1EDI3023AS_技术文档

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

Features

•

Single channel isolated IGBT driver using coreless transformer technology

For IGBTs up to 1200 V

CMTI up to 150 V/ns at 1000 V

8 kV basic insulation according to VDE V 0884-11:2017-01

Basic insulation recognized according to UL 1577

Min. 12 A peak current rail-to-rail output

Propagation delay 60 ns typical

Typ. 10 A integrated Active Miller Clamp supports unipolar switching

Integrated ADC for DC-link measurements

Integrated safety features to support ASIL B(D):

-

Redundant DESAT and OCP protection

Gate and output stage monitoring

Shoot-through protection

Primary/secondary supply monitoring

Internal supervision

•

ISO 26262 Safety Element out of Context for safety requirements up to

ASIL B

Green Product (RoHS compliant)

Potential applications

•

Traction inverters for HEV and EV

Auxiliary inverters for HEV and EV

High power DC/DC converters

Product validation

Qualified for automotive applications. Product validation according to AEC-Q100.

Description

The EiceDRIVER^™gate driver 1EDI3023AS is a high-voltage IGBT driver designed for automotive motor drives

above 5 kW. The device is based on Infineon’s coreless transformer (CT) technology, providing galvanic

insulation between low voltage and high voltage domains. The device has been designed to support 400 V,

600 V and 1200 V IGBT technologies.

Datasheet

Please read the sections "Important notice" and "Warnings" at the end of this document

Rev. 1.1

2022-02-17

www.infineon.com/isolated-high-voltage-gate-driver

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

Description

The device features a high output stage of minimum 12 A peak current. A comprehensive feature set allows

advanced protection of the device and the power switch, as well as optimized driver performance and

robustness.

The device can be connected on the low voltage side (“primary” side) to 5 V and 3.3 V logic.

On the high voltage side (secondary side), the device is dimensioned to drive the gate of IGBTs directly. Short

propagation delays and controlled internal tolerances lead to a minimal distortion of the PWM signal. In

addition, there is a Miller clamping stage with minimum 12 A integrated, which allows unipolar supply of the

IGBT.

The device features an integrated ADC for DC link measurement and a detailed error diagnosis via a PWM signal.

A large panel of safety related functions supports functional safety requirements at system level as per

ISO 26262. Besides, these integrated features ease the implementation of a transition to safe-state.

Type

Package

Marking

1EDI3023AS

PG-DSO-20

1EDI3023AS

Datasheet

2

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

Table of contents

Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Potential applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Product validation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Table of contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

1

2

Pin configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6

2.1

Pin definitions and functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6

3

General product characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8

Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8

Functional range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9

Thermal characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10

Insulation characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12

3.1

3.2

3.3

3.4

4

Operating modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14

Operating modes diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14

Operating modes description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14

Single failure events in Normal_Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15

4.1

4.2

4.3

5

5.1

5.2

Power supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

Bipolar and unipolar supplies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

Electrical characteristics power supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

6

6.1

6.2

Switching characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18

Functional description switching . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18

Electrical characteristics switching . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18

7

Protection and monitoring functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .20

DESAT protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

Over Current Protection (OCP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22

Safe turn-oﬀ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24

Shoot Through Protection (STP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26

Power supply monitoring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

Gate monitoring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29

Output stage monitoring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .31

7.1

7.2

7.3

7.4

7.5

7.6

7.7

8

8.1

8.2

Clamping functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35

Active Miller clamp . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35

Passive clamping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36

9

Analog-to-Digital Converter (ADC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37

9.1

Functional description ADC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37

Datasheet

3

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

Table of contents

9.2

Electrical characteristics ADC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .38

10

Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .40

Reset (NRST) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .40

Ready (RDY) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

Fault (NFLT) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41

I/O levels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42

DATA read-out . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42

10.1

10.2

10.3

10.4

10.5

11

11.1

11.2

Application information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46

Electrical characteristics external components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46

Typical application example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47

12

Package information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48

Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49

Disclaimer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50

Datasheet

4

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

1 Block diagram

1

Block diagram

GND2

VCC1

GND1

INP

P-Supply

VEE2

P-Supply

VCC2

PWM

Input

Stage

Output

Stage

-

Switching

Control

TOUT

INN

Secon-

dary

Primary

Logic

CLAMP/GATE

NFLT

NRST

Logic

DESAT

OCP

OCPP

OCPN

EN

RDY

AIP

DATA

ADC

GND2

Figure 1

Block diagram

Datasheet

5

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

2 Pin configuration

2

Pin configuration

GND1

VEE2

OCPP

1

2

20

19

18

17

16

15

14

13

12

11

VCC1

DATA

NFLT

RDY

NRST

EN

OCPN

3

AIP

4

GND2

5

DESAT

VCC2

6

7

INN

TOUT

8

INP

GATE/CLAMP

VEE2

9

GND1

10

Figure 2

Pin assignment

2.1

Pin definitions and functions

Table 1

Pin definition and functions

Pin # Pin name

I/O

Voltage

class

Function

1

2

3

GND1

VCC1

DATA

Ground

Supply

Output

Primary

ground

Ground connection for the primary side.

Primary

supply

5 V/3.3 V power supply for the primary side (referring to

GND1).

5 V primary The data pin is used for ADC or diagnosis data. This pin is a

push-pull output which is driving a PWM signal according to

the data.

4

5

NFLT

RDY

Output

5 V primary The fault open-drain signal is used to report failure events

triggered by DESAT or OCP protection. As a result the pin is

driven to low. This pin has to be connected externally to VCC1

with a pull-up resistance.

5 V primary The ready open-drain signal is used to report failure events

like UVLO1, UVLO2, OVLO2, Life Sign Lost, Output Stage Error,

Gate Monitoring Error, etc. As a result this pin is driven to

low. This pin has to be connected externally to VCC1 with a

pull-up resistance.

6

7

NRST

EN

Input

5 V primary The reset signal is used to clear the failure/fault events which

triggered RDY or NFLT active low. The signal is clearing an

error on rising edge. An internal pull-down resistance is

driving this pin to low state in case the pin is floating.

5 V primary The enable signal allows the logic on the primary side to

enable or disable the device. The logic levels are according

(table continues...)

Datasheet

6

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

2 Pin configuration

Table 1

(continued) Pin definition and functions

Pin # Pin name

I/O

Voltage

class

Function

to the used power supply. An internal weak pull-down

resistance is disabling the device in case the pin is floating.

8

9

INN

INP

Input

5 V primary The inverting PWM signal is used for monitoring for shoot

through protection. An internal weak pull-up resistor to VCC1

drives this input to high state in case the pin is floating.

5 V primary The non-inverting PWM signal of the driver. An internal weak

pull-down resistor to GND1 drives this input to low state in

case the pin is floating.

10

11

12

GND1

VEE2

Ground

Supply

Primary

ground

Ground connection for the primary side.

Secondary Negative power supply for the secondary side (referring to

supply

GND2).

GATE/

CLAMP

Input/

Output

15 V

The gate monitoring and clamp signal is monitoring the gate

secondary of the power switch and clamping the gate to VEE2 if the

threshold VCLAMP is reached.

13

14

15

TOUT

VCC2

Output

Supply

Input

15 V

The transistor drive voltage signal switches the power switch

secondary gate to VCC2 or VEE2, according to the PWM input.

Secondary Positive power supply for the secondary side (referring to

supply

GND2).

DESAT

15 V

The desaturation protection signal monitors the voltage

secondary across the power switch. An internal current source to VCC2

drives this signal to high level in case it is floating.

16

17

18

GND2

AIP

Ground

Input

Secondary Reference ground for the secondary side.

ground

5 V

The ADC function can be used to monitor the DC-link voltage.

secondary The internal current source is disabled.

OCPN

Input

5 V

The negative over current protection signal is diﬀerential

secondary therefore it should be always close to OCPP signal. A

common-mode filter should be applied to the OCPP signal.

19

20

OCPP

VEE2

Input

5 V

The positive over current protection signal is diﬀerential

secondary therefore it should be always close to OCPN signal. A

common-mode filter should be applied to the OCPN signal.

An internal weak pull-up resistor drives this input to high

state in case the pin is floating.

Supply

Secondary Negative power supply for the secondary side (referring to

supply

GND2).

Datasheet

7

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

3 General product characteristics

3

General product characteristics

3.1

Absolute maximum ratings

Table 2

Absolute maximum ratings

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified). Absolute maximum ratings are defined as ratings which when being exceeded may lead to

destruction of the integrated circuit. Absolute maximum ratings are not subject to production test, specified by

design.

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Positive

power supply

(primary)

V_{VCC1_MAX}-0.3

V_{VCC2_MAX}-0.3

V_{VEE2_MAX}-13

–

7

V

Referenced to GND1

PRQ-560

PRQ-561

PRQ-562

PRQ-563

Positive

power supply

(secondary)

30

0.3

40

V

Referenced to GND2

Negative

power supply

(secondary)

Power supply V_VCC2-

voltage

–

VEE2_MAX

diﬀerence

(secondary)

VCC2-VEE2

Voltages on V_{INx_MAX}

any I/O pin

-0.3

–

V_VCC1

+ 0.3

V

Referenced to GND1

PRQ-564

on primary

side (INP,

INN, NRST,

DATA, RDY,

NFLT, EN)

AIP voltage

V_{AIP_MAX}

-0.3

–

V_VCC2

+ 0.3

V

PRQ-789

PRQ-566

DESAT

voltage

V_{DESAT_MAX}-0.3

V_VCC2

+ 0.3

Referenced to GND2

OCPP

OCPN

V_{OCPP_MAX}-2.8

V_{OCPN_MAX}-2.8

–

2.8

V

Referenced to GND2

PRQ-788

PRQ-831

PRQ-567

Maximum

Clamp/gate

voltage

V_Clamp/

V_VEE2

- 0.3

V_VCC2

+ 0.3

Gate_MAX

TOUT voltage V_{OUT_MAX}V_VEE2

–

V_VCC2

+ 0.3

V

Referenced to GND2

PRQ-568

- 0.3

(table continues...)

Datasheet

8

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

3 General product characteristics

Table 2

(continued) Absolute maximum ratings

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified). Absolute maximum ratings are defined as ratings which when being exceeded may lead to

destruction of the integrated circuit. Absolute maximum ratings are not subject to production test, specified by

design.

Parameter Symbol

Values

Unit Note or condition

P-

Number

Min. Typ. Max.

TOUT high

output

maximum

current

I_{OUTH_MAX}-15

–

A

t_MAX= 1.5 µs, non-repetitive

PRQ-569

PRQ-570

PRQ-848

TOUT low

output

maximum

current

I_{OUTL_MAX}

–

15

t_MAX= 1.5 µs, non-repetitive

Gate/Clamp I_Gate/

low

Clamp_Max

maximum

output

current

Current on

output logic

pins (DATA,

RDY, NFLT)

|I_{OUTx_MAX}

|

–

10

2

mA

kV

PRQ-572

ESD

immunity

V_{ESD_HBM}-2

T_{s_MAX}-55

T_{J_MAX}-40

–

HBM according to AEC Q100-002, CDM

according to AEC Q100-011

PRQ-573

PRQ-575

PRQ-790

Storage

temperature

150 ^οC

150 ºC

Junction

temperature

3.2

Functional range

Table 3

Functional range

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter Symbol

Values

Unit Note or condition

P-

Number

Min. Typ. Max.

Positive

power supply

(primary)

V_VCC1

3

–

5.5

V

Referenced to GND1

PRQ-579

PRQ-797

VCC1 ramp- t_RP1

up slew-rate

–

2000 V/ms

(table continues...)

Datasheet

9

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

3 General product characteristics

Table 3

(continued) Functional range

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

VCC2 ramp- t_RP2

0.65

0

–

1000 V/ms

PRQ-798

PRQ-581

up slew-rate

Negative

V_VEE2

-11.5 -5

0

V

Referenced to GND2

power supply

(secondary)

VEE2 ramp- t_RP3

-0.10 –

0

-100 V/ms

0

PRQ-799

PRQ-582

up slew-rate

Power supply V_VCC2-VEE2

voltage

diﬀerence

–

25

V

(secondary)

VCC2-VEE2

Junction

T_J

-40

–

150 ^οC

150 kV/µs For voltages up to 1000 V

PRQ-588

PRQ-589

temperature

Common

mode

dV_ISO/dt

-150

transient

immunity

Voltages on V_INx

any I/O pin

on primary

side (INP,

0

–

V_VCC1

V

Referenced to GND1

PRQ-583

INN, NRST,

DATA, RDY,

NFLT)

3.3

Thermal characteristics

The thermal capability of the device is depending on the used power module. The following formula and

parameters can be used to calculate the maximum switching frequency for a dedicated power module:

Figure 3

Formula to calculate the maximum switching frequency in application

Where the maximum switching losses are P_SW= P_DIS2- P_{IDLE_sec}, R_gis the external gate resistor, C_Gateis the

maximum gate charge of the power switch, and R_DSON-OSLNis the internal gate resistor.

Note:

This formula is only valid if ON/OFF resistors have the same value.

Datasheet

10

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

3 General product characteristics

3.3.1

Thermal characteristics parameters

Table 4

Thermal characteristics parameters

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Power

Dissipation -

Primary Chip

P_DIS1

–

40

–

mW

T_AMB= 25°C, V_VCC1= 5 V, PWM duty cycle

= 50%, Normal_Mode, no C_LOAD, no R_LOAD

on TOUT, average value (peak current

neglected)

PRQ-946

Power

P_DIS2

–

300

–

mW

T_AMB= 25°C, V_VCC2= typ., V_VEE2= typ., PWM PRQ-947

Dissipation -

Secondary

Chip

duty cycle = 50%, Normal_Mode, no C_LOAD

no R_LOADon TOUT, average value (peak

current neglected)

,

Switching

frequency

f_SW

–

25

85

430 kHz

V_VCC2= 18 V, V_VEE2= -5 V, C_Gate= 9 nF, R_g= 6 PRQ-839

Ω, T_AMB= 25°C

Thermal

Resistance

Junction to

Ambient

(25°C)

R_THJA

–

K/W

T_amb= 25°C

T_AMB= 125°C

T_amb= 25°C

PRQ-932

PRQ-975

PRQ-933

Thermal

Resistance

Junction to

Ambient

(125°C)

R_THJA,125

–

71

60

Thermal

Resistance

Junction to

Case

R_THJCBOT

(bottom)

Thermal

R_THJCTOP

R_THJBOARD

R_PSIJT

–

52

–

K/W

PRQ-934

PRQ-1031

PRQ-935

Resistance

Junction to

Case (top)

Thermal

45.4

21

T_amb= 25°C, power losses on secondary

side ≤ 500 mW, power losses on primary

side ≤ 50 mW

Resistance

Junction to

Board (25°C)

Ψ - Pseudo

T_amb= 25°C

Thermal

Resistance

Junction to

Case (top)

Datasheet

11

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

3 General product characteristics

Note:

This thermal data was generated in accordance with JEDEC JESD51 standards. For more information,

go to www.jedec.org.

3.4

Insulation characteristics

Table 5

Insulation characteristics for reinforced and basic insulation in compliance with DIN

VDE V 0884-11:2017-01. Input to output test conditions according to method a) and b)

follow the more stringent requirements as of reinforced insulation.

Description

Symbol

Value

Unit

Installation classification per IEC 60664-1, Table F.1

for rated mains voltage ≤ 150 V_RMS

–

I-IV

–

for rated mains voltage ≤ 300 V_RMS

I-IV

for rated mains voltage ≤ 600 V_RMS

for rated mains voltage ≤ 1000 V_RMS

I-III (IV for basic)

I-II (III for basic)

Climatic classification

40/125/21

–

Pollution degree (IEC 60664-1)

Minimum external creepage

Minimum external clearance

Minimum comparative tracking index

Maximum repetitive insulation voltage

2

8

–

CPG

CLR

CTI

mm

–

8

400

1767

V_{IORM,reinforce}

V_PEAK

d

V_IORM,basic

1420

8000

6875

Maximum rated transient insulation voltage

V_IOTM

V_PEAK

Maximum surge insulation voltage for reinforced insulation

V_{IOSM,reinforce}

d

Test voltage in subgroup #1 = 1.6 * V_{IOSM,reinforced}= 11kV

Maximum surge insulation voltage for basic insulation

V_IOSM,basic

8000

V_PEAK

Test voltage in subgroup #1 = 1.3 * V_IOSM,basic= 10.4kV

Input to output test voltage, method b) V_ini,b= 1.2 * V_iotm, V_pd(m)

V_{iorm,reinforced}* 1.875, 100% production test with t_ini,b= 1 s

=

q_pd

< 5

pC

Input to output test voltage, method a) V_ini,a= V_iotm, V_pd(m)

V_{iorm,reinforced}* 1.6, sample test with t_ini,a= 60 s

=

Insulation resistance at 100 °C ≤ T_amb≤ 125 °C, V_io= 500 V

Insulation resistance at T_S= 150 °C, V_io= 500 V

R_IO

>10¹²

>10⁹

Ω

R_{IO_S}

Table 6

Insulation characteristics recognized according to UL 1577

Parameter

Symbol

Characteristic

Unit

Insulation withstand

voltage / 1 min

V_ISO

5700

V(rms)

Insulation test voltage / 1 s V_ISO

6000

V(rms)

(table continues...)

Datasheet

12

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

3 General product characteristics

Table 6

(continued) Insulation characteristics recognized according to UL 1577

Symbol Characteristic Unit

Parameter

Note:

The insulation characteristics only apply when the device is operated within the safety limits given by

the absolute maximum ratings.

Datasheet

13

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

4 Operating modes

4

Operating modes

4.1

Operating modes diagram

NRST = 0 | 1

Normal_Mode

Outputs:

DATA: ADC

RDY = 1

NFLT = 1

Inputs enabled²⁾

Ready_Mode

Outputs:

DATA: DIAG

RDY = 1

EN = 1

EN = 0

NFLT = 1

Power_Down

Outputs:

DATA = DIAG

RDY = 0 (pas. clamp)

NFLT = 1

Error_Mode

Outputs:

DATA: ADC (EN=1)⁴⁾

DATA: DIAG (EN=0)

RDY = 0 or NFTL = 0

Ready lost³⁾-> RDY = 0

DESAT or OCP -> NFLT = 0

1) Device ready: no OSM Error, no Gate Monitoring Error, no OVLO2, no UVLO2, no open pin at OCPx, no Prim. or Sec. Internal Supervision Error, OTP read ok

2) INP & INN are enabled

3) Device not ready: OSM Error, Gate Monitoring Error, OVLO2, UVLO2, OCPx open pin, Sec. Internal Supervision Error, OTP read error

4) At life sign loss ADC signal at DATA pin output is static 0

Figure 4

Operating modes state diagram

Note:

•

Life sign lost will be detected only if communication has been established once.

External pull-up required on RDY and NFLT (open drain output)

4.2

Operating modes description

The device has the following modes which it can operate in:

•

Ready_Mode (not enabled)

Error_Mode (Failure/Fault event occurred)

Normal_Mode (Device enabled)

Reset

If the NRST signal is low the device keeps its operating mode (no influence on PWM). Further the rising edge on

NRST signal will reset the failure/fault event memory.

Datasheet

14

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

4 Operating modes

Power Down and Start up

The device is in Power_Down_Mode at start-up or if an UVLO1 error occurs. In both cases it will not operate. If

the device is partly supplied (e.g. VCC1 only) the device will enter Error_Mode. Therefore supplies should rise

within the specified slew rates to a valid voltage level according to given operating conditions. Aferwards a

rising edge on NRST will bring the device into Ready_Mode (no Failure or Fault Event occurred).

Mode Transitions

Once in Ready_Mode the change to Normal_Mode can be done with setting EN signal to "high level" (voltage

level diﬀers with VCC1 level), changing it to "low level" is also the returning into Ready_Mode. The transition

into Error_Mode can only be done with the according events which are:

•

OCP event

DESAT event

UVLO2 event

OVLO2 event

Sec. Internal Supervision Error

Output Stage Monitor Error

Gate Monitoring Error

OCPx pin open

OTP read error

Error_Mode

In Error_Mode a "low level" on signal EN will issue diagnosis information on the DATA pin. This diagnosis

information states details about the failure root cause. A "high level" on signal EN issues the ADC information,

identical to Normal_Mode.

A rising edge on NRST and no failure or fault active will transition the device back to Ready_Mode (or to

Normal_Mode if signal EN is set). In Ready_Mode diagnosis information is available on the DATA pin. See also

the operating modes diagram for further information.

4.3

Single failure events in Normal_Mode

Table 7

Single failure events in Normal_Mode

Failure Event

Output stage

reaction

Resulting pin status changes

DESAT when TOUT = high (VCC2) Safe turn-oﬀ

NFLT = 0; DATA: ADC (EN = 1), DATA: DIAG (EN = 0)

RDY = 0; DATA: ADC (EN = 1), DATA: DIAG (EN = 0)

OCP when TOUT = high (VCC2)

Gate monitoring error

Safe turn-oﬀ

Safe turn-oﬀ when

TOUT = high (VCC2)

OSM error

Tri-state

RDY = 0; DATA: ADC (EN = 1), DATA: DIAG (EN = 0)

RDY = 0; DATA = 0

UVLO2

Normal switch-oﬀ

OVLO2

UVLO1

Prim. internal supervision error

Sec. internal supervision error

OCPx pin open

RDY = 0; DATA = 0

RDY = 0; DATA: ADC (EN = 1), DATA: DIAG (EN = 0)

Datasheet

15

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

5 Power supply

5

Power supply

5.1

Bipolar and unipolar supplies

The device is designed to support two diﬀerent supply configurations, bipolar supply and unipolar supply.

Note:

In bipolar supply the driver is typically supplied with a positive voltage of 15 V at VCC2 and a negative

voltage of -5 V at VEE2 (referenced to GND2). The negative supply prevents a dynamic turn on due

to the additional charge which is generated from the input capacitance current of the power switch

times the negative supply voltage. GATE/CLAMP has to be connected to the gate of the power switch in

all power supply configurations.

5.2

Electrical characteristics power supply

Table 8

Electrical characteristics power supply

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Quiescent

Current Input

Chip (VCC1)

I_QVCC1

3

5

–

mA

Ready_Mode, all primary I/Os without

impact on Ready_Mode open, V_VCC1= 5

V, V_VCC2= 15 V, V_VEE2= -5 V

PRQ-937

PRQ-938

Operating

Current VCC1

(TOUT = high

(VCC2))

I_{QPVCC1_ON}

I_{OPVCC1_OFF}

I_{OPVCC2_ON}

–

10

12

mA

Normal_Mode, INN = 0, INP = 1, EN = 1,

NRST = 1, outputs open,V_VCC1= 5 V, V_VCC2

15 V, V_VEE2= -5 V

=

Operating

Current VCC1

(TOUT = low

(VEE2))

–

5.5

11

7

Normal_Mode, INN = 0, INP = 0, EN = 1,

NRST = 1, outputs open, V_VCC1= 5 V, V_VCC2

15 V, V_VEE2= -5 V

PRQ-939

=

Operating

Current VCC2

(TOUT = high

(VCC2))

13

Normal_Mode, INN = 0, INP = 1, EN = 1,

NRST = 1, primary outputs open, OCPx = 0,

DESAT = 0, Gate shorted to TOUT, V_VCC1

5 V, V_VCC2= 15 V, V_VEE2= -5 V, other pins

open

PRQ-1036

=

Operating

Current VCC2

(TOUT = low

(VEE2))

I_{OPVCC2_OFF}

6

–

11

13

2

mA

Normal_Mode, INN = 0, INP = 0, EN = 1,

PRQ-1037

PRQ-944

PRQ-945

NRST = 1, primary outputs open, OCPx = 0,

DESAT = 0, Gate shorted to TOUT, V_VCC1

5 V, V_VCC2= 15 V, V_VEE2= -5 V, other pins

open

=

Operating

Current VEE2

(TOUT = high

(VCC2))

I_{OPVEE2_ON}

1.5

Normal_Mode, INN = 0, INP = 1, EN = 1,

NRST = 1, primary outputs open, OCPx = 0,

DESAT = 0, Gate shorted to TOUT, V_VCC1

5 V, V_VCC2= 15 V, V_VEE2= -5 V, other pins

open

=

Operating

Current VEE2

I_{OPVEE2_OFF}0.5

2

Normal_Mode, INN = 0, INP = 0, EN = 1,

NRST = 1, primary outputs open, OCPx = 0,

(table continues...)

Datasheet

16

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

5 Power supply

Table 8

(continued) Electrical characteristics power supply

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

(TOUT = low

(VEE2))

DESAT = 0, Gate shorted to TOUT, V_VCC1

5 V, V_VCC2= 15 V, V_VEE2= -5 V, other pins

open

=

Datasheet

17

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

6 Switching characteristics

6

Switching characteristics

6.1

Functional description switching

The voltage on pin TOUT ranges from V_VEE2to V_VCC2(referenced to GND2).

The device supports short propagation delay for On and Oﬀ switching of t_PDONand t_PDOFF

.

6.2

Electrical characteristics switching

Table 9

Electrical characteristics switching

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter

Symbol

Values

Min. Typ. Max.

- 12

Unit

Note or condition

P-

Number

High level

output peak

current

I_OUTH

A

INP = V_VCC1, INN = V_GND1, EN = V_VCC1,TOUT

= V_VCC2, CLAMP/GATE = V_VEE2,V_VCC2= 15 V,

V_VEE2= -5 V, C_LOAD= 200 nF

PRQ-662

Low level

output peak

current

I_OUTL

12

A

INP = V_GND1, INN = V_GND1, EN = V_VCC1,TOUT PRQ-663

= V_VEE2, CLAMP/GATE = V_VCC2,V_VCC2= 15 V,

V_VEE2= -5 V, C_LOAD= 200 nF

Propagation t_PDON

40

60

120 ns

VCC1 = typ., VCC2 = typ., VEE2 = typ.,

PRQ-770

delay - On

Start: INP rising edge at V_{digital,input(high)},

Stop: TOUT rising edge at V_VEE2+ 1.5 V, no

load, no gate resistance

Propagation t_PDOFF

delay - Oﬀ

120 ns

VCC1 = typ., VCC2 = typ., VEE2 = typ.,

PRQ-851

Start: INP falling edge at V_{digital,input(low)}

,

Stop: TOUT falling edge at V_VCC2- 1.5 V, no

load, no gate resistance

Propagation t_Prop,dis

delay

-20

10

–

20

ns

t_PDON- t_PDOFF,t_PDON& t_PDOFFmeasured @

same T_JUNC

PRQ-803

PRQ-968

distortion

Propagation t_PDENON

delay EN to

turn-on (INP

= high)

60

120 ns

V_VCC1= typ.; V_VCC2= typ., V_VEE2= typ., INP

= high, INN = GND1, TOUT = V_VEE2+ 1.5 V,

referring to VEE2 (rising edge)

Propagation t_PDENOFF

delay EN to

turn-oﬀ (INP

= high)

10

60

V_VCC1= typ., V_VCC2= typ., V_VEE2= typ., INP

= high, INN = GND1, TOUT = V_VCC2- 1.5

V referring to VEE2 (falling edge)

PRQ-967

TOUT rise

time 90 %

t_Rise1

–

55

35

ns

no C_LOAD, no R_LOAD, V_VCC2= typ., V_VEE2

=

PRQ-801

PRQ-958

typ. V_TOUT= V_VEE2+ 1.5 V to V_TOUT= V_VCC2

-

1.5 V

TOUT rise

time 70 %

t_Rise2

no C_LOAD,no R_LOAD, V_VCC2= typ., V_VEE2=

typ., V_TOUT= V_VEE2+ 1.5 V to V_TOUT= V_VCC2

-

6 V

(table continues...)

Datasheet

18

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

6 Switching characteristics

Table 9

(continued) Electrical characteristics switching

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Fall time

t_Fall

–

45

ns

No C_LOAD, no R_LOAD, V_VCC2= typ., V_VEE2

= typ., V_TOUT= V_VCC2- 1.5 V to V_TOUT

V_VEE2+ 1.5 V

PRQ-802

=

TOUT RDSON R_DSON-

High-side

0.30

–

Ω

N-MOS, tolerances according to R_DSON-OSLNPRQ-1032

OSHN

TOUT RDSON R_DSON-

0.3

1

N-MOS and P-MOS, voltage drop V_VCC2

V_TOUT< 1 V

-

PRQ-849

PRQ-850

High-side

P&N

OSHtot

TOUT RDSON R_DSON-OSLN0.07

Low-side

–

0.35

N-MOS, voltage drop V_TOUT- V_VEE2< 1 V

Note:

The defined minimum/maximum value of I_OUTxis the minimum current which the device delivers

under the given conditions. In general the device is capable to delives higher output currents than the

defined minimum/maximum. The maximum output current needs to be limited by an external gate

resistor to stay inside the defined absolute maximum rating parameters regarding maximum peak

current (equivalent energy needs to be considered) and maximum junction temperature.

Datasheet

19

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

7

Protection and monitoring functions

7.1

DESAT protection

7.1.1

Functional description DESAT protection

The device monitors the voltage across the power switch when TOUT = high(VCC2), afer the DESAT blanking

time is elapsed. If the corresponding reference level (V_DESATx) is reached, it issues a safe turn-oﬀ within

t_DESAT2OFF, then changes into Error_Mode and signals a NFLT low in t_{NFLT_DESAT}

.

Vcc2

Logic

NFTL trigger

DESAT

Voltage

Comp

DSAT

Divider

Fixed Vref

Clamping_active

GND2

Figure 5

DESAT diagram of principal functionality

The DESAT pin has an internal clamping which clamps DESAT to V_DESATLin case TOUT = low (VEE2), TOUT =

V_SOﬀPLTor in case of OSM (tristate).

Datasheet

20

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

Internal DESAT

CLAMP

time

GATE

V_GATEVEEH,min

TOUT

time

INP

t_DESATBT

Figure 6

DESAT clamping and blanking timing diagram

7.1.2

Electrical characteristics DESAT protection

Table 10

Electrical characteristics DESAT protection

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

DESAT

reference

level

V_DESAT0

8.6

9

9.3

V

VCC2 = typ., VEE2 = typ.

PRQ-734

DESAT

current

source

I_DESATCS

-550 -500 -450 µA

V_VCC2= typ., V_VEE2= typ., V_DESAT≤ 10 V

PRQ-800

PRQ-693

DESAT low

voltage

V_DESATL

0

200 300 mV

Referenced to GND2, DESAT clamping

enabled, I_sink= 5 mA

(table continues...)

Datasheet

21

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

Table 10

(continued) Electrical characteristics DESAT protection

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

DESAT

detection &

reaction time

t_DESAT2OFF100 300 400 ns

V_{DESAT_Overdrive}= 2 V, Slew rate @ DESAT =

10 V/µs; TOUT = V_VCC2- 1.5 V, afer DESAT

blanking time elapsed, C_{LOAD_TOUT}= no

load, no resistive load

PRQ-841

PRQ-969

PRQ-690

DESAT

blanking

time

t_DESATBT

120 320 400 ns

From V_GATEVEEHto release of clamping

(Desat pin voltage rising above 0.5 V,

with internal current source, no external

C_DESAT), no C_Load/R_Loadon TOUT

DESAT input V_DESAT

voltage range

0

–

V_VCC2

V

Referenced to GND2

7.2

Over Current Protection (OCP)

7.2.1

Functional description OCP protection

The device monitors the voltage diﬀerence between OCPP and OCPN when TOUT = high (VCC2) afer the OCP

blanking time is elapsed. If the corresponding reference level (V_OCPDx) is reached, it issues a safe turn-oﬀ within

t_OCP2OFF, then changes into Error_Mode and signals a NFLT low in t_{NFLT_OCP}

.

2.5 V typ.

IGBT/SiC

Logic

OCPP pin

open

RDY trigger

OCPP

Comp1

NFLT trigger

Rsense

Fixed

threshold

OCPN

GND2

RDY trigger

OCPN pin

open

Figure 7

OCP diagram of principal functionality

Datasheet

22

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

OCP blanking

time

GATE

V_GATEVEEH,min

TOUT

time

INP

t_OCPBT

Figure 8

7.2.2

OCP blanking time

Electrical characteristics OCP protection

Electrical characteristics OCP

Table 11

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Overcurrent V_OCPD1

error

270 300 330 mV

V_OCPP- V_OCPN

PRQ-695

detection

threshold

OCPP &

OCPN pull-up

resistance

R_PUOCP2

26

-1

38

–

50

1

kΩ

PRQ-697

PRQ-793

OCPP &

OCPN

voltage

V_OCP

V

referring to GND2

(table continues...)

Datasheet

23

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

Table 11

(continued) Electrical characteristics OCP

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

OCP

detection &

reaction time

t_OCP2OFF

100 300 400 ns

V_{OCP_Overdrive}= 200 mV, slew rate = 100 mV/ PRQ-842

ns, TOUT = V_VCC2- 1.5 V, afer OCP blanking

time elapsed, C_{LOAD_TOUT}= no load, no

resistive load

OCP blanking t_OCPBT

time

120 320 400 ns

From V_GATEVEEHto release of blanking.

V_{OCP_Overdrive}= 200 mV, slew rate = 100

mV/ns, no C_Load/R_Loadon TOUT

PRQ-1014

OCP pin open V_OCPOPEN2.2

2.45 2.6

V

PRQ-1030

detection

voltage

7.3

Safe turn-oﬀ

Functional description safe turn-oﬀ

7.3.1

The device enables a two-level turn-oﬀ in case of a fault.

Datasheet

24

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

V_DESAT

V_DESATx,max

time

V_TOUT

V_VCC2

V_VCC2– 1.5 V

V_SOffPLT,typ

V_SOffPLT,typ– 1.5 V

V_VEE2+ 1.5 V

t_DESAT2OFF

t_SafeOffPLT

t_PLT2off

V_VEE2

time

Figure 9

Two level turn-oﬀ principle for safe turn-oﬀ

Note:

•

Safe turn-oﬀ is only enabled at DESAT, OCP and gate monitoring error (if TOUT = high (VCC2)

events.

DESAT is only used as an example, can be replaced by OCP and gate monitoring.

7.3.2

Electrical characteristics safe turn-oﬀ

Table 12

Parameter

Electrical characteristics safe turn-oﬀ

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Safe turn-oﬀ t_{SaꢀeOﬀPLT}

1

–

1.5

μs

PRQ-918

PRQ-973

plateau time

Plateau to

t_PLT2Oﬀ

10

–

50

ns

No R_Load, no C_Load

turn-oﬀ time

(table continues...)

Datasheet

25

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

Table 12

(continued) Electrical characteristics safe turn-oﬀ

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Safe turn-oﬀ V_SOﬀPLT

plateau

voltage level

8.46

9

9.54

V

V_VCC2≥ V_SOﬀPLT,max+ 2 V, C_{LOAD_TOUT}= 68 nF, PRQ-919

R_{LOAD_TOUT}= 1.7 Ω

7.4

Shoot Through Protection (STP)

7.4.1

Functional description STP

The device has a Shoot Through Protection (STP) function to prevent both high-side and low-side switches to

be activated simultaneously.

Note:

STP is always active. However, setting the INN pin to GND1 deactivates the function.

If one of the drivers is in ON state, the driver’s counterpart PWM input is inhibited, preventing it to turn on.

HS

Driver HS

INP_HS

OUT_HS

PWM_HS

PWM_LS

L

o

g

i

INN_HS

c

LOGIC

Driver LS

INP_LS

INN_LS

OUT_LS

L

o

g

i

LS

c

Figure 10

Shoot through protection application diagram

The device follows the shoot through protection timing diagram shown below:

Datasheet

26

Rev. 1.1

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EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

Keep State

INP_HS

INP_LS

INN_HS

TOUT_HS

t_PDOFF

t_DEAD

t_PDON

TOUT_LS

t_PDON

t_DEAD

t_PDON

t_PDOFF

Figure 11

7.4.2

Shoot through protection timing diagram

Electrical characteristics STP

Table 13

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Dead time for t_DEAD3

shoot

650 800 950 ns

PRQ-729

through

protection

7.5

Power supply monitoring

Functional description power supply monitoring

7.5.1

The device is equipped with an undervoltage lockout for the primary supply (VCC1) and secondary

supply (VCC2) in order to ensure correct switching of the power switch.

Note:

In all under voltage conditions the ASC signal still works until the voltage drops below VASCOFF at

VCC2.

The device turns oﬀ the power switch and ignores signals at INP and INN (goes into Power_Down Mode) if the

power supply VCC1 drops below V_UVLO1L. It returns to Ready_Mode if the voltage at VCC1 is above V_UVLO1Hand

the device received a rising edge at NRST.

The device turns oﬀ the power switch within t_UVLO22OFFand ignores signals at INP and INN (go into Error_Mode)

within t_PS2RDYif the power supply VCC2 drops below V_{UVLO2L_x}. It returns to Ready_Mode if the voltage at VCC2 is

above V_{UVLO2H_x}and the device received a rising edge at NRST.

The device is equipped with an overvoltage lockout for the secondary supply VCC2 in order to prevent damage

of the power switch.

Datasheet

27

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EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

Note:

The ASC signal will overwrite the turn-oﬀ command, which may lead to damage of the power switch

(power switch).

The device turns oﬀ the power switch within t_OVLO22OFFand ignores signals at INP and INN (go into Error_Mode)

within t_PS2RDYif the power supply V_VCC2rises above V_{OVLO2H_x}. It returns to Ready_Mode if the voltage V_VCC2is

below V_{OVLO2L_x}and the device received a rising edge at NRST.

Note:

•

In Error_Mode, RDY changes to 0.

Turn-oﬀ means normal switch-oﬀ and not a safe turn-oﬀ.

Exception: ASC function → TOUT = high (VCC2).

7.5.2

Electrical characteristics power supply monitoring

Table 14

Electrical characteristics power supply monitoring

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

UVLO1

threshold

low

V_UVLO1L

2.6

2.75

–

V

@ VCC1, referenced to GND1

PRQ-741

PRQ-740

UVLO1

threshold

high

V_UVLO1H

–

2.85 2.95

V

@ VCC1, referenced to GND1

UVLO1

V_UVLO1HYS

–

80

100 mV

PRQ-742

PRQ-889

hysteresis

OVLO2

threshold

high

V_{OVLO2H_3}17.8 18.5 19.0

V_{OVLO2L_3}17.1 17.7 18.2

V

@ VCC2, referenced to GND2

OVLO2

threshold

low

PRQ-890

OVLO2

V_OVLO2HYS400 800

–

mV

V

V_{OVLO2H_x}- V_{OVLO2L_x}

PRQ-896

PRQ-750

hysteresis

UVLO2

threshold

high

V_{UVLO2H_1}12.2 12.6 13

V_{UVLO2L_1}11.4 11.8 12.2

@ VCC2, referenced to GND2

UVLO2

threshold

low

V

@ VCC2, referenced to GND2

PRQ-752

UVLO2

V_UVLO2HYS720 800 880 mV

t_UVLO12OFF500 800 ns

PRQ-755

PRQ-914

hysteresis

UVLO1

–

Slewrate = 2 V/µs, Overdrive = +/- 300 mV

detection &

reaction time

(table continues...)

Datasheet

28

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

Table 14

(continued) Electrical characteristics power supply monitoring

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

UVLO2

detection &

reaction time

t_UVLO22OFF

–

500 800 ns

Slewrate=10 V/µs; Overdrive=+/-200 mV

PRQ-915

PRQ-916

PRQ-976

OVLO2

detection &

reaction time

t_OVLO22OFF

Slewrate=10 V/µs; Overdrive=+/-200 mV

VCC2 = typ., VEE2 = typ.

Power supply t_PS2RDY

monitoring

detection

and

–

2.5

µs

notification

time

7.6

Gate monitoring

Functional description gate monitoring

7.6.1

The device monitors in the time frame of t_GMBT(dynamic or static) the gate signal V_GATEat pin CLAMP/GATE

to ensure the signal V_TOUTreaches the threshold value of V_GATEproperly. If monitoring conditions are violated,

the device issues a safe turn-oﬀ (if TOUT = high (VCC2) in less than t_GM-DaRand changes to Error_Mode in less

than t_{RDY_GM}

.

V_GATE

t_GMBTd

VGATEVCCH, max

VGATEVEEL, min

time

t_GM-DaR

V_TOUT

V_VCC2– 1.5 V

V_VEE2+ 1.5 V

time

Figure 12

Dynamic gate monitoring timing diagram

Datasheet

29

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

V_GATE

t_GMBTs

VGATEVCCH,max

VGATEVEEL,min

time

V_TOUT

t_GM-DaR

V_VCC2– 1.5 V

V_VEE2+ 1.5 V

time

Figure 13

7.6.2

Static gate monitoring timing diagram

Electrical characteristics gate monitoring

Table 15

Electrical characteristics gate monitoring

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Gate

t_GM-DaR

450 650 900 ns

VCC2 = typ., VEE2 = typ.

PRQ-853

monitoring

detection

and reaction

time

Gate

t_{RDY_GM}

–

1.5

2.5

µs

VCC2 = typ., VEE2 = typ.

PRQ-910

monitoring

detection

and

notification

time

Dynamic gate t_GMBTd3

monitoring

blanking

6.99 7.6

7.40 7.9

8.21 µs

8.40 µs

VEE2 = typ., VCC2 = typ.

PRQ-979

PRQ-983

time

Static gate

monitoring

blanking

time

t_GMBTs3

(table continues...)

Datasheet

30

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

Table 15

(continued) Electrical characteristics gate monitoring

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Gate

V_GATEVCCHV_VCC2V_VCC2V_VCC2

V

t_GMBTis active

PRQ-855

PRQ-962

PRQ-963

PRQ-856

monitoring

VCC2 voltage

threshold

high level

- 2.3 - 2.1 - 1.9

Gate

V_GATEVCCLV_VCC2V_VCC2V_VCC2

V

t_GMBTis active

monitoring

VCC2 voltage

threshold

low level

- 3.2 - 3

- 2.8

Gate

V_GATEVEEHV_VEE2V_VEE2V_VEE2

+ 2.8 + 3 + 3.2

monitoring

VEE2 voltage

threshold

high level

Gate

V_GATEVEELV_VEE2V_VEE2V_VEE2

monitoring

VEE2 voltage

threshold

low level

+ 1.9 + 2.1 + 2.3

7.7

Output stage monitoring

7.7.1

Functional description output stage monitoring

The output stage monitoring checks whether the internal output signal is according to the given PWM or ASC

input signal in the time frame of t_{OUTMBTx ,}otherwise the device issues a tri-state for the output stage in less

than t_OUTM-DaRand changes to Error_Mode in less than t_{RDY_OSM}

.

Datasheet

31

Rev. 1.1

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EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

V_TOUT,real

VOSMVCCH, max

VOSMVEEL, min

Short to VEE2

time

V_TOUT

t_OUTMBTd

t_OUTM-DaR

t_OUTMBTd

VOSMVCCH, max

Tri state

VOSMVEEL, min

I_VCC2/I_VEE2

90%

time

10%

time

Figure 14

Dynamic output stage monitoring working principle

Datasheet

32

Rev. 1.1

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EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

V_TOUT,real

t_OUTMBTs

VOSMVCCH,max

VOSMVEEL,min

V_TOUT

time

t_OUTM-DaR

VOSMVCCH,max

Tri state

VOSMVEEL,min

time

I_VCC2

90%

10%

time

Figure 15

Static output stage monitoring working principle

Note:

The passive clamping at TOUT is working.

7.7.2

Electrical characteristics output stage monitoring

Table 16

Electrical characteristics output stage monitoring

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Output stage t_OUTM-DaR200 350 500 ns

VCC2 = typ., VEE2 = typ.

PRQ-859

monitoring

detection

and reaction

time

Output stage t_{RDY_OSM}

monitoring

detection

–

1.5

2.5

µs

VCC2 = typ., VEE2 = typ.

PRQ-964

and

(table continues...)

Datasheet

33

Rev. 1.1

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EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

7 Protection and monitoring functions

Table 16

(continued) Electrical characteristics output stage monitoring

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

VEE2 = typ., VCC2 = typ.

t_OUTBTis active

P-

Number

Min. Typ. Max.

notification

time

Dynamic

output stage

monitoring

blanking

time

t_OUTMBTd3600 800 1000 ns

PRQ-922

PRQ-925

PRQ-863

PRQ-965

PRQ-966

PRQ-864

Static output t_OUTMBTs31000

stage

monitoring

blanking

time

–

1200 ns

Output stage V_OSMVCCHV_VCC2V_VCC2V_VCC2

V

monitoring

VCC2 voltage

threshold

- 2.3 - 2.1 - 1.9

high level

Output stage V_OSMVCCL

monitoring

VCC2 voltage

threshold

low level

V_VCC2V_VCC2V_VCC2

- 3.2 - 3

t_OUTBTis active

- 2.8

Output stage V_OSMVEEHV_VEE2V_VEE2V_VEE2

t_OUTBTis active

monitoring

VEE2 voltage

threshold

+ 2.8 + 3

+ 3.2

high level

Output stage V_OSMVEEL

monitoring

V_VEE2V_VEE2V_VEE2

+ 1.9 + 2.1 + 2.3

t_OUTBTis active

VEE2 voltage

threshold

low level

Datasheet

34

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

8 Clamping functions

8

Clamping functions

8.1

Active Miller clamp

8.1.1

Functional description Active Miller clamp

The clamp output is activated if the gate voltage V_GATEgoes below V_GATEVEELduring turn-oﬀ.

V_GATE

VGATEVEEL, min

time

Active Miller

Clamping

active

Clamp

active

time

INP

time

Figure 16

Active Miller clamp timing diagram

Note:

In a half bridge configuration the switched oﬀ power switch tends to dynamically turn on during the

turn on phase of the opposite power switch. A Miller clamp allows sinking the Miller current across a

low impedance path in this high dV/dt situation. Therefore, in many applications the use of a negative

supply voltage can be avoided.

8.1.2

Electrical characteristics Active Miller clamp

Table 17

Electrical characteristics Active Miller clamp

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Low level

clamp peak

current

I_CLAMPL

9.5

10

A

TOUT = low (V_VEE2), CLAMP/GATE = V_CLAMP,PRQ-667

V_VCC2= 15 V, V_VEE2= -5 V

CLAMP/GATE V_CLAMP/

V_VEE2

–

V_VCC2

V

Referenced to GND2, no load

PRQ-586

voltage

GATE

(table continues...)

Datasheet

35

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

8 Clamping functions

Table 17

(continued) Electrical characteristics Active Miller clamp

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

CLAMP

RDSON

R_DSON-

CLAMP

0.08

–

0.35

Ω

Voltage drop V_VCC2- V_TOUT< 1 V

PRQ-852

8.2

Passive clamping

8.2.1

Functional description passive clamping

If the secondary chip is not supplied, the pin GATE/CLAMP is passively clamped to VEE2.

8.2.2

Electrical characteristics passive clamping

Table 18

Electrical characteristics passive clamping

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

GATE passive V_PCLPG1

clamping

voltage

–

V_VEE2

+ 2 V

V

Secondary chip not supplied (VCC2

floating, VEE2 = 0 V), I_Clamp= 10 mA

PRQ-738

(ICLAMP = 10

mA)

GATE passive V_PCLPG2

clamping

–

V_VEE2

+ 2.2

V

Secondary chip not supplied (VCC2

floating, VEE2 = 0 V), I_Clamp= 100 mA

PRQ-882

voltage

(ICLAMP =

100 mA)

Datasheet

36

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

9 Analog-to-Digital Converter (ADC)

9

Analog-to-Digital Converter (ADC)

9.1

Functional description ADC

The device has an ADC to measure the DC-link voltage.

The integrated ADC allows the measurement of the DC-link voltage. The internal current source I_ADC,refis

deactivated. The voltage signal V_AIPis encoded to a PWM signal that is passed through the isolation to DATA pin

on the primary side. The Total Unadjusted Error is the square sum of errors (INL, ER_OFFand ER_GAIN).

DC-link voltage

Device

0 uA

AIP

ADC

DATA

Galvanic

GND2

isolation

Figure 17

DC-link measurement diagram

The integrated ADC allows isolated temperature sensing. The internal current source I_ADC,refis disabled . The

voltage signal V_AIPis encoded to a PWM signal that is passed through the isolation to DATA pin on the primary

side. The Total Unadjusted Error is the square sum of errors (INL, ER_OFFand ER_GAIN).

Datasheet

37

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

9 Analog-to-Digital Converter (ADC)

VCC2

Device

0 uA

AIP

NTC

ADC

DATA

Galvanic

isolation

GND2

Figure 18

ADC application diagram with NTC.

Note:

V_{IADC,eﬀective}= (V_IADC* ER_GAIN/ 100)

9.2

Electrical characteristics ADC

Table 19

Electrical characteristics ADC

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

ADC

–

12

bit

PRQ-609

PRQ-794

resolution

Ideal ADC

input voltage

full scale

V_IADC

–

4.82

–

ADC Gain

Error

ER_GAIN

ER_OFF

- 1.5

–

+ 1.5 %FS

Refers to V_IADC, valid for Input range V_AIP

V_GND2= 0.4 V...4.4 V

-

PRQ-897

PRQ-898

ADC Oﬀset

Error

-0.25 –

+0.2 %FS

5

Refers to V_IADC, valid for Input range V_AIP

V_GND2= 0.4 V...4.4 V

(table continues...)

Datasheet

38

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

9 Analog-to-Digital Converter (ADC)

Table 19

(continued) Electrical characteristics ADC

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

ADC INL

INL

–

0.02 0.07 %FS

Refers to V_IADC, valid for Input range V_AIP

V_GND2= 0.4 V...4.4 V

-

PRQ-899

PRQ-900

PRQ-903

PRQ-1034

4

3

ADC DNL

DNL

–

0.00 0.02 %FS

Refers to V_IADC, valid for Input range V_AIP

V_GND2= 0.4 V...4.4 V

7

5

ADC sample f_SAMPLE

rate

2.28 2.4

- 3

2.52 kHz

12 bit

ADC leakage I_leakADC

current

3

µA

V_AIP= 4 V

Datasheet

39

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

10 Interface

10

Interface

10.1

Reset (NRST)

10.1.1

Functional description NRST

The NRST pin is the reset input of the device.

All errors cleared with a rising edge on NRST.

10.1.2

Electrical characteristics NRST

Table 20

Electrical characteristics NRST

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Minimum

reset

t_NRST

10

–

µs

PRQ-764

duration

time

10.2

Ready (RDY)

Functional description RDY

10.2.1

The RDY pin reports whether the device is ready.

Note:

Ready means: no OSM error, no gate monitoring error, no OVLO2, no UVLO2, no open pin at OCPx, no

prim. or sec. internal supervision error, OTP read ok.

The RDY pin has a passive clamping.

Note:

Passive clamping keeps RDY = 0 in case of no supply.

10.2.2

Electrical characteristics RDY

Table 21

Electrical characteristics RDY

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

RDY open

drain output

low level

V_RDY(low)

–

0.5

V

V_VCC1≥ 3.0 V, I_load= 5 mA

PRQ-840

(table continues...)

Datasheet

40

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

10 Interface

Table 21

(continued) Electrical characteristics RDY

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

RDY output

low passive

clamping

V_RDYCLAMP

–

0.5

1

V

I_RDYCLAMP= 500 µA, V_CC1= floating, all I/O = PRQ-834

floating

Power up

t_PUprim

t_PUsec

–

100 1500 µs

Time from UVLO1 release to device

operable, secondary chip running

PRQ-959

PRQ-960

PRQ-961

timing prim.

Power up

timing sec.

Time from UVLO2 release to device

operable, primary chip running

Time from

rising Edge

NRST to RDY

= high

t_NRST2RDY50

–

200 ns

No error detected

10.3

Fault (NFLT)

Functional description NFLT

10.3.1

The device has an active low fault pin (NFLT) to report DESAT and OCP short circuit events.

If the device switches oﬀ the output stage due to a DESAT or OCP event, it goes to Error_Mode and signals the

event on pin NFLT with NFLT = 0 within t_{NFLT_DESAT}or t_{NFLT_OCP}

.

Note: Switch oﬀ means safe turn-oﬀ.

The device keeps the fault signal available unless a reset event takes place.

10.3.2

Electrical characteristics NFLT

Table 22

Electrical characteristics NFLT

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

OCP event

detection to

NFLT

t_{NFLT_OCP}

–

1.2

2.3

µs

V_{OCP_Overdrive}= +/-200 mV, slew rate = 100

mV/ns, NFLT = 90 %, R_{PU_NFLT}= 1 kΩ

V_{DESAT_Overdrive}= +/-200 mV, slew rate = 10

V/µs, NFLT = 90 %, R_{PU_NFLT}= 1 kΩ

PRQ-614

activation

DESAT event t_{NFLT_DESAT}

detection to

NFLT

–

1.5

2.5

µs

PRQ-844

activation

(table continues...)

Datasheet

41

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

10 Interface

Table 22

(continued) Electrical characteristics NFLT

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

NFLT open

drain output

low level

V_NFLT

–

0.5

V

V_VCC1≥ 3.0 V; |I_NFLT| = 5 mA

PRQ-791

10.4

I/O levels

Table 23

I/O levels

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless otherwise

specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Primary

digital input

low level

V_digital,inpu

t(low)

0

–

0.8

V

PRQ-704

PRQ-705

Primary

V_digital,inpu

2

–

V_VCC1

V

digital input

high level

t(high)

INP high/low t_INPPD

750

40

–

ns

V_VCC1=typ., V_VCC2=typ., V_VEE2=typ., 50% to

PRQ-970

PRQ-971

PRQ-929

duration

50%

INN high/low t_INNPD

duration

–

V_VCC1=typ., V_VCC2=typ., V_VEE2=typ., 50% to

50%

Weak pull

down

R_PDIN1

48

60.5 kΩ

resistance

NRST, EN,

INP

Weak pull up R_PDINN

resistance

INN

40

52

PRQ-930

10.5

DATA read-out

Functional description DATA

10.5.1

In case the device switches to Error_Mode and EN pin is low, diagnostic data are available, starting with the

next frame. In Ready_Mode diagnostic data are available. In Normal_Mode and in Error_Mode, when EN pin is

high, ADC result data are available.

Datasheet

42

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

10 Interface

V

Error detected:

RDY = 0 or NFTL = 0

Error cleared by

NRST rising edge

OPM

Normal_Mode

Error_Mode

Ready_Mode

Normal_Mode

t_{Period_ADC}

ADC pattern

t_{Period_diag}

DIAG pattern

DATA

EN

ADC pattern

time

V

Error detected:

RDY = 0 or NFTL = 0

Error cleared by

NRST rising edge

OPM

Ready_Mode

Error_Mode

Ready_Mode to Normal_Mode

t_{Period_diag}

t_{Period_ADC}

DATA

EN

ADC pattern

DIAG pattern

time

Note: Next frame means first rising edge of following pulse

Figure 19

DATA pin ADC and diagnostic transition timing diagram

The 12 bit ADC data is pulse width modulated to a signal with a period of t_{Period_ADC}

.

The duty cycle for 12 bit ADC data always remains in the range of D_ADCregardless of the ADC input.

The following diagnostic functions are reported in Ready_Mode and in Error_Mode, if EN = 0:

•

UVLO2

OVLO2

Gate monitoring

Output stage monitoring

OCP

DESAT

Sec. internal supervision error (Parity, OTP, PMU_Supervision error)

The 8 bit diagnostic functions is pulse width modulated to a signal with a period of t_{Period_Diag}

.

The duty cycle of the DATA pin always remains in the range of D_Diagregardless of the diagnostic status.

Note:

0% and 100% duties are not allowed at DATA pin.

Table 24

BIT_x

Diagnostic read-out at DATA pin

Value

Description

Value

Description

Example: Single

failure DESAT

BIT 0

0

PRIM NOT READY

1

PRIM READY

1

(table continues...)

Datasheet

43

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

10 Interface

Table 24

BIT_x

(continued) Diagnostic read-out at DATA pin

Value

Description

Value

Description

Example: Single

failure DESAT

BIT 1

BIT 2

BIT 3

BIT 4

BIT 5

BIT 6

BIT 7

BIT 8

BIT 9

BIT 10

BIT 11

0

1

Reserved (always 0)

0

No OSM Error

1

OSM Error

0

No GATEMON Error

No DESAT Error

No OCP Error

GATEMON Error

DESAT Error

OCP Error

0

1

0

No UVLO2 Error

No OVLO2 Error

SEC READY

UVLO2 Error

OVLO2 Error

SEC NOT READY

0

Result from example diagnostic read-out:

Duty cycle = 3.49 %

The duty cycle for diagnostic read-out can be calculated using the following formula:

Figure 20

Formula to calculate the duty cycle for diagnostic read-out

10.5.2

Electrical characteristics DATA

Table 25

Electrical characteristics DATA

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

ADC DATA

duty cycle

range

D_ADC

0.36

–

99.6

%

No life sign lost, no primary reset

PRQ-782

PRQ-783

Diagnostic

duty cycle

range

D_Diag

0.36

–

99.6

%

(table continues...)

Datasheet

44

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

10 Interface

Table 25

(continued) Electrical characteristics DATA

T_J= -40°C to 150°C; all voltages with respect to ground, pos. current flowing into pin (unless

otherwise specified).

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

ADC DATA

period

t_{Period_ADC}95

100 105 µs

PRQ-784

PRQ-785

PRQ-706

PRQ-707

Diagnostic

period

t_{Period_Diag}95

100 105 µs

DATA output V_DATA,outpu

low level

–

0

0.5

–

V

V_VCC1≥ 3.0 V, |I_load| = 5 mA

t(low)

DATA output V_DATA,outpuV_CC1V_VCC1

high level

- 0.5

t(high)

Datasheet

45

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

11 Application information

11

Application information

The external component values are specified as typical values in a typical application. Deviation of the nominal

values are specified as min or max values, if applicable. Unless otherwise specified the deviation for external

components are:

•

Resistor: 10%

Capacitor: -50% ... +30%

Note:

The following information is given as a hint for the implementation of the device only and shall not be

regarded as a description or warranty of a certain functionality, condition or quality of the device.

11.1

Electrical characteristics external components

Table 26

Parameter

Electrical characteristics external components

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

Decoupling

capacitance

(between

VCC1 and

GND1)

C_dVCC1

0.55 1.1

–

µF

Total capacitance refers to 1 µF

PRQ-1002

PRQ-1001

PRQ-1000

capacitance + 0.1 µF close to the device.

Max value depends on t_RP1

.

Decoupling

capacitance

(between

VCC2 and

GND2)

C_dVCC2

–

11

µF

Total capacitance refers to 10 µF

capacitance + 1 µF close to the device.

Values depend on external C_LOAD. Max

value depends on t_RP2

.

Decoupling

capacitance

(between

VEE2 and

GND2)

C_dVEE2

Total capacitance refers to 10 µF

capacitance + 1 µF close to the device. Max

value depends on t_RP3

.

Pull-up

R_pu

–

10

–

kΩ

pF

kΩ

pF

Ω

Min value depends on I_{OUTx_MAX}

Value must fit to application

.

PRQ-1015

PRQ-1016

PRQ-1017

PRQ-1018

PRQ-1019

PRQ-1021

resistance

Filter

resistance

R_Filter

C_Filter

R_Desat

–

1

Filter

capacitance

–

47

DESAT

resistance

1

2.2

100

0.47

Depends on maximum current and

on V_DESATxdeviation.

DESAT filter C_Desat

capacitance

50

–

Depends on required response time.

OCP sense

resistor

R_OCPSense

Value depends on power switch

specification, voltage rating of OCP pin has

to be considered.

OCPP filter

resistance

R_OCPP

–

10

–

Ω

Depends on required response time.

Consider internal pull-up.

PRQ-1022

(table continues...)

Datasheet

46

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

11 Application information

Table 26

(continued) Electrical characteristics external components

Parameter

Symbol

Values

Unit

Note or condition

P-

Number

Min. Typ. Max.

OCPP filter

C_OCP

–

10

–

pF

Ω

Depends on required response time

PRQ-1023

PRQ-1024

PRQ-1025

capacitance

OCPN

resistance

R_OCPN

R_Load

–

Should match to OCPP filter resistor.

Consider internal pull-up.

TOUT

resistance

1.7

Ω

Min resistor value required according

to max output current in functional range.

Max value limited by gate monitoring

feature.

GATE/CLAMP R_GATE

series

resistance

–

0

–

Ω

Optional component. Voltage across

resistor impacts Active Miller clamping

feature.

PRQ-1028

11.2

Typical application example

VCC2

µC

Driver IC

VCC2

GND2

VEE2

VCC1

C^dVCC2

VCC1

C^dVCC1

C^dVEE2

GND2

GND1

R^Filter

VEE2

INP

R^Desat

C^Filter

R^Filter

DESAT

C^Desat

GND2

GND1

D^Desat

INN

C^Filter

GND1

DC-link

R^VD-DClink1

TOUT

AIP

DATA

VCC1

R^Load

R^pu

RDY

VCC1

R^VD-DClink2

GND2

R^GATE

R^pu

GATE/CLAMP

NFLT

R^OCPP

R^Filter

NRST

EN

OCPP

OCPN

C^Filter

C^OCP

R^OCPN

R^OCPSense

R^Filter

GND1

C^Filter

GND2

GND1

Figure 21

Typical application example with ADC

Note:

This is a very simplified example. The function must be verified in the real application.

Datasheet

47

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

12 Package information

12

Package information

1)

7.5

1)

6.4

0.35 x 45°

0.7±0.2

Seating plane

Coplanarity

Bottom view

11

20

11

Pin1 marking

1

10

1

2)

0.5

0.25±0.06

1) Does not include plastic or metal protrusion of 0.15 max. per side

2) Dambar protrusion shall be maximum 0.1 mm total in excess of lead width

All dimensions are in units mm

The drawing is in compliance with ISO 128-30, Projection Method 1 [

]

Figure 22

PG-DSO-20

Green Product (RoHS compliant)

To meet the world-wide customer requirements for environmentally friendly products and to be compliant

with government regulations the device is available as a Green Product. Green Products are RoHS compliant

(Pb-free finish on leads and suitable for Pb-free soldering according to IPC/JEDEC J-STD-020).

Information on alternative packages

Please visit www.infineon.com/packages.

Datasheet

48

Rev. 1.1

2022-02-17

EiceDRIVER^™gate driver 1EDI3023AS

Single channel isolated IGBT driver

Revision history

Revision Date

Changes

1.1

2022-02-17

Chapter 3.2 updated

•

Table 3 updated

-

VCC1, VEE2, VCC2 ramp-up slew-rates reduced

ramp-down condition removed

Chapter 3.4 updated

Table 5 updated

•

-

extended by further electrical information

additional reinforced insulation options

1.01

1.0

2021-06-25

2021-03-18

Typo in insulation certification standard corrected

Initial datasheet created

Datasheet

49

Rev. 1.1

2022-02-17

Trademarks

All referenced product or service names and trademarks are the property of their respective owners.

Edition 2022-02-17

Published by

Infineon Technologies AG

81726 Munich, Germany

IMPORTANT NOTICE

WARNINGS

The information given in this document shall in no

event be regarded as a guarantee of conditions or

characteristics (“Beschaﬀenheitsgarantie”).

With respect to any examples, hints or any typical

values stated herein and/or any information regarding

the application of the product, Infineon Technologies

hereby disclaims any and all warranties and liabilities

of any kind, including without limitation warranties of

non-infringement of intellectual property rights of any

third party.

In addition, any information given in this document is

subject to customer’s compliance with its obligations

stated in this document and any applicable legal

requirements, norms and standards concerning

customer’s products and any use of the product of

Infineon Technologies in customer’s applications.

Due to technical requirements products may contain

dangerous substances. For information on the types

in question please contact your nearest Infineon

Technologies oﬀice.

Except as otherwise explicitly approved by Infineon

Technologies in

authorized representatives of Infineon Technologies,

Infineon Technologies’ products may not be used in

any applications where a failure of the product or

any consequences of the use thereof can reasonably

be expected to result in personal injury.

a written document signed by

©

2022 Infineon Technologies AG

Do you have a question about any

aspect of this document?

Email: erratum@infineon.com

Document reference

IFX-Z8F80035733

The data contained in this document is exclusively

intended for technically trained staﬀ. It is the

responsibility of customer’s technical departments to

evaluate the suitability of the product for the intended

application and the completeness of the product

information given in this document with respect to such

application.


型号：	1EDI3023AS
厂家：	Infineon
描述：	EiceDRIVER™ 1EDI3023AS 采用英飞凌强大的无磁芯变压器技术提供跨越隔离屏障的双向信号传输。变压器驱动
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