LM2679SADJNOPB - NATIONAL SEMICONDUCTOR

ACPL-330J

1.5 Amp Output Current IGBT Gate Driver Optocoupler

with Integrated (VCE) Desaturation Detection, UVLO,

Fault Feedback, Active Miller Clamp and Auto-Fault Reset

Data Sheet

Description

The ACPL-330J is an advanced 1.5 A output current, easy-

to-use, intelligent gate driver which makes IGBT VCE fault

protection compact, aordable, and easy-to implement.

Features such as integrated VCE detection, under

voltage lockout (UVLO), “soft” IGBT turn-o, isolated

open collector fault feedback and active Miller clamping

provide maximum design exibility and circuit protec-

tion.

The ACPL-330J contains a AlGaAs LED. The LED is

optically coupled to an integrated circuit with a power

output stage. ACPL-330J is ideally suited for driving

power IGBTs and MOSFETs used in motor control inverter

applications. The voltage and current supplied by these

optocouplers make them ideally suited for directly

driving IGBTs with ratings up to 1200 V and 100 A. For

IGBTs with higher ratings, the ACPL-330J can be used to

drive a discrete power stage which drives the IGBT gate.

The ACPL-330J has an insulation voltage of VIORM = 1414

VPEAK.

Block Diagram

Features

• 1.5 A maximum peak output current

• 1.0 A minimum peak output current

• 250 ns maximum propagation delay over

temperature range

• 1.0A Active Miller Clamp. Clamp pin short to VEE if not

in used

• Miller Clamping

• Desaturation Detection

• Under Voltage Lock-Out Protection (UVLO)

with Hysteresis

• Open Collector Isolated fault feedback

• “Soft” IGBT Turn-o

• Automatic Fault Reset after xed Mute Time , typically

26ms

• Available in SO-16 package

• 100 ns maximum pulse width distortion (PWD)

• 50 kV/µs minimum common mode rejection (CMR)

at VCM = 1500 V

• ICC(max) < 5 mA maximum supply current

• Wide VCC operating range: 15 V to 30 V over

temperature range

• Wide operating temperature range: –40°C to 105°C

• Safety Approvals:

UL, 5000 VRMS for 1 minute, CSA Approval,

IEC/EN/DIN-EN 60747-5-5 VIORM = 1414 VPEAK

Applications

• Isolated IGBT/Power MOSFET gate drive

• AC and brushless DC motor drives

• Industrial inverters and Uninterruptible Power Supply

(UPS)

Lead (Pb) Free

RoHS 6 fully

compliant

RoHS 6 fully compliant options available;

-xxxE denotes a lead-free product

CAUTION: It is advised that normal static precautions be taken in handling and assembly of this

component to prevent damage and/or degradation which may be induced by ESD. The components

featured in this datasheet are not to be used in military or aerospace applications or environments.

SHIELD

DESAT

VCC2

VOUT

VCLAMP

VEE

VCC1

FAULT

ANODE

CATHODE

VCLAMP

VLED

6, 7

5, 8

1, 4

9, 12

DESAT

UVLO

LED1

LED2

Pin Description Pin Symbol Description

1 VSInput Ground

2 VCC1 Positive input supply voltage. (3.3 V to 5.5 V)

3FAULT Fault output. FAULT changes from a high impedance state

to a logic low output within 5 µs of the voltage on the

DESAT pin exceeding an internal reference voltage of 6.5 V.

FAULT output is an open collector which allows the FAULT

outputs from all ACPL-330J in a circuit to be connected

together in a “wired OR” forming a single fault bus for inter-

facing directly to the micro-controller.

4 VSInput Ground

5 CATHODE Cathode

6 ANODE Anode

7 ANODE Anode

8 CATHODE Cathode

9 VEE Output supply voltage.

10 VCLAMP Miller clamp

11 VOUT Gate drive voltage output

12 VEE Output supply voltage.

13 VCC2 Positive output supply voltage

14 DESAT Desaturation voltage input. When the voltage on DESAT

exceeds an internal reference voltage of 6.5 V while the

IGBT is on, FAULT output is changed from a high impedance

state to a logic low state within 5 µs.

15 VLED LED anode. This pin must be left unconnected for guaran-

teed data sheet performance. (For optical coupling testing

only)

16 VECommon (IGBT emitter) output supply voltage.

VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

FAULT

CATHODE

ANODE

CATHODE

VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

FAULT

CATHODE

ANODE

CATHODE

Ordering Information

ACPL-330J is UL Recognized with 5000 Vrms for 1 minute per UL1577.

Part number

Option

Package

Surface

Mount Tape& Reel

IEC/EN/DIN EN

60747-5-5 QuantityRoHS Compliant

ACPL-330J -000E SO-16 X X 45 per tube

-500E X X X 850 per reel

To order, choose a part number from the part number column and combine with the desired option from the option

column to form an order entry.

Example 1:

ACPL-330J-500E to order product of SO-16 Surface Mount package in Tape and Reel packaging with IEC/EN/DIN EN

60747-5-5 Safety Approval in RoHS compliant.

Example 2:

ACPL-330J-000E to order product of SO-16 Surface Mount package in tube packaging with IEC/EN/DIN EN

60747-5-5 Safety Approval and RoHS compliant.

Option datasheets are available. Contact your Avago sales representative or authorized distributor for information.

Remarks: The notation ‘#XXX’ is used for existing products, while (new) products launched since 15th July 2001 and

RoHS compliant option will use ‘-XXXE‘.

Package Outline Drawings

16-Lead Surface Mount

7.493 ± 0.254

(0.295 ± 0.010)

10111213141516

87654321

0.457

(0.018)

3.505 ± 0.127

(0.138 ± 0.005)

9°

10.312 ± 0.254

(0.406 ± 0.10)

10.363 ± 0.254

(0.408 ± 0.010)

0.64 (0.025) MIN.

0.203 ± 0.076

(0.008 ± 0.003)

STANDOFF

8.763 ± 0.254

(0.345 ± 0.010)

0-8°

0.457

(0.018) 1.270

(0.050)

A XXXX

YYWW

TYPE NUMBER

DATE CODE

11.63 (0.458)

2.16 (0.085)

0.64 (0.025)

LAND PATTERN RECOMMENDATION

EEE

LOT ID

AVAGO

LEAD-FREE

Dimensions in Millimeters (Inches)

Floating lead protrusion is 0.25 mm (10 mils) Max.

Note: Initial and continued variation in color of the white mold compound is normal and does not aect performance or reliability of the device

ALL LEADS TO

BE COPLANAR

± 0.05 (0.002)

PIN 1 DOT

Table 1. IEC/EN/DIN EN 60747-5-5 Insulation Characteristics*

Description Symbol Characteristic Unit

Installation classication per DIN VDE 0110/39, Table 1

for rated mains voltage ≤ 150 Vrms

for rated mains voltage ≤ 300 Vrms

for rated mains voltage ≤ 600 Vrms

for rated mains voltage ≤ 1000Vrms

I – IV

I – III

Climatic Classication 40/100/21

Pollution Degree (DIN VDE 0110/39) 2

Maximum Working Insulation Voltage VIORM 1414 Vpeak

Input to Output Test Voltage, Method b**,

VIORM x 1.875=VPR, 100% Production Test with tm=1 sec, Partial discharge < 5 pC

VPR 2652 Vpeak

Input to Output Test Voltage, Method a**,

VIORM x 1.6=VPR, Type and Sample Test, tm=10 sec, Partial discharge < 5 pC

VPR 2262 Vpeak

Highest Allowable Overvoltage (Transient Overvoltage tini = 60 sec) VIOTM 8000 Vpeak

Safety-limiting values – maximum values allowed in the event of a failure

Case Temperature TS175 °C

Input Current IS, INPUT 400 mA

Output Power PS, OUTPUT 1200 mW

Insulation Resistance at TS, VIO = 500 V RS>109W

* Isolation characteristics are guaranteed only within the safety maximum ratings which must be ensured by protective circuits in application.

Surface mount classication is class A in accordance with CECCOO802.

** Refer to IEC/EN/DIN EN 60747-5-5 Optoisolator Safety Standard section of the Avago Regulatory Guide to Isolation Circuits, AV02-2041EN for a

detailed description of Method a and Method b partial discharge test proles.

Dependence of Safety Limiting Values on Temperature. (take from DS AV01-0579EN Pg.7)

- POWER - mW

TS - CASE TEMPERATURE - °C

200

1200

800

1400

50 75 100

400

150 175

PS , OUTPUT

PS , INPUT

125

200

600

1000

Recommended Pb-Free IR Prole

Recommended reow condition as per JEDEC Standard, J-STD-020 (latest revision). Non-Halide Flux should be used.

Regulatory Information

The ACPL-330J has been approved by the following organizations:

IEC/EN/DIN EN 60747-5-5 Approval under: DIN EN 60747-5-5 (VDE 0884-5):2011-11 EN 60747-5-5:2011

UL Approval under UL 1577, component recognition program up to VISO = 5000 VRMS. File E55361.

CSA Approval under CSA Component Acceptance Notice #5, File CA 88324.

Table 2. Insulation and Safety Related Specications

Parameter Symbol ACPL-330J Units Conditions

Minimum External Air

Gap (Clearance)

L(101) 8.3 mm Measured from input terminals to output terminals,

shortest distance through air.

Minimum External

Tracking (Creepage)

L(102) 8.3 mm Measured from input terminals to output terminals,

shortest distance path along body.

Minimum Internal

Plastic Gap (Internal

Clearance)

0.5 mm Through insulation distance conductor to conductor,

usually the straight line distance thickness between the

emitter and detector.

Tracking Resistance

(Comparative Tracking

Index)

CTI >175 V DIN IEC 112/VDE 0303 Part 1

Isolation Group IIIa Material Group (DIN VDE 0110, 1/89, Table 1)

Table 3. Absolute Maximum Ratings

Parameter Symbol Min. Max. Units Note

Storage Temperature TS-55 125 °C

Operating Temperature TA-40 105 °C 2

Output IC Junction Temperature TJ125 °C 2

Average Input Current IF(AVG) 25 mA 1

Peak Transient Input Current

(<1 µs pulse width, 300pps)

IF(TRAN) 1.0 A

Reverse Input Voltage VR5 V

“High” Peak Output Current IOH(PEAK) 1.5 A 3

“Low” Peak Output Current IOL(PEAK) 1.5 A 3

Positive Input Supply Voltage VCC1 -0.5 7.0 V

FAULT Output Current IFAULT 8.0 mA

FAULT Pin Voltage VFAULT -0.5 VCC1 V

Total Output Supply Voltage (VCC2 - VEE) -0.5 33 V

Negative Output Supply Voltage (VE - VEE) -0.5 15 V 6

Positive Output Supply Voltage (VCC2 - VE) -0.5 33 - (VE - VEE) V

Gate Drive Output Voltage VO(PEAK) -0.5 VCC2 V

Peak Clamping Sinking Current IClamp 1.0 A

Miller Clamping Pin Voltage VClamp -0.5 VCC2 V

DESAT Voltage VDESAT VEVE + 10 V

Output IC Power Dissipation PO600 mW 2

Input IC Power Dissipation PI150 mW 2

Solder Reow Temperature Prole See Package Outline Drawings section

Table 4. Recommended Operating Conditions

Parameter Symbol Min. Max. Units Note

Operating Temperature TA- 40 105 °C 2

Total Output Supply Voltage (VCC2 - VEE) 15 30 V 7

Negative Output Supply Voltage (VE - VEE) 0 15 V 4

Positive Output Supply Voltage (VCC2 - VE) 15 30 - (VE - VEE) V

Input Current (ON) IF(ON) 8 12 mA

Input Voltage (OFF) VF(OFF) - 3.6 0.8 V

Table 5. Electrical Specications (DC)

Unless otherwise noted, all typical values at TA = 25°C, VCC2 - VEE = 30 V, VE - VEE = 0 V;

all Minimum/Maximum specications are at Recommended Operating Conditions.

Parameter Symbol Min. Typ. Max. Units Test Conditions Fig. Note

FAULT Logic Low

Output Voltage

VFAULTL 0.1 0.4 V IFAULT = 1.1 mA, VCC1 = 5.5V

0.1 0.4 V IFAULT = 1.1 mA, VCC1 = 3.3V

FAULT Logic High

Output Current

IFAULTH 0.02 0.5 µA VFAULT = 5.5 V, VCC1 = 5.5V

0.002 0.3 µA VFAULT = 3.3 V, VCC1 = 3.3V

High Level

Output Current

IOH -0.3 -0.75 A VO = VCC2 – 4 4, 18 5

-1.0 A VO = VCC2 – 15 3

Low Level

Output Current

IOL 0.3 0.75 A VO = VEE + 2.5 5, 19 5

1.0 A VO = VEE + 15 3

Low Level Output Current

During Fault Condition

IOLF 90 140 230 mA VOUT - VEE = 14 V 6

High Level

Output Voltage

VOH VCC-2.9 VCC-2.0 V IO = -650 µA 2, 4,

7, 8,9

Low Level

Output Voltage

VOL 0.17 0.5 V IO = 100 mA 3, 5,

Clamp Pin Threshold

Voltage

VtClamp 2.0 V

Clamp Low Level

Sinking Current

ICL 0.21 0.7 A VO = VEE + 2.5

High Level Supply Current ICC2H 2.5 5 mA IO = 0 mA 6, 7,

Low Level Supply Current ICC2L 2.5 5 mA IO = 0 mA

Blanking Capacitor

Charging Current

ICHG 0.13 -0.24 -0.33 mA VDESAT = 2 V 8, 24 9, 10

Blanking Capacitor

Discharge Current

IDSCHG 10 30 mA VDESAT = 7.0 V 25

DESAT Threshold VDESAT 6 6.5 7.5 V VCC2 -VE >VUVLO- 9, 27 9

UVLO Threshold VUVLO+ 10.5 11.6 12.5 V VO > 5 V 7, 9, 11

VUVLO- 9.2 10.3 11.1 V VO < 5 V 7, 9, 12

UVLO Hysteresis (VUVLO+

- VUVLO-)

0.4 1.3 V

Threshold Input Current

Low to High

IFLH 2.0 6 mA IO = 0 mA, VO > 5 V

Threshold Input Voltage

High to Low

VFHL 0.8 V

Input Forward Voltage VF1.2 1.6 1.95 V IF = 10 mA

Temperature Coecient

of Input Forward Voltage

DVF/DTA-1.3 mV/°C

Input Reverse Breakdown

Voltage

BVR5 V IR = 10 µA

Input Capacitance CIN 70 pF f = 1 MHz, VF = 0 V

Table 6. Switching Specications (AC)

Unless otherwise noted, all typical values at TA = 25°C, VCC2 - VEE = 30 V, VE - VEE = 0 V;

all Minimum/Maximum specications are at Recommended Operating Conditions.

Parameter Symbol Min. Typ. Max. Units Test Conditions Fig. Note

Propagation Delay Time

to High Output Level

tPLH 100 180 250 ns Rg = 20 W, Cg = 5 nF,

f = 10 kHz,

Duty Cycle = 50%,

IF = 10 mA, VCC2 = 30 V

1, 10,

11, 12,

13, 26

13, 15

Propagation Delay Time

to Low Output Level

tPHL 100 180 250 ns

Pulse Width Distortion PWD -100 20 100 ns 14, 17

Propagation Delay Dierence

Between Any Two Parts or

Channels

(tPHL - tPLH)

PDD

-150 150 ns 17, 16

Rise Time tR50 ns

Fall Time tF50 ns

DESAT Sense to 90% VO Delay tDESAT(90%) 0.15 0.3 µs CDESAT = 100pF, RF=2.1kΩ,

Rg = 20 W, Cg = 5 nF,

VCC2 = 30 V

14, 27,

DESAT Sense to 10% VO Delay tDESAT(10%) 1.1 1.5 µs CDESAT = 100pF, RF=2.1kΩ ,

Rg = 20 W, Cg = 5 nF,

VCC2 = 30 V

15, 16,

17, 27,

DESAT Sense to Low Level

FAULT Signal Delay

tDESAT(FAULT) 0.25 0.5 µs CDESAT = 100 pF, RF = 2.1

kΩ, CF = Open, Rg = 20 Ω,

Cg = 5 nF, VCC2 = 30 V

27, 34 18

0.8 CDESAT = 100 pF, RF = 2.1

kΩ, CF = 1 nF, Rg = 20 Ω,

Cg = 5 nF, VCC2 = 30 V

DESAT Sense to DESAT

Low Propagation Delay

tDESAT(LOW) 0.25 µs CDESAT = 100pF, RF = 2.1

kW,

Rg = 20 W, Cg = 5 nF,

VCC2 = 30 V

27, 34 19

DESAT Input Mute tDESAT(MUTE) 15 26 40 µs CDESAT = 100pF, RF = 2.1

kW,

Rg = 20 W, Cg = 5 nF,

VCC1 = 5.5V, VCC2 = 30 V

34 20

Output High Level Common

Mode Transient Immunity

|CMH| 15 25 kV/µs TA = 25°C, IF = 10 mA

VCM = 1500 V, VCC2 = 30 V,

RF = 2.1 kΩ, CF = 15 pF

28, 29,

30, 31

50 60 TA = 25°C, IF = 10 mA

VCM = 1500 V, VCC2 = 30 V,

RF = 2.1 kΩ, CF = 1 nF

21, 26

Output Low Level Common

Mode Transient Immunity

|CML| 15 25 kV/µs TA = 25°C, VF = 0 V

VCM = 1500 V, VCC2 = 30 V,

RF = 2.1 kΩ, CF = 15 pF

28, 29,

30, 31

50 60 TA = 25°C, VF = 0 V

VCM = 1500 V, VCC2 = 30 V,

RF = 2.1 kΩ, CF = 1 nF

Notes:

1. Derate linearly above 70°C free air temperature at a rate of 0.3 mA/°C.

2. In order to achieve the absolute maximum power dissipation specied, pins 4, 9, and 10 require ground plane connections and may require

airow. See the Thermal Model section in the application notes at the end of this data sheet for details on how to estimate junction temperature

and power dissipation. In most cases the absolute maximum output IC junction temperature is the limiting factor. The actual power dissipation

achievable will depend on the application environment (PCB Layout, air ow, part placement, etc.). See the Recommended PCB Layout section

in the application notes for layout considerations. Output IC power dissipation is derated linearly at 10 mW/°C above 90°C. Input IC power

dissipation does not require derating.

3. Maximum pulse width = 10 µs. This value is intended to allow for component tolerances for designs with IO peak minimum = 1.0 A.

Derate linearly from 2.0 A at +25°C to 1.5 A at +105°C. This compensates for increased IOPEAK due to changes in VOL over temperature.

4. This supply is optional. Required only when negative gate drive is implemented.

5. Maximum pulse width = 50 µs.

6. See the Slow IGBT Gate Discharge During Fault Condition section in the applications notes at the end of this data sheet for further details.

7. 15 V is the recommended minimum operating positive supply voltage (VCC2 - VE) to ensure adequate margin in excess of the maximum VUVLO+

threshold of 12.5 V. For High Level Output Voltage testing, VOH is measured with a dc load current. When driving capacitive loads, VOH will

approach VCC as IOH approaches zero units.

8. Maximum pulse width = 1.0 ms.

9. Once VO of the ACPL-330J is allowed to go high (VCC2 - VE > VUVLO+), the DESAT detection feature of the ACPL-330J will be the primary source of

IGBT protection. UVLO is needed to ensure DESAT is functional. Once VCC2 is increased from 0V to above VUVLO+, DESAT will remain functional

until VCC2 is decreased below VUVLO-. Thus, the DESAT detection and UVLO features of the ACPL-330J work in conjunction to ensure constant

IGBT protection.

10. See the DESAT fault detection blanking time section in the applications notes at the end of this data sheet for further details.

11. This is the “increasing” (i.e. turn-on or “positive going” direction) of VCC2 - VE

12. This is the “decreasing” (i.e. turn-o or “negative going” direction) of VCC2 - VE

13. This load condition approximates the gate load of a 1200 V/75A IGBT.

14. Pulse Width Distortion (PWD) is dened as |tPHL - tPLH| for any given unit.

15. As measured from IF to VO.

16. The dierence between tPHL and tPLH between any two ACPL-330J parts under the same test conditions.

17. As measured from ANODE, CATHODE of LED to VOUT

18. This is the amount of time from when the DESAT threshold is exceeded, until the FAULT output goes low.

19. This is the amount of time the DESAT threshold must be exceeded before VOUT begins to go low, and the FAULT output to go low. This is supply

voltage dependent.

20. Auto Reset: This is the amount of time when VOUT will be asserted low after DESAT threshold is exceeded. See the Description of Operation

(Auto Reset) topic in the application information section.

21. Common mode transient immunity in the high state is the maximum tolerable dVCM/dt of the common mode pulse, VCM, to assure that the

output will remain in the high state (i.e., VO > 15 V or FAULT > 2 V).

22. Common mode transient immunity in the low state is the maximum tolerable dVCM/dt of the common mode pulse, VCM, to assure that the

output will remain in a low state (i.e., VO < 1.0 V or FAULT < 0.8 V).

23. To clamp the output voltage at VCC - 3 VBE, a pull-down resistor between the output and VEE is recommended to sink a static current of 650 µA

while the output is high. See the Output Pull-Down Resistor section in the application notes at the end of this data sheet if an output pull-down

resistor is not used.

24. In accordance with UL 1577, each optocoupler is proof tested by applying an insulation test voltage ≥ 6000 Vrms for 1 second. This test is

performed before the 100% production test for partial discharge (method b) shown in IEC/EN/DIN EN 60747-5-5 Insulation Characteristic Table.

25. This is a two-terminal measurement: pins 1-8 are shorted together and pins 9-16 are shorted together.

26. Split resistors network with a ratio of 1:1 is needed at input LED1. See Figure 31.

Table 7. Package Characteristics

Parameter Symbol Min. Typ. Max. Units Test Conditions Fig. Note

Input-Output Momentary

Withstand Voltage

VISO 5000 Vrms RH < 50%, t = 1 min.,

TA = 25°C

24, 25

Input-Output Resistance RI-O > 109WVI-O = 500 V 25

Input-Output Capacitance CI-O 1.3 pF freq=1 MHz

Output IC-to-Pins 9 &10

Thermal Resistance

q09-10 30 °C/W TA = 25°C

(VOH - VCC) - HIGH OUTPUT VOLTAGE DROP - V

TA- TEMPERATURE -°C

-2.5

-2

-1.5

-1

-0.5

-40 -20 0 20 40 60 80 105

____IOUT = -650µA

0.05

0.1

0.15

0.2

0.25

-40 -20 0 20 40 60 80 105

VOL - OUTPUT LOW VOLTAGE - V

TA- TEMPERATURE -°C

0.0 0.2 0.4 0.6 0.8 1.0

IOH - OUTPUT HIGH CURRENT - A

VOH - HIGH OUTPUT VOLTAGE DROP - V

_ _ _ _ 105°C

______ 25°C

--------- -40°C

0 0.5 1 1.5

IOL - OUTPUT LOW CURRENT - A

_ _ _ _ 100°C

25°C

--------- -40°C

VOL - OUTPUT LOW VOLTAGE - V

Figure 1. Timing Curve

Figure 2. VOH vs. temperature Figure 3. VOL vs. temperature

Figure 4. VOH vs. IOH Figure 5. VOL vs. IOL

OUT

PHL

PLH

10%

50%

90%

2.00

2.25

2.50

2.75

3.00

3.25

3.50

-40 -20 0 20 40 60 80 105

ICC2 - OUTPUT SUPPLY CURRENT - mA

TA- TEMPERATURE -°C

2.25

2.35

2.45

2.55

2.65

15 20 25 30

ICC2 - OUTPUT SUPPLY CURRENT - mA

VCC2 - SUPPLY VOLTAGE - V

-0.35

-0.30

-0.25

-0.20

-40 -20 0 20 40 60 80 105

- BLANKING CAPACITOR

CHARGING CURRENT - mA

TA- TEMPERATURE -°C

6.0

6.5

7.0

7.5

-40 -20 0 20 40 60 80 105

VDESAT - DESAT THRESHOLD - V

TA- TEMPERATURE -°C

100

150

200

250

300

-40 -20 0 20 40 60 80 105

TP - PROPAGATION DELAY - ns

TA- TEMPERATURE -°C

100

150

200

250

300

15 20 25 30

VCC - SUPPLY VOLTAGE - V

TP - PROPAGATION DELAY - ns

PLH

PHL

PLH

PHL

ICC2H

ICC2L

ICC2H

ICC2L

Figure 7. ICC2 vs. VCC2

Figure 8. ICHG vs. temperature Figure 9. DESAT threshold vs. temperature

Figure 10. Propagation delay vs. temperature Figure 11. Propagation delay vs. supply voltage

Figure 6. ICC2 vs. temperature

100

150

200

250

300

0 10 20 30 40 50

LOAD RESISTANCE - ohm

PLH

PHL

TP - PROPAGATION DELAY - ns

100

200

300

0 10 20 30 40 50

LOAD CAPACITANCE - nF

PLH

tPHL

TP - PROPAGATION DELAY - ns

100

150

200

250

-40 -20 0 20 40 60 80 105

TDESAT90% - DESAT Sense to 90% Vo Delay - ns

TA- TEMPERATURE -°C

0.0

0.5

1.0

1.5

2.0

-40 -20 0 20 40 60 80 105

cc2

=15V

Vcc2 =30V

TDESAT10% - DESAT Sense to 10% Vo Delay - us

TA- TEMPERATURE -°C

0.0

1.0

2.0

3.0

4.0

10 20 30 40 50

LOAD RESISTANCE-ohm

cc2

=15V

Vcc2 =30V

TDESAT10% - DESAT Sense to 10% Vo Delay - us

0.000

0.004

0.008

0.012

0 10 20 30 40 50

LOAD CAPACITANCE-nF

TDESAT10% - DESAT Sense to 10% Vo Delay - ms

Vcc2 =15V

Vcc2 =30V

Figure 13. Propagation delay vs. load capacitance

Figure 14. DESAT sense to 90% VOUT delay vs. temperature Figure 15. DESAT sense to 10% VOUT delay vs. temperature

Figure 16. DESAT sense to 10% VOUT delay vs. load resistance Figure 17. DESAT sense to 10% VOUT delay vs. load capacitance

Figure 12. Propagation delay vs. load resistance

Figure 18. IOH Pulsed test circuit

Figure 19. IOL Pulsed test circuit

Figure 20. VOH Pulsed test circuit

VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

FAULT

CATHODE

ANODE

CATHODE

10mA

0.1µF

15V Pulsed

IOUT

30V

VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

FAULT

CATHODE

ANODE

CATHODE

10mA

0.1µF0.1µF

15V Pulsed

IOUT

30V

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

15V Pulsed

OUT

30V

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF0.1µF

15V Pulsed

OUT

30V

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

650µA

OUT

30V

10mA

Figure 21. VOL Pulsed test circuit

Figure 22. ICC2H test circuit

Figure 23. ICC2L test circuit

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

100mA

OUT

30V

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

ANODE

CATHODE

0.1µF0.1µF

100mA

OUT

30V

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

CC2

30V

10mA

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF0.1µF

CC2

30V

10mA10mA

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

0.1µF 30V

CC2

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF0.1µF

0.1µF0.1µF 30V

CC2

Figure 24. ICHG Pulsed test circuit

Figure 25. IDSCHG test circuit

Figure 26. tPLH, tPHL, tf, tr, test circuit

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

CHG

30V

10mA

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF0.1µF

CHG

30V

10mA10mA

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

30V

IDSCHG

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF0.1µF

30V

IDSCHG

5nF

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

OUT

30V

20Ω

10mA, 10kHz,

50% Duty Cycle

5nF5nF

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF0.1µF

OUT

30V

10mA, 10kHz,

50% Duty Cycle

Figure 27. tDESAT fault test circuit

Figure 28. CMR Test circuit LED2 o

Figure 29. CMR Test Circuit LED2 on

5nF

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

OUT

30V

20Ω

FAULT

10mA 5nF

LED

DESAT

CC2

OUT

CLAMP

CC1

0.1µF0.1µF

OUT

30V

FAULT

10mA10mA

20Ω

5nF

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

30V

360Ω

0.1µF

5nF5nF

LED

DESAT

CC2

OUT

CLAMP

CC1

0.1µF0.1µF

SCOPE

30V

VCM

20Ω

5nF

VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

30V

360Ω

0.1µF

VCM

5nF5nF

VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

0.1µF0.1µF

SCOPE

30V

0.1µF0.1µF

5V5V

=2.1kΩ

=15pF

or 1nF

=2.1kΩ

=15pF

or 1nF

=2.1kΩ

Figure 30. CMR Test circuit LED1 o

Figure 31. CMR Test Circuit LED1 on

20Ω

5nF

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

SCOPE

30V

360Ω

0.1µF

LED

CC2

OUT

CLAMP

CC1

µµ

20Ω

5nF

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

0.1µF

SCOPE

30V

360Ω

0.1µF

LED

CC2

OUT

CLAMP

CC1

=2.1kΩ

=15pF

or 1nF

=2.1kΩ

=15pF

or 1nF

CATHODE

ANODE

CATHODE

180Ω

Split resistors network with a ratio of 1:1

Application Information

Product Overview Description

The ACPL-330J is a highly integrated power control

device that incorporates all the necessary components

for a complete, isolated IGBT / MOSFET gate drive circuit

with fault protection and feedback into one SO-16

package. Active Miller clamp function eliminates the

need of negative gate drive in most application and

allows the use of simple bootstrap supply for high side

driver. An optically isolated power output stage drives

IGBTs with power ratings of up to 100 A and 1200 V. A

high speed internal optical link minimizes the propaga-

tion delays between the microcontroller and the IGBT

while allowing the two systems to operate at very large

common mode voltage dierences that are common

in industrial motor drives and other power switching

applications. An output IC provides local protection

for the IGBT to prevent damage during over current,

and a second optical link provides a fully isolated fault

status feedback signal for the microcontroller. A built

in “watchdog” circuit, UVLO monitors the power stage

supply voltage to prevent IGBT caused by insucient

gate drive voltages. This integrated IGBT gate driver is

designed to increase the performance and reliability of

a motor drive without the cost, size, and complexity of a

discrete design.

Two light emitting diodes and two integrated circuits

housed in the same SO-16 package provide the input

control circuitry, the output power stage, and two optical

channels. The output Detector IC is designed manufac-

tured on a high voltage BiCMOS/Power DMOS process.

The forward optical signal path, as indicated by LED1,

transmits the gate control signal. The return optical signal

path, as indicated by LED2, transmits the fault status

feedback signal.

Under normal operation, the LED1 directly controls the

IGBT gate through the isolated output detector IC, and

LED2 remains o. When an IGBT fault is detected, the

output detector IC immediately begins a “soft” shutdown

sequence, reducing the IGBT current to zero in a con-

trolled manner to avoid potential IGBT damage from

inductive over voltages. Simultaneously, this fault status

is transmitted back to the input via LED2, where the fault

latch disables the gate control input and the active low

fault output alerts the microcontroller.

During power-up, the Under Voltage Lockout (UVLO)

feature prevents the application of insucient gate

voltage to the IGBT, by forcing the ACPL-330J’s output

low. Once the output is in the high state, the DESAT (VCE)

detection feature of the ACPL-330J provides IGBT pro-

tection. Thus, UVLO and DESAT work in conjunction to

provide constant IGBT protection.

Recommended Application Circuit

The ACPL-330J has an LED input gate control, and an

open collector fault output suitable for wired ‘OR’ ap-

plications. The recommended application circuit shown

in Figure 33 illustrates a typical gate drive implementa-

tion using the ACPL-330J. The following describes about

driving IGBT. However, it is also applicable to MOSFET.

Depending upon the MOSFET or IGBT gate threshold

requirements, designers may want to adjust the VCC

supply voltage (Recommended VCC = 17.5V for IGBT and

12.5V for MOSFET).

The two supply bypass capacitors (0.1 µF) provide the

large transient currents necessary during a switching

transition. Because of the transient nature of the

charging currents, a low current (5mA) power supply

suces. The desaturation diode DDESAT 600V/1200V

fast recovery type, trr below 75ns (e.g. ERA34-10) and

capacitor CBLANK are necessary external components for

the fault detection circuitry. The gate resistor RG serves to

limit gate charge current and controls the IGBT collector

voltage rise and fall times. The open collector fault

output has a passive pull-up resistor RF (2.1 kW) and a

1000 pF ltering capacitor, CF. A 47 kW pull down resistor

RPULL-DOWN on VOUT provides a predictable high level

output voltage (VOH). In this application, the IGBT gate

driver will shut down when a fault is detected and fault

reset by next cycle of IGBT turn on. Application notes are

mentioned at the end of this datasheet.

Figure 32. Block Diagram of ACPL-330J

SHIELD

DESAT

VCC2

VOUT

VCLAMP

VEE

VCC1

FAULT

ANODE

CATHODE

VCLAMP

VLED

6, 7

5, 8

1, 4

9, 12

DESAT

UVLO

LED1

LED2

Figure 33. Recommended application circuit (Single Supply) with desaturation detection and active Miller Clamp

Description of Operation

Normal Operation

During normal operation, VOUT of the ACPL-330J is con-

trolled by input LED current IF (pins 5, 6, 7 and 8), with

the IGBT collector-to-emitter voltage being monitored

through DESAT. The FAULT output is high. See Figure 34.

Fault Condition

The DESAT pin monitors the IGBT Vce voltage. When the

voltage on the DESAT pin exceeds 6.5 V while the IGBT

is on, VOUT is slowly brought low in order to “softly”

turn-o the IGBT and prevent large di/dt induced

voltages. Also

Figure 34. Fault Timing diagramactivated is an internal

feedback channel which brings the FAULT output low for

the purpose of notifying the micro-controller of the fault

condition.

Fault Reset

Once fault is detected, the output will be soft-shut down

to low. All input LED signals will be ignored during

the fault period to allow the driver to completely soft

shut-down the IGBT. For ACPL-330J, the driver will auto-

matically reset the FAULT pin after a xed mute time of

25ms (typical). See Figure 34.

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

100 Ω

BLANK

DESAT

PULL-DOWN

+ HVDC

- HVDC

3-PHASE

0.1µF

Figure 34. Fault Timing diagram

VDESAT

VOUT

FAULT

6.5V

tDESAT(LOW)

10%

tDESAT(10%)

90%

tDESAT(90%)

50%

tDESAT(FAULT)

tDESAT(MUTE)

Automatic Reset

after mute time

50%

tBLANK

Output Control

The outputs (VOUT and FAULT) of the ACPL-330J are con-

trolled by the combination of IF, UVLO and a detected

IGBT Desat condition. Once UVLO is not active (VCC2 -

VE > VUVLO), VOUT is allowed to go high, and the DESAT

(pin 14) detection feature of the ACPL-330J will be the

primary source of IGBT protection. Once VCC2 is increased

from 0V to above VUVLO+, DESAT will remain functional

until VCC2 is decreased below VUVLO-. Thus, the DESAT

detection and UVLO features of the ACPL-330J work in

conjunction to ensure constant IGBT protection.

Desaturation Detection and High Current Protection

The ACPL-330J satises these criteria by combining a

high speed, high output current driver, high voltage

optical isolation between the input and output, local

IGBT desaturation detection and shut down, and an

optically isolated fault status feedback signal into a single

16-pin surface mount package.

The fault detection method, which is adopted in the

ACPL-330J is to monitor the saturation (collector)

voltage of the IGBT and to trigger a local fault shutdown

sequence if the collector voltage exceeds a predeter-

mined threshold. A small gate discharge device slowly

reduces the high short circuit IGBT current to prevent

damaging voltage spikes. Before the dissipated energy

can reach destructive levels, the IGBT is shut o. During

the o state of the IGBT, the fault detect circuitry is simply

disabled to prevent false ‘fault’ signals.

The alternative protection scheme of measuring IGBT

current to prevent desaturation is eective if the short

circuit capability of the power device is known, but

this method will fail if the gate drive voltage decreases

enough to only partially turn on the IGBT. By directly

measuring the collector voltage, the ACPL-330J limits

the power dissipation in the IGBT even with insucient

gate drive voltage. Another more subtle advantage of the

desaturation detection method is that power dissipation

in the IGBT is monitored, while the current sense method

relies on a preset current threshold to predict the safe

limit of operation. Therefore, an overly conservative over

current threshold is not needed to protect the IGBT.

Slow IGBT Gate Discharge during Fault Condition

When a desaturation fault is detected, a weak pull-down

device in the ACPL-330J output drive stage will turn on

to ‘softly’ turn o the IGBT. This device slowly discharges

the IGBT gate to prevent fast changes in drain current

that could cause damaging voltage spikes due to lead

and wire inductance. During the slow turn o, the large

output pull-down device remains o until the output

voltage falls below VEE + 2 Volts, at which time the large

pull down device clamps the IGBT gate to VEE.

DESAT Fault Detection Blanking Time

The DESAT fault detection circuitry must remain disabled

for a short time period following the turn-on of the IGBT

to allow the collector voltage to fall below the DESAT

threshold. This time period, called the DESAT blanking

time is controlled by the internal DESAT charge current,

the DESAT voltage threshold, and the external DESAT

capacitor.

The nominal blanking time is calculated in terms of

external capacitance (CBLANK), FAULT threshold voltage

(VDESAT), and DESAT charge current (ICHG) as tBLANK =

CBLANK x VDESAT / ICHG. The nominal blanking time with

the recommended 100pF capacitor is 100pF * 6.5 V / 240

µA = 2.7 µsec.

The capacitance value can be scaled slightly to adjust the

blanking time, though a value smaller than 100 pF is not

recommended. This nominal blanking time represents

the longest time it will take for the ACPL-330J to respond

to a DESAT fault condition. If the IGBT is turned on while

the collector and emitter are shorted to the supply rails

(switching into a short), the soft shut-down sequence

will begin after approximately 3 µsec. If the IGBT collector

and emitter are shorted to the supply rails after the IGBT

is already on, the response time will be much quicker due

to the parasitic parallel capacitance of the DESAT diode.

The recommended 100pF capacitor should provide

adequate blanking as well as fault response times for

most applications.

IFUVLO(VCC2-VE) DESAT Function Pin 3 (FAULT) Output VOUT

ON Active Not Active High Low

ON Not Active Active (with DESAT fault) Low (FAULT) Low

ON Not Active Active (no DESAT fault) High (or no fault) High

OFF Active Not Active High Low

OFF Not Active Not Active High Low

Figure 35. Output pull-down resistor.

DESAT Pin Protection Resistor

The freewheeling of yback diodes connected across

the IGBTs can have large instantaneous forward voltage

transients which greatly exceed the nominal forward

voltage of the diode. This may result in a large negative

voltage spike on the DESAT pin which will draw substan-

tial current out of the driver if protection is not used. To

limit this current to levels that will not damage the driver

IC, a 100 ohm resistor should be inserted in series with

the DESAT diode. The added resistance will not alter the

DESAT threshold or the DESAT blanking time.

Figure 36. DESAT pin protection.

VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

FAULT

CATHODE

ANODE

CATHODE

RPULL-DOWN

VCC

VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

FAULT

CATHODE

ANODE

CATHODE

RPULL-DOWN

VCC

LED

DESAT

CC2

OUT

CLAMP

CC1

FAULT

CATHODE

ANODE

CATHODE

100 Ω

100pF

DESAT

Under Voltage Lockout

The ACPL-330J Under Voltage Lockout (UVLO) feature is

designed to prevent the application of insucient gate

voltage to the IGBT by forcing the ACPL-330J output

low during power-up. IGBTs typically require gate

voltages of 15 V to achieve their rated VCE(ON) voltage.

At gate voltages below 13 V typically, the VCE(ON) voltage

increases dramatically, especially at higher currents.

At very low gate voltages (below 10 V), the IGBT may

operate in the linear region and quickly overheat.

The UVLO function causes the output to be clamped

whenever insucient operating supply (VCC2) is applied.

Once VCC2 exceeds VUVLO+ (the positive-going UVLO

threshold), the UVLO clamp is released to allow the

device output to turn on in response to input signals. As

VCC2 is increased from 0 V (at some level below VUVLO+),

rst the DESAT protection circuitry becomes active. As

VCC2 is further increased (above VUVLO+), the UVLO clamp

is released. Before the time the UVLO clamp is released,

the DESAT protection is already active. Therefore, the

UVLO and DESAT Fault detection feature work together

to provide seamless protection regardless of supply

voltage (VCC2).

Active Miller Clamp

A Miller clamp allows the control of the Miller current

during a high dV/dt situation and can eliminate the use

of a negative supply voltage in most of the applications.

During turn-o, the gate voltage is monitored and the

clamp output is activated when gate voltage goes below

2V (relative to VEE). The clamp voltage is VOL+2.5V typ

for a Miller current up to 1100mA. The clamp is disabled

when the LED input is triggered again.

Other Recommended Components

The application circuit in Figure 33 includes an output

pull-down resistor, a DESAT pin protection resistor, a

FAULT pin capacitor, and a FAULT pin pullup resistor and

Active Miller Clamp connection.

Output Pull-Down Resistor

During the output high transition, the output voltage

rapidly rises to within 3 diode drops of VCC2. If the output

current then drops to zero due to a capacitive load, the

output voltage will slowly rise from roughly VCC2-3(VBE)

to VCC2 within a period of several microseconds. To limit

the output voltage to VCC2-3(VBE), a pull-down resistor,

RPULL-DOWN between the output and VEE is recommend-

ed to sink a static current of several 650 µA while the

output is high. Pull-down resistor values are dependent

on the amount of positive supply and can be adjusted

according to the formula, Rpull-down = [VCC2-3 * (VBE)] /

650 µA.

Pull-up Resistor on FAULT Pin

The FAULT pin is an open collector output and therefore

requires a pull-up resistor to provide a high-level signal.

Also the FAULT output can be wire ‘OR’ed together with

other types of protection (e.g. over-temperature, over-

voltage, over-current ) to alert the microcontroller.

Figure 38. Large IGBT drive with negative gate drive, external booster. VCLAMP control secondary discharge path for higher power application.

Figure 37. IGBT drive with negative gate drive, external booster and desaturation detection (VCLAMP should be connected to VEE when it is not used) VCLAMP is

used as secondary gate discharge path. * indicates component required for negative gate drive topology

Other Possible Application Circuit (Output Stage)

VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

FAULT

CATHODE

ANODE

CATHODE

VCE

RPULL-DOWN

+ HVDC

-HVDC

3-PHASE

VCE

01F 01F

01F

O R 1

O R 2



VLED

DESAT

VCC2

VEE

VOUT

VCLAMP

VEE

VCC1

FAULT

CATHODE

ANODE

CATHODE

VCE

RPULL-DOWN

+ HVDC

-HVDC

3-PHASE

VCE

01F 01F

01F

O R 1

O R 2



Capacitor on FAULT Pin for High CMR

Rapid common mode transients can aect the fault pin

voltage while the fault output is in the high state. A 1000

pF capacitor should be connected between the fault pin

and ground to achieve adequate CMOS noise margins at

the specied CMR value of 50 kV/µs.

Related Application Notes

AN5314 – Active Miller Clamp

AN5315 – “Soft” Turn-o Feature

AN1043 – Common-Mode Noise : Sources and Solutions

AV02-0310EN - Plastic Optocouplers Product ESD and Moisture Sensitivity

Thermal Model

The ACPL-330J is designed to dissipate the majority of

the heat through pins 1, 4, 5 & 8 for the input IC and pins

9 & 12 for the output IC. (There are two VEE pins on the

output side, pins 9 and 12, for this purpose.) Heat ow

through other pins or through the package directly into

ambient are considered negligible and not modeled

here.

In order to achieve the power dissipation specied in

the absolute maximum specication, it is imperative

that pins 5, 9, and 12 have ground planes connected to

them. As long as the maximum power specication is

not exceeded, the only other limitation to the amount

of power one can dissipate is the absolute maximum

junction temperature specication of 125°C. The junction

temperatures can be calculated with the following

equations:

Tji = Pi (θi5 + θ5A) + TA

Tjo = Po (θo9,12 + θ9,12A) + TA

where Pi = power into input IC and Po = power into

output IC. Since θ5A and θ9,12A are dependent on PCB

layout and airow, their exact number may not be

available. Therefore, a more accurate method of calcu-

lating the junction temperature is with the following

equations:

Tji = Pi θi5 + TP5

Tjo = Po θo9,12 + TP9,12

These equations, however, require that the pin 5 and pins

9, 12 temperatures be measured with a thermal couple

on the pin at the ACPL-330J package edge.

If the calculated junction temperatures for the thermal

model in Figure 39 is higher than 125°C, the pin tem-

perature for pins 9 and 12 should be measured (at the

package edge) under worst case operating environment

for a more accurate estimate of the junction tempera-

tures.

Figure 39. ACPL-330J Thermal Model

Tji = junction temperature of input side IC

Tjo = junction temperature of output side IC

TP5 = pin 5 temperature at package edge

TP9,12 = pin 9 and 12 temperature at package edge

θI5 = input side IC to pin 5 thermal resistance

θo9,12 = output side IC to pin 9 and 12 thermal resistance

θ5A = pin 5 to ambient thermal resistance

θ9,12A = pin 9 and 12 to ambient thermal resistance

*The θ5A and θ9,12A values shown here are for PCB layouts with reasonable air ow.

This value may increase or decrease by a factor of 2 depending on PCB layout and/or airow.

TP1 TP9, 12

θ1A = 50°C/W*

Tji

θI1 = 60°C/W

θ9, 12A = 50°C/W*

θl9, 12 = 30°C/W

Tjo

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AV02-1280EN - November 20, 2015