IR5001_技术文档

Data Sheet No.PD60229

IR5001

UNIVERSAL ACTIVE ORING CONTROLLER

FEATURES

DESCRIPTION

The IR5001 is a universal high-speed controller and

N-channel power MOSFET driver for Active ORing and

reverse polarity protection applications. The output voltage

of the IR5001 is determined based on the polarity of the

voltage difference on its input terminals. In particular, if the

current flow through an N-channel ORing FET is from

source to drain, the output of the IR5001 will be pulled

high to Vcc, thus turning the Active ORing FET on. If the

current reverses direction and flows from drain to source

(due to a short-circuit failure of the source, for example),

the IC will quickly switch the Active ORing FET off. Typical

turn-off delay for the IR5001 is only 130nS, which helps to

minimize voltage sags on the redundant dc voltage.

Both inputs to the IC (INN and INP) as well as Vline

input contain integrated high voltage resistors and internal

clamps. This makes the IR5001 suitable for applications at

voltages up to 100V, and with a minimum number of

external components.

Controller / driver IC in an SO-8 package for

implementation of Active ORing / reverse polarity

protection using N-channel Power MOSFETs

Suitable for both input ORing (for carrier class

telecom equipment) as well as output ORing for

redundant DC-DC and AC-DC power supplies

130ns Typical Turn-Off delay time

3A Peak Turn-Off gate drive current

Asymmetrical offset voltage of the internal high-speed

comparator prevents potential oscillations at light load

Ability to withstand continuous gate short conditions

Integrated voltage clamps on both comparator inputs

allow continuous application of up to 100V

Option to be powered either directly from 36-75V

universal telecom bus (100V max), or from an

external bias supply and bias resistor

Input/Output pins to determine the state of the Active

ORing circuit and power system redundancy

APPLICATIONS

-48V/-24V Input Active ORing for carrier class communication equipment

Reverse input polarity protection for DC-DC power supplies

24V/48V output active ORing for redundant AC-DC rectifiers

Low output voltage (12V, 5V, 3.3V...) active ORing for redundant DC-DC and AC-DC power supplies

Active ORing of multiple voltage regulators for redundant processor power

PACKAGE / ORDERING

TYPICAL APPLICATION

INFORMATION

A

+48V input

B

IR5001

Vline

Vcc

Vout

Gnd

DC

FETch INN

FETst INP

FET Check Pulse

FET A Status

Top View

Vline

Vcc

FETch

FETst

1

2

3

4

8

7

6

5

Vout

Gnd

INN

INP

-48V input A

IR5001

Vline Vout

Vcc

Gnd

INN

FETch

θJA=128°C/W

Fet B Status

FETst INP

Ordering P/N

IR5001S

Package

8 - Pin SOIC

-48V input B

Figure 1 - Typical application of the IR5001 in - 48V input,

carrier class telecommunications equipment.

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IR5001

ABSOLUTE MAXIMUM RATINGS

Vline Voltage

-5.0V to 100V (continuous)

-0.5V to 15VDC

5mA

Vcc Voltage

Icc Current

INN, INP Voltage

FETch, FETst

-5.0V to 100V (continuous)

-0.5V to 5.5V

FETst Sink Current

Junction Temperature

Storage Temperature Range

10mA

-40°C to 125°C

-65°C to 150°C

CAUTION:

1. Stresses above those listed in "Absolute Maximum Ratings" may cause permanent damage to the device. This

is a stress only rating and operation of the device at these or any other conditions above those indicated in the

operational section of this specification is not implied.

2. This device is ESD sensitive. Use of standard ESD handling precautions is required.

.

ELECTRICAL SPECIFICATIONS

Unless otherwise specified, these specifications apply over Vline = 36V to 100V; Vcc is decoupled with 0.1uF to

Gnd, CL=10nF at Vout; INP is connected to Gnd. Typical values refer to TA=25°C. Minimum and maximum limits

apply to TA= 0°C to 85°C temperature range and are 100% production-tested at both temperature extremes. Low

duty cycle pulse testing is used which keeps junction and case temperatures equal to the ambient temperature.

PARAMETERS

Bias Section

SYMBOL

TEST CONDITION

MIN TYP MAX UNITS

Vline=25V

0.14 0.3 0.5

Iline

Vline=36V

0.2 0.5 0.75 mA

1.2 1.7 2.2

Vline Bias Current

Vline=100V, Note 1

VCC output voltage

Vcc(out)

Vcc(ON)

Vline=25V

Vline=open, VINP=0; VINN= -

0.3V

10.2 12.5 13.9

V

UVLO Section

UVLO ON Threshold Voltage

8.3 9.6 10.9

Vcc increased until Vout switches

from LO to HI,

Note 2

V

Vline=open, VINP=0, VINN=-

0.3V, Vcc is decreased until

Vout switches from HI to LO

UVLO OFF Threshold Voltage

UVLO Hysteresis

Vcc(OFF)

5.7 7.2 8.5

1.6 2.3 2.8

V

VINP=0V and VINN Ramping up,

VOUT changes from HI to LO,

Fig.3

Input Comparator Section

Input Offset Voltage (VINP-

VINN)

Vos

-7.9 -4.0

0

mV

VINP=0,VINN ramping down,

Figures 3 and 4

Input Hysteresis Voltage

Vhyst

13

31

44

(INN) Input Bias Current

(INP) Input Bias Current

I(INN)

I(INP)

VINP=0V, VINN=36V

VINN=0V, VINP=36V

0.2 0.5 0.9

mA

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IR5001

PARAMETERS

Output Section

High Level Output Voltage

Low Level Output Voltage

Turn-On DelayTime

Rise Time

SYMBOL

TEST CONDITION

MIN TYP MAX UNITS

Vline=25V, IOH=50uA,

V(INN)=-0.3V

IOL=100mA, V(INN)=+0.3V

Vout HI

9.5 12 14

0.1 0.1

V

Vout LO

td(on)

tr

td(off)

tf

V

us

ms

5

27 45

Vout switching from LO to HI, Fig.5

0.1 0.7

5

Turn-Off Delay Time

Fall Time

110 130 170

10 26 39

Vout switching from HI to LO, Fig.5

ns

FETch and FETst

FETch Sink Current

FETch Output Delay Time

FETch Threshold

I(FETch)

FETch=5V

Note 1

-0.5 -1.1 -2

uA

FETch_pd

Vth(FETch)

0.8 1.8

0.9 1.2 1.5

us

V

5k resistor from FETst to 5V logic

bias.

V(INP) = Gnd, V(INN) ramping down

from 0 until FETst switches to Low.

FETst Threshold Voltage

Vth(FETst)

VOL

-525 -300 -200 mV

FETst Low Level Output

Voltage

Isink=1mA, V(INN)=-0.5V

0

50 100 mV

Note 1: Guaranteed by design but not tested in production.

Note 2: Low Vcc output voltage corresponds to low UVLO voltage

PIN DESCRIPTIONS

PIN#

PIN SYMBOL

PIN DESCRIPTION

IC power supply pin for 36V to 75V input communications systems.

Minimum 25V has to be applied at this pin to bias the IC.

1

Vline

Output pin of the internal shunt regulator, or input pin for biasing the IC via

external resistor. This pin is internally regulated at 12.5V typical. A

minimum 0.1uF capacitor must be connected from this pin to Gnd of IR5001.

2

3

Vcc

FET check input pin. Together with FET status output pin, the FETch pin

can be used to determine the state of the Active ORing circuit and power

system redundancy.

FETch

FET status output pin. Together with FETch input pin, the FETst pin can be

used to determine the state of the Active ORing circuit and power system

redundancy.

4

5

FETst

INP

Positive input of internal comparator. This pin should connect to the source

of N-channel Active ORing MOSFET.

Negative input pin of internal comparator. This pin should connect to the

drain of N-channel Active ORing MOSFET.

6

7

8

INN

Gnd

Vout

Ground pin of the IR5001.

Output pin for the IR5001. This pin is used to directly drive the gate of the

Active Oring N-Channel MOSFET.

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IR5001

BLOCK DIAGRAM

50K

1

VLINE

2

Vcc

12V Shunt

Regulator

5V, V^REF

8

7

V

OUT

5V

UVLO

1.25V

Generator

9V

Gnd

5V

12V

70K

5

INP

INN

clamp

Level

3.5mV

28mV

Shifter

70K

6

clamp

5V

4

FETst

0.3V

1.25V

3

FETch

2uA

Figure 2 - Simplified block diagram of the IR5001.

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IR5001

PARAMETER DEFINITION AND TIMING DIAGRAM

VOUT

V

(V^IN^IN^N^P=Gnd)

-Vos

Gnd

VINP - VINN

(0,0)

V^HYST

VHYST

V^OS

Figure 3 - Input Comparator Offset (Vos ) and Hysteresis

Voltage (Vhyst) Definition.

Figure 4 - Input Comparator Hysteresis Definition.

10ns

90mV

50mV

0

V^INP- V^INN= 200mV

-50mV

-90mV

V^IN

(V^INP- V^INN)

t^d(off)

t^d(on)

V^OH

90%

50%

10%

V^OL

V^OUT

t^f

t^r

Figure 5 - Dynamic Parameters.

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IR5001

TYPICAL OPERATING CHARACTERISTICS

10.8

10.4

10

180

170

160

150

140

130

120

9.6

9.2

8.8

8.4

-40 -20

0

20

40

60

80 100

-40

0

40

80

120

Temperature (°C)

Figure 6 - Turn Off Delay vs. Junction Temperature

Figure 7 - UVLO Upper Trip Point vs. Junction Temperature

5.7

5.6

5.5

5.4

5.3

5.2

5.1

28

26

24

22

20

18

16

-40

-10

20

50

80

110

140

-40

0

40

80

120

Temperature (°C)

Figure 8 - Vos vs. Junction Temperature

Figure 9 - Fall Time vs. Junction Temperature

-280

31

29

27

25

23

21

19

17

15

-300

-320

-340

-360

-380

-40 -20

0

20

40

60

80 100

-40

-10

20

50

80

110

140

Temperature (°C)

Figure 10 - INP, INN Input Hysteresis vs. Junction Temp.

Figure 11 - FETst Threshold Voltage vs. Junction Temp.

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IR5001

TYPICAL OPERATING CHARACTERISTICS

1.75

1.5

1.25

1

13

12.8

12.6

12.4

12.2

12

Top:

25°C

85°C

125°C

-40°C

125°C

85°C

25°C

-40°C

Bottom:

0.75

0.5

0.25

0

11.8

11.6

20

40

60

Vline (V)

80

100

20

40

60

Vline (V)

80

100

Figure 13 - I(Vline) vs. Vline and Junction Temperature

Figure 12 - Vcc vs. Vline and Junction Temperature

1.4

1.2

1

121.0

120.5

120.0

119.5

119.0

118.5

118.0

117.5

117.0

0.8

0.6

0.4

0.2

0

20

40

60

INN (V)

80

100

20

40

60

80

100

Vline (V)

Figure 15 - Turn Off Delay vs. Vline at Room Temperature

Figure 14 - Bias Current I(INN) vs. V(INN) at Vline=25V

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IR5001

An example of Rbias calculation is given below.

Vbias voltages used in the example are referenced

to IR5001 Gnd:

DETAILED PIN DESCRIPTION

Vline and Vcc

Vbias min = 12V

Vbias max = 16V

Vline and Vcc are the input and output pins of

the internal shunt regulator. The internal shunt

regulator regulates the Vcc voltage at ~12V. The

Vcc pin should always be by-passed with a ceramic

capacitor to the Gnd pin.

Rbias = (Vbias min – Vcc UVLOmax) / Icc min =

= (12V – 10.9V) / 0.5mA = 2.2kOhm

Next, using a minimum Vcc (10.2V), verify that Icc

with the selected Rbias will be less than 5mA:

Icc max = (Vbias max – Vcc min)/Rbias =

Both Vline and Vcc pins can be used for biasing

the IR5001, as shown in Fig. 16. The Vline pin is

designed to bias the IR5001 directly when the

available bias voltage is above 25V and less than

100V (targeted at typical 36V – 75V telecom

applications). This connection is shown in Fig 16.a.

If the available Vbias voltage is lower than 25V, then

the IC must be biased using Vcc pin and an external

bias resistor as shown in Fig. 16.b. If the available

bias voltage is above 100V, both Vline and Vcc pins

can be used with an external bias resistor. For

calculation of the proper bias resistor value, see

= (16V - 10.2V) / 2.2kOhm = 2.6mA

Since 2.6mA is below 5mA max Icc, the calculated

Rbias (2.2kOhm) can be used in this design.

INP and INN Inputs

INP and INN are the inputs of the internal high-

speed comparator. Both pins have integrated on-

board voltage clamps and high-voltage 70kOhm

resistors.

example below.

In a typical application, INP should be connected

to the source of the N-FET and INN to the drain. To

improve the noise immunity, the connections from

INN and INP pins to the source and drain terminals

of the N-FET should be as short as possible.

IR5001

Vline

Vcc

OUT

Gnd

INN

INP

+

FETch

FETst

Vbias

The (INP – INN) voltage difference determines

the state of the Vout pin of the IR5001. When the

body diode of the Active ORing N-FET is forward-

biased and the current first starts flowing, the

voltage difference INP – INN will quickly rise toward

~700mV (typical body diode forward voltage drop).

As soon as this voltage exceeds Vhyst – Vos

(27mV typical), the Vout of the IR5001 will be pulled

high, turning the channel of the active ORing FET

on. As the channel of the N-FET becomes fully

enhanced, the (INP – INN) will reduce and stabilize

at the value determined by the source-drain current,

Isd, and Rds(on) of the N-FET:

a)

IR5001

Vline

Vcc

OUT

Gnd

INN

INP

Rbias

+

FETch

FETst

Vbias

b)

(INP – INN) steady state = Isd * RDS(on).

Figue 16 - Biasing options for IR5001

When the Vcc pin is used for biasing the If for some reason (due to a short-circuit failure of

IR5001, the Vbias must always be higher than the the source, for example), the current reverses

maximum value of the Vcc UVLO threshold (10.9V). direction and tries to flow from drain to source, the

The Rbias resistor should always be connected (INP – INN) will become negative; The IR5001 will

between the Vbias voltage source and Vcc pin. The then quickly pull its output low, switching the ORing

Rbias resistor is selected to provide adequate Icc FET off. For considerations regarding the selection

current for the IC. The minimum required Icc to

guarantee proper IC operation under all conditions is

0.5mA. The maximum Icc is specified at 5mA.

of the Active ORing N-FET and RDS(on), see

Applications Information Section.

The offset voltage of the internal high-speed

comparator is centered around negative 4mV, and is

always less than 0mV. This asymmetrical offset

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IR5001

functioning properly unless external circuitry is used.

For example, the diode could be failed short, and the

system would not be aware of it until the source fails

and the whole system gets powered down due to

lost redundancy (shorted diode failed to isolate the

source failure). With the FETch pin it is possible to

perform a periodic check of the status of the Active

ORing circuit to assure that system redundancy is

maintained.

guarantees that once the ORing N-FET is

conducting and Vout of the IR5001 is high (FET

current flows from source to drain), the current must

reverse the direction before the IR5001 will switch

the FET off.

The asymmetrical offset voltage

prevents potential oscillations at light load that could

otherwise occur if the offset voltage was centered

around 0mV (as is the case in standard

comparators).

In the IR5001, the FETch pin is an input pin that

can be used to turn off the output of the IR5001:

logic high signal on FETch will pull the Vout pin low,

and turn-off the channel of the Active ORing N-FET.

This will force the current to flow through the body

diode, resulting in VINP – VINN voltage increase

from less than ~100mV, to ~700mV. This voltage

increase will be reported at FETst pin, which will

switch from logic high to logic low, and indicate that

the Active ORing circuit is working properly. Failure

of the FETst pin output to change from logic high to

logic low would indicate that the Active ORing circuit

may not be operating as designed, and the system

may no longer have power redundancy. For details

on how to use this feature consult IR5001 Evaluation

Kit, P/N IRDC5001-LS48V.

Vout

Vout is the output pin of the IR5001, and connects

directly to the gate of the external Active ORing N-

FET. The voltage level at the Vout pin is typically a

diode drop lower than the Vcc voltage.

FETst and FETch

FETch and FETst pins are diagnostic pins that can

be used to determine the status of the Active ORing

circuit.

FETst is an open-drain output pin. When the voltage

difference between VINP - VINN is less than 0.3V,

the FETst pin will be logic high. This is normally the

case when Active ORing is operating properly (VINP

- VINN is less than ~100mV). If the Active ORing

FET is not turned on while the IR5001 is properly

biased, the output of the FETst pin will be logic low

(only the body diode of the N-FET is conducting, and

VINP - VINN is ~700mV).

If t the FETch pin is not used, it should be tied to

ground (for noise immunity purposes). If not used,

FETst pin should be left open.

Gnd

In typical target applications, the ground pin (Gnd) of

IR5001 is connected to the source of the Active

ORing N-FET.

FETch pin. In traditional systems with diode ORing,

it is not possible to determine if the diode is

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IR5001

APPLICATION INFORMATION

Positive Rail ORing / Ground ORing in

Communications Boards

The IR5001 is designed for multiple active ORing

and reverse polarity protection applications with

minimal number of external components. Examples

of typical circuit connections are shown below.

An example of a typical connection in positive

rail ORing is shown in Fig. 18. Typical applications

are inside redundant AC-DC and DC-DC power

supplies, or on-board ORing. For positive rail ORing,

an additional Vbias voltage above the positive rail is

needed to bias the IR5001.

Negative Rail ORing/Reverse Polarity Protection

An evaluation kit for high-current 12V positive

rail ORing is available under p/n IRAC5001-

HS100A, demonstrating performance of the IR5001

at 100A output current.

A typical connection of the IR5001 in negative

rail Active ORing or reverse polarity protection is

shown in Fig. 17. In this example, IR5001 is biased

directly from the positive rail. However, any of the

biasing schemes shown in Fig. 16 can be used.

For input ORing in carrier-class communications

boards, one IR5001 is used per feed. This is shown

in Fig.1. An evaluation kit is available for typical

system boards, with input voltages of negative 36V

to negative 75V, and for power levels from 30W to

about 300W. The p/n for the evaluation kit is

Considerations for the Selection of the Active

ORing N-Channel MOSFET

Active ORing FET losses are all conduction

losses, and depend on the source-drain current and

RDS(on) of the FET. The conduction loss could be

virtually eliminated if a FET with very low RDS(on)

was used. However, using arbitrarily low RDS(on) is

not desirable for three reasons:

IRDC5001-LS48V.

detailed design considerations and in-circuit

performance data for the IR5001.

This evaluation kit contains

1. Turn off propagation delay. Higher RDS(on) will

provide more voltage information to the internal

comparator faster, and will result in faster FET

turn off protection in case of short-circuit of the

source (less voltage disturbance on the

redundant bus.

Vin +

IR5001

Vline

Vcc

OUT

Gnd

INN

INP

Rbias

2. Undetected reverse (drain to source) current

flow. With the asymmetrical offset voltage, some

small current can flow from the drain to source

of the ORing FET and be undetected by the

IR5001. The amount of undetected drain-source

current depends on the RDS(on) of the selected

MOSFET and its RDS(on). To keep the reverse

(drain-source) current below 5 – 10% of the

nominal source-drain state, the RDS(on) of the

selected FET should produce 50mV to 100mV of

the voltage drop during nominal operation.

Load

+

FETch

FETst

Vbias

Redundant Vin -

Vin -

Figure. 17 Connection of INN, INP, and Gnd for negative

rail Active ORing or reverse polarity protection.

3. Cost. With properly selected RDS(on), Active

ORing using IR5001 can be very cost

competitive with traditional ORing while

providing huge power loss reduction. For

example, a FET with 20mOhm RDS(on) results in

60mV voltage drop at 3A; associated power

savings compared to the traditional diode ORing

(assuming typical 0.6V forward voltage drop) is

ten fold(0.18W vs. 1.8W)! Now assume that

FET RDS(on) was 10mOhm. The power loss

would be reduced by additional 90mW, which is

negligible compared to the power loss reduction

already achieved with 20mOhm FET. But to get

this negligible saving, the cost of the Active

ORing FET would increase significantly.

Redundant Vout +

Vout +

IR5001

Vline

Vcc

OUT

Gnd

INN

INP

Rbias

Load

+

FETch

FETst

Vbias

Vout -

Figure. 18. Connection of INN,INP, and Gnd when the

MOSFET is placed in the path of positive rail.

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IR5001

In a well - designed Active ORing circuit, the

Rds(on) of the Active ORing FET should generate

between 50mV to 100mV of (INP – INN) voltage

during normal, steady state operation. (The normal

operation refers to current flowing from the source to

drain of the Active ORing FET, half of the full-load

system current flowing through each OR-ed source,

Pdiss < (Tj max – Tamb max) / Rtheta j-a

Since Tj max= 125 °C, Tamb = 85 °C, and Rtheta j-a

= 128 °C/W, the maximum power dissipation allowed

is:

at nominal input voltage).

Maximum power

Pdiss max = (125 – 85) / 128 = 0.3W

dissipation under worst-case conditions for the FET

should be calculated and verified against the data

sheet limits of the selected device.

With proper selection of Icc (as discussed in the

Detailed Pin Description), the maximum power

dissipation will never be exceeded (Max Icc * Max

Vcc = 10mA * 13.9V = 0.14W).

IR5001 Thermal considerations

Maximum junction temperature of the IR5001 in an

application should not exceed the maximum

operating junction temperature, specified at 125°C:

Layout Considerations

INN and INP should be connected very close to

the drain and source terminal of the Active ORing

FET. PCB trace between the Vout pin and the gate

of the N-FET should also be minimized. A minimum

of 0.1uF decoupling capacitor must be connected

from Vcc to Gnd of the IR5001and should be placed

as close to the IR5001 as possible. Ground should

be connected to the source of N-FET separately

from the INP pin.

Tj = Pdiss * Rtheta j-a + Tamb <= Tj (max),

where Rtheta j-a is the thermal resistance from

junction to ambient thermal resistance (specified at

128 °C/W), Pdiss is IC power dissipation, and Tamb

is operating ambient temperature.

The maximum power dissipation can be estimated

as follows:

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IR5001

(S) SOIC Package

8-Pin Surface Mount, Narrow Body

H

A

B

C

E

DETAIL-A

L

D

PIN NO. 1

DETAIL-A

I

0.38 +/- 0.015 x 45°

K

T

F

J

G

8-PIN

SYMBOL MIN

MAX

A

B

C

D

E

F

G

H

I

4.80

1.27 BSC

0.53 REF

4.98

0.36

0.46

3.99

1.72

0.25

3.81

1.52

0.10

7° BSC

0.19

5.80

0°

0.41

1.37

0.25

6.20

8°

1.27

1.57

J

K

L

T

NOTE: ALL MEASUREMENTS ARE IN MILLIMETERS.

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IR5001

PACKAGE SHIPMENT METHOD

PKG

DESIG

S

PACKAGE

DESCRIPTION

COUNT

8

PARTS

PER TUBE

95

PARTS

PER REEL

2500

T & R

Orientation

Fig A

SOIC, Narrow Body

1

Feed Direction

Figure A

This product has been designed and qualified for the industrial market

IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, USA Tel: (310) 252-7105

TAC Fax: (310) 252-7903

Visit us at www.irf.com for sales contact information

Data and specifications subject to change without notice. 4/8/2005

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型号：	IR5001
厂家：	Infineon
描述：	UNIVERSAL ACTIVE ORING CONTROLLER 通用有源ORing控制器控制器
文件：	总13页 (文件大小：227K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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IR500N-D0

IR500N-E0

IR5060

IR5061

IR5062

IR5063