configuration
B:7: Signal Isolation
The gate supply signal is suggested to be isolated to twice the working VDS on the SJT during off-state to provide adequate protection to
circuitry external to the gate drive circuit. This may be done using opto or galvanic isolation techniques.
B:8: Additional Features
The IX2204 has additional functionality available which is unused in the given configuration. Desaturation detection and fault status monitoring
may be implemented by un-grounding the DESAT, BLANK, and TRISTATE pins and configuring them as recommended in the IX2204
datasheet, available from IXYS. Active miller clamping is also available on other gate drive ICs which may also be desired in some SJT
switching applications but is not required, refer to specific gate drive IC datasheets for more information.
C: Alternative Gate Drive ICs
dividual product manufacturers.
Table 4 features a partial list of alternative gate drive ICs which may be used for driving the GA03JT12-247; specific product information
should be obtained from the individual product manufacturers.
Table 4: Additional Commercial Gate Drivers Compatible with GA06JT12-247
Manufacturer
Part Number
Optical Signal
Isolation
Desaturation
Detection
Features
Active Miller
3
Gate Clamping
High Side
Capability
Number of
Outputs



Avago Tech.
HCPL-316J
–
1




Avago Tech.
HCPL-322J
1

IXYS
IXD_604
–
–
–
2

IXYS
IXD_614
–
–
–
1

Micrel
MIC4452YN
–
–
–
1

Microsemi
LX4510
–
–
–
1

Texas Instruments UCC27322
–
–
–
1
3
– Active Miller Gate Clamping recommended for VEE = GND switching applications as SJT and/or output BJT secondary gate discharge path.
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Pg9 of 10 GA03JT12-247
Package Dimensions
TO-247AB
PACKAGE OUTLINE
NOTE
1. CONTROLLED DIMENSION IS INCH. DIMENSION IN BRACKET IS MILLIMETER.
2. DIMENSIONS DO NOT INCLUDE END FLASH, MOLD FLASH, MATERIAL PROTRUSIONS
Revision History
Date
Revision
Comments
2014/08/26
7
Updated Electrical Characteristics
2014/02/05
6
Updated Electrical Characteristics
2013/12/18
5
Updated Gate Drive Section
2013/11/12
4
Updated Electrical Characteristics
2013/08/30
3
Updated Switching Characteristics
Supersedes
Published by
GeneSiC Semiconductor, Inc.
43670 Trade Center Place Suite 155
Dulles, VA 20166
GeneSiC Semiconductor, Inc. reserves right to make changes to the product specifications and data in this document without notice.
GeneSiC disclaims all and any warranty and liability arising out of use or application of any product. No license, express or implied to any
intellectual property rights is granted by this document.
GeneSiC is not responsible for third-party component performance and does not guarantee similar results.
Unless otherwise expressly indicated, GeneSiC products are not designed, tested or authorized for use in life-saving, medical, aircraft
navigation, communication, air traffic control and weapons systems, nor in applications where their failure may result in death, personal
injury and/or property damage.
Aug 2014
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Pg10 of 10 GA03JT12-247
SPICE Model Parameters
This is a secure document. Please copy this code from the SPICE model PDF file on our website
(http://www.genesicsemi.com/images/products_sic/sjt/GA03JT12-247_SPICE.pdf)
into
LTSPICE
(version 4) software for simulation of the GA03JT12-247.
*
MODEL OF GeneSiC Semiconductor Inc.
*
*
$Revision:
1.2
$
*
$Date:
26-AUG-2014
$
*
*
GeneSiC Semiconductor Inc.
*
43670 Trade Center Place Ste. 155
*
Dulles, VA 20166
*
*
COPYRIGHT (C) 2014 GeneSiC Semiconductor Inc.
*
ALL RIGHTS RESERVED
*
* These models are provided "AS IS, WHERE IS, AND WITH NO WARRANTY
* OF ANY KIND EITHER EXPRESSED OR IMPLIED, INCLUDING BUT NOT LIMITED
* TO ANY IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
* PARTICULAR PURPOSE."
* Models accurate up to 2 times rated drain current.
*
.model GA03JT12 NPN
+ IS
3.01E-49
+ ISE
1.00E-27
+ EG
3.2
+ BF
58.5
+ BR
0.55
+ IKF
200
+ NF
1
+ NE
2
+ RB
18.0
+ RBM
0.9
+ IRB
1e-4
+ RE
0.184170194
+ RC
0.342829806
+ CJC
1.37E-10
+ VJC
3.150960833
+ MJC
0.43821105
+ CJE
2.97E-10
+ VJE
2.901930244
+ MJE
0.475141754
+ XTI
3
+ XTB
-1.24
+ TRC1
5.00E-3
+ VCEO
1200
+ ICRATING 3
+ MFG
GeneSiC_Semiconductor
*End of GA03JT12 SPICE Model
Aug 2014
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