ACS710_技术文档

ACS710

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

Features and Benefits

Description

▪Industry-leading noise performance with greatly improved

bandwidth through proprietary amplifier and filter design

techniques

The Allegro^™ACS710 current sensor provides economical

andprecisemeansforcurrentsensingapplicationsinindustrial,

commercial,andcommunicationssystems.Thedeviceisoffered

in a small footprint surface mount package that allows easy

implementation in customer applications.

▪Small footprint package suitable for space-constrained

applications

▪1 mꢀ primary conductor resistance for low power loss

▪High isolation voltage, suitable for line-powered

applications

▪User-adjustable Overcurrent Fault level

▪Overcurrent Fault signal typically responds to an

overcurrent condition in < 2 μs

▪Integrated shield virtually eliminates capacitive coupling

from current conductor to die due to high dV/dt voltage

transients

▪Filter pin capacitor improves resolution in low bandwidth

applications

TheACS710consistsofaprecisionlinearHallsensorintegrated

circuit with a copper conduction path located near the surface

of the silicon die. Applied current flows through the copper

conduction path, and the analog output voltage from the Hall

sensor linearly tracks the magnetic field generated by the

applied current. The accuracy of the ACS710 is maximized

with this patented packaging configuration because the Hall

element is situated in extremely close proximity to the current

to be measured.

High level immunity to current conductor dV/dt and stray

electric fields, offered byAllegro proprietary integrated shield

technology, results in low ripple on the output and low offset

drift in high-side, high voltage applications.

▪3 to 5.5 V, single supply operation

▪Factory trimmed sensitivity and quiescent output voltage

▪Chopper stabilization results in extremely stable quiescent

output voltage

The voltage on the Overcurrent Input (VOC pin) allows

customerstodefineanovercurrentfaultthresholdforthedevice.

When the current flowing through the copper conduction path

(betweentheIP+andIP–pins)exceedsthisthreshold, theopen

drain Overcurrent Fault pin will transition to a logic low state.

Factory programming of the linear Hall sensor inside of the

ACS710 results in exceptional accuracy in both analog and

digital output signals.

▪Ratiometric output from supply voltage

Package: 16-pin SOIC Hall Effect IC

Package (suffix LA)

The internal resistance of the copper path used for current

sensing is typically 1 mΩ, for low power loss.Also, the current

conduction path is electrically isolated from the low voltage

Approximate Scale 1:1

Continued on the next page…

Typical Application Circuit

V_CC

Fault_EN

R_H

1

2

3

4

5

6

7

8

16

15

14

13

12

11

10

9

IP+

IP–

FAULT_EN

VOC

R_H, R_LSets resistor divider reference for V_OC

ACS710

C_F

C_OC

A

Noise and bandwidth limiting filter capacitor

Fault delay setting capacitor, 22 nF maximum

Use of capacitor required

R_L

VCC

FAULT

VIOUT

FILTER

VZCR

GND

R_PU

I_P

C

OC

0.1 μF

B

V_IOUT

Use of resistor optional, 330 kΩ recommended.

If used, resistor must be connected between

B

C

F

¯¯¯¯¯¯¯¯¯

FAULT pin and V_CC

.

1 nF

A

ACS710-DS, Rev. 8

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Description (continued)

Pb-based solder balls, currently exempt from RoHS. The device is

fully calibrated prior to shipment from the factory.

sensorinputsandoutputs.ThisallowstheACS710familyofsensors

to be used in applications requiring electrical isolation, without the

use of opto-isolators or other costly isolation techniques.

Applications include:

• Motor control and protection

• Load management and overcurrent detection

• Power conversion and battery monitoring / UPS systems

TheACS710isprovidedinasmall,surfacemountSOIC16package.

The leadframe is plated with 100% matte tin, which is compatible

withstandardlead(Pb)freeprintedcircuitboardassemblyprocesses.

Internally,thedeviceisPb-free,exceptforflip-chiphigh-temperature

Selection Guide

Sens (typ)

at V_CC= 5 V

(mV/A)

I_P

(A)

Latched

Fault

T_A

(°C)

1

Part Number

Packing

ACS710KLATR-6BB-T^2,3

ACS710KLATR-12CB-T²

ACS710KLATR-25CB-T²

ACS710KLATR-6BB-NL-T^2,3

ACS710KLATR-12CB-NL-T²

ACS710KLATR-25CB-NL-T²

±6

151

56

±12.5

±25

Yes

–40 to 125

Tape and Reel, 1000 pieces per reel

28

±6

151

56

±12.5

±25

No

28

¹Contact Allegro for packing options.

²Variant not intended for automotive applications.

³The formerly offered V_CC= 3.3 V version of the I_P= ±6 A variant (formerly the ACS710KLATR-6BB-T) is now offered as the ACS716KLATR-

6BB-T. For additional information, please refer to the ACS716 datasheet.

Allegro MicroSystems, LLC

115 Northeast Cutoff

2

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Absolute Maximum Ratings

Characteristic

Symbol

V_CC

Notes

Rating

Unit

V

Supply Voltage

8

Filter Pin

V_FILTER

V_IOUT

V_OC

V

Analog Output Pin

Overcurrent Input Pin

32

8

V

¯¯¯¯¯¯¯¯¯

Overcurrent FAULT Pin

V_{¯¯¯¯¯¯¯¯¯}

8

V

FAULT

Fault Enable (FAULT_EN) Pin

V_FAULTEN

V_ZCR

8

V

Voltage Reference Output Pin

8

V

DC Reverse Voltage: VCC, FILTER, VIOUT, VOC,

V_Rdcx

V_EX

–0.5

0.3

V

¯¯¯¯¯¯¯¯¯

FAULT, FAULT_EN, and VZCR Pins

Excess to Supply Voltage: FILTER, VIOUT, VOC,

Voltage by which pin voltage can exceed the VCC pin

voltage

¯¯¯¯¯¯¯¯¯

FAULT, FAULT_EN, and VZCR Pins

Output Current Source

Output Current Sink

I_IOUT(Source)

I_IOUT(Sink)

T_A

3

1

mA

°C

Operating Ambient Temperature

Junction Temperature

Range K

–40 to 125

165

T_J(max)

°C

Storage Temperature

T_stg

–65 to 170

°C

Isolation Characteristics

Characteristic

Symbol

Notes

Rating

Unit

Agency type-tested for 60 seconds per

UL standard 1577

Dielectric Strength Test Voltage*

Working Voltage for Basic Isolation

V_ISO

3000

277

VAC

For basic (single) isolation per UL standard 1577;

for higher continuous voltage ratings, please contact

Allegro

V_WFSI

* Allegro does not conduct 60-second testing. It is done only during the UL certification process.

Thermal Characteristics

Characteristic

Symbol

Test Conditions

Value Unit

When mounted on Allegro demo board with 1332 mm²(654 mm²on com-

ponent side and 678 mm²on opposite side) of 2 oz. copper connected to

the primary leadframe and with thermal vias connecting the copper layers.

Performance is based on current flowing through the primary leadframe and

includes the power consumed by the PCB.

Package Thermal Resistance

R_θJA

17

ºC/W

Allegro MicroSystems, LLC

115 Northeast Cutoff

3

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Functional Block Diagram

Latching Version

VCC

D

Q

CLK

R

POR

Hall

Bias

POR

Fault Latch

FAULT Reset

FAULT_EN

VOC

Drain

–

+

FAULT

2V_REF

Control

Logic

OC Fault

3 mA

Fault

Comparator

VZCR

–

+

Sensitivity

Trim

IP+

IP–

VIOUT

Signal

Recovery

R_F(INT)

Hall

Amplifier

V_OUT(Q)

Trim

GND

FILTER

Terminal List Table, Latching Version

Number

Name

Description

Sensed current copper conduction path pins. Terminals for current being sensed;

fused internally, loop to IP– pins; unidirectional or bidirectional current flow.

1 through 4

IP+

Sensed current copper conduction path pins. Terminals for current being sensed;

fused internally, loop to IP+ pins; unidirectional or bidirectional current flow.

5 through 8

IP–

Pin-out Diagram

9

GND

VZCR

Device ground connection.

Voltage Reference Output pin. Zero current (0 A) reference; output voltage on this

pin scales with V_CC. (Not a highly accurate reference.)

10

16 FAULT_EN

IP+

IP–

1

2

3

4

5

6

7

8

15 VOC

Filter pin. Terminal for an external capacitor connected from this pin to GND to set

the device bandwidth.

11

12

FILTER

VIOUT

14 VCC

13 FAULT

12 VIOUT

11 FILTER

10 VZCR

Analog Output pin. Output voltage on this pin is proportional to current flowing

through the loop between the IP+ pins and IP– pins.

Overcurrent Fault pin. When current flowing between IP+ pins and IP– pins

exceeds the overcurrent fault threshold, this pin transitions to a logic low state.

¯¯¯¯¯¯¯¯¯

FAULT

13

14

15

9

GND

VCC

VOC

Supply voltage.

Overcurrent Input pin. Analog input voltage on this pin sets the overcurrent fault

threshold.

¯¯¯¯¯¯¯¯¯

16

FAULT_EN Enables overcurrent faulting when high. Resets FAULT when low.

Allegro MicroSystems, LLC

115 Northeast Cutoff

4

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Functional Block Diagram

Non-Latching Version

VCC

Hall

Bias

POR

Drain

–

VOC

FAULT

2V_REF

+

FAULT_EN

FAULT Reset

3 mA

OC Fault

VZCR

Fault

Comparator

Sensitivity

Trim

IP+

IP–

VIOUT

Signal

Recovery

R_F(INT)

Hall

Amplifier

V_OUT(Q)

Trim

GND

FILTER

Terminal List Table, Non-Latching Version

Number

Name

Description

Sensed current copper conduction path pins. Terminals for current being sensed;

fused internally, loop to IP– pins; unidirectional or bidirectional current flow.

1 through 4

IP+

Sensed current copper conduction path pins. Terminals for current being sensed;

fused internally, loop to IP+ pins; unidirectional or bidirectional current flow.

5 through 8

IP–

Pin-out Diagram

9

GND

VZCR

Device ground connection.

Voltage Reference Output pin. Zero current (0 A) reference; output voltage on this

pin scales with V_CC. (Not a highly accurate reference.)

10

16 FAULT_EN

IP+

IP–

1

2

3

4

5

6

7

8

15 VOC

Filter pin. Terminal for an external capacitor connected from this pin to GND to set

the device bandwidth.

11

12

FILTER

VIOUT

14 VCC

13 FAULT

12 VIOUT

11 FILTER

10 VZCR

Analog Output pin. Output voltage on this pin is proportional to current flowing

through the loop between the IP+ pins and IP– pins.

Overcurrent Fault pin. When current flowing between IP+ pins and IP– pins

exceeds the overcurrent fault threshold, this pin transitions to a logic low state.

¯¯¯¯¯¯¯¯¯

FAULT

13

14

15

9

GND

VCC

VOC

Supply voltage.

Overcurrent Input pin. Analog input voltage on this pin sets the overcurrent fault

threshold.

16

FAULT_EN Enables overcurrent faulting when high.

Allegro MicroSystems, LLC

115 Northeast Cutoff

5

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

COMMON OPERATING CHARACTERISTICS Valid at T_A= –40°C to 125°C, V_CC= 5 V, unless otherwise specified

Characteristic

Symbol

Test Conditions

Min.

Typ.

Max.

Units

ELECTRICAL CHARACTERISTICS

Supply Voltage¹

V_CC

3

–

5

5.5

–

V

Nominal Supply Voltage

V_CCN

¯¯¯¯¯¯¯¯¯

Supply Current

I_CC

VIOUT open, FAULT pin high

–

11

–

14.5

10

–

mA

nF

Output Capacitance Load

Output Resistive Load

C_LOAD

R_LOAD

VIOUT pin to GND

10

–

kΩ

Magnetic Coupling from Device Conductor

to Hall Element

MC_HALL

Current flowing from IP+ to IP– pins

–

9.5

–

G/A

Internal Filter Resistance²

R_F(INT)

–

1.7

1

–

kꢀ

Primary Conductor Resistance

R_PRIMARY

T_A= 25°C

mΩ

ANALOG OUTPUT SIGNAL CHARACTERISTICS

Full Range Linearity³

Symmetry⁴

E_LIN

I_P= ±I_P0A

–0.75

99.1

±0.25

100

0.75

%

E_SYM

100.9

Bidirectional Quiescent Output

V_OUT(QBI)

I_P= 0 A, T_A= 25°C

–

V_CC×0.5

–

V

TIMING PERFORMANCE CHARACTERISTICS

T_A= 25°C, Swing I_Pfrom 0 A to I_P0A

no capacitor on FILTER pin, 100 pF from

VIOUT to GND

,

VIOUT Signal Rise Time

t_r

–

3

1

4

–

ꢁs

T_A= 25°C, no capacitor on FILTER pin,

100 pF from VIOUT to GND

VIOUT Signal Propagation Time

VIOUT Signal Response Time

t_PROP

T_A= 25°C, Swing I_Pfrom 0 A to I_P0A

,

t_RESPONSE

no capacitor on FILTER pin, 100 pF from

VIOUT to GND

–3 dB, Apply I_Psuch that V_IOUT= 1 V_pk-pk

no capacitor on FILTER pin, 100 pF from

VIOUT to GND

,

VIOUT Large Signal Bandwidth

Power-On Time

f_3dB

–

120

35

–

kHz

Output reaches 90% of steady-state level,

no capacitor on FILTER pin, T_A= 25°C

t_PO

ꢁs

OVERCURRENT CHARACTERISTICS

Setting Voltage for Overcurrent Switchpoint⁵

V_OC

V_CC×0.25

–

V_CC×0.4

–

V

A

Signal Noise at Overcurrent

Comparator Input

I_NCOMP

±1

Switchpoint in V_OCsafe operating area;

assumes I_NCOMP= 0 A

Overcurrent Fault Switchpoint Error^6,7

E_OC

–

±5

–

%

V

¯¯¯¯¯¯¯¯¯

Overcurrent FAULT Pin Output Voltage

V_{¯¯¯¯¯¯¯¯¯}

0.4

¯¯¯¯¯¯¯¯¯

1 mA sink current at FAULT pin

FAULT

Fault Enable (FAULT_EN Pin) Input Low

Voltage Threshold

V_IL

V_IH

–

0.8 × V_CC

–

1

0.1×V_CC

V

Fault Enable (FAULT_EN Pin) Input High

Voltage Threshold

–

Fault Enable (FAULT_EN Pin) Input

Resistance

R_FEI

Mꢀ

Continued on the next page…

Allegro MicroSystems, LLC

115 Northeast Cutoff

6

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

COMMON OPERATING CHARACTERISTICS (continued) Valid at T_A= –40°C to 125°C, V_CC= 5 V, unless otherwise specified

Characteristic

Symbol

Test Conditions

Min.

Typ.

Max.

Units

OVERCURRENT CHARACTERISTICS (continued)

Set FAULT_EN to low, V_OC= 0.25 × V_CC

,

C_OC= 0 F; then run a DC I_Pexceeding the

corresponding overcurrent threshold; then

reset FAULT_EN from low to high and

measure the delay from the rising edge of

Fault Enable (FAULT_EN Pin) Delay⁸

t_FED

–

15

–

μs

¯¯¯¯¯¯¯¯¯

FAULT_EN to the falling edge of FAULT

Set FAULT_EN to low, V_OC= 0.25 × V_CC

,

C_OC= 0 F; then run a DC I_Pexceeding the

Fault Enable (FAULT_EN Pin) Delay

(Non-Latching versions)⁹

corresponding overcurrent threshold; then

reset FAULT_EN from low to high and

measure the delay from the rising edge of

t_FED(NL)

–

150

1.9

–

ns

¯¯¯¯¯¯¯¯¯

FAULT_EN to the falling edge of FAULT

FAULT_EN set to high for a minimum

of 20 μs before the overcurrent event;

switchpoint set at V_OC= 0.25 × V_CC

;

Overcurrent Fault Response Time

t_OC

μs

delay from I_Pexceeding overcurrent

fault threshold to V_{¯¯¯¯¯¯¯¯¯}< 0.4 V, without

FAULT

external C_OCcapacitor

FAULT_EN set to high for a minimum

of 20 μs before the undercurrent event;

switchpoint set at V_OC= 0.25 × V_CC; delay

from I_Pfalling below the overcurrent fault

Undercurrent Fault Response Time

(Non-Latching versions)

t_UC

–

3

–

μs

threshold to V_{¯¯¯¯¯¯¯¯¯}> 0.8 × V_CC, without

FAULT

external C_OCcapacitor, R_PU= 330 kΩ

Time from V_FAULTEN< V_ILto

Overcurrent Fault Reset Delay

t_OCR

500

ns

V_{¯¯¯¯¯¯¯¯¯}> 0.8 × V_CC, R_PU= 330 kΩ

FAULT

Time from V_FAULTEN<V_ILto rising edge of

Overcurrent Fault Reset Hold Time

t_OCH

R_OC

–

2

250

–

ns

V_{¯¯¯¯¯¯¯¯¯}

FAULT

Overcurrent Input Pin Resistance

T_A= 25°C, VOC pin to GND

MΩ

VOLTAGE REFERENCE CHARACTERISTICS

T_A= 25 °C

(Not a highly accurate reference)

Voltage Reference Output

V_ZCR

0.48 x V_CC0.5 × V_CC0.51xV_CC

V

Source current

Sink current

3

50

–

mA

μA

Voltage Reference Output Load Current

Voltage Reference Output Drift

I_ZCR

∆V_ZCR

±10

mV

¹Devices are programmed for maximum accuracy at V_CC= 5 V. The device contains ratiometry circuits that accurately alter the 0 A Output Voltage and

Sensitivity level of the device in proportion to the applied V_CClevel. However, as a result of minor nonlinearities in the ratiometry circuit, additional output

error will result when V_CCvaries from the V_CClevel at which the device was programmed. Customers that plan to operate the device at a V_CClevel other

than the V_CClevel at which the device was programmed should contact their local Allegro sales representative regarding expected device accuracy levels

under these bias conditions.

²R_F(INT)forms an RC circuit via the FILTER pin.

³This parameter can drift by as much as 0.8% over the lifetime of this product.

⁴This parameter can drift by as much as 1% over the lifetime of this product.

⁵See page 8 on how to set overcurrent fault switchpoint.

⁶Switchpoint can be lower at the expense of switchpoint accuracy.

⁷This error specification does not include the effect of noise. See the I_NCOMPspecification in order to factor in the additional influence of noise on the

fault switchpoint.

⁸Fault Enable Delay is designed to avoid false tripping of an Overcurrent (OC) fault at power-up. A 15 μs (typical) delay will always be needed, every

time FAULT_EN is raised from low to high, before the device is ready for responding to any overcurrent event.

⁹During power-up, this delay is 15 μs in order to avoid false tripping of an Overcurrent (OC) fault.

Allegro MicroSystems, LLC

115 Northeast Cutoff

7

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

PERFORMANCE CHARACTERISTICS, T_ARange K, valid at T_A= –40°C to 125°C, V_CC= 5 V, unless otherwise specified

Characteristic

X6BB CHARACTERISTICS

Optimized Accuracy Range¹

Linear Sensing Range

Noise²

Symbol

Test Conditions

Min.

Typ.

Max.

Units

I_POA

I_R

–7.5

–14

–

7.5

14

–

A

–

V_NOISE(rms)T_A= 25°C, Sens = 100 mV/A, C_f= 0, C_LOAD= 4.7 nF, R_LOADopen

I_P= 6.5 A, T_A= 25°C

4.05

151

152

±10

±11

±40

±1.6

±5.6

mV

mV/A

mV

%

–

Sensitivity³

Sens

I_P= 6.5 A, T_A= 25°C to 125°C

–

I_P= 6.5 A, T_A= –40°C to 25°C

–

I_P= 0 A, T_A= 25°C

–

Electrical Offset Voltage

Variation Relative to

V_OE

I_P= 0 A, T_A= 25°C to 125°C

–

4

V_OUT(QBI)

I_P= 0 A, T_A= –40°C to 25°C

–

Over full scale of I_POA, I_Papplied for 5 ms, T_A= 25°C to 125°C

Over full scale of I_POA, I_Papplied for 5 ms, T_A= –40°C to 25°C

–

Total Output Error⁵

E_TOT

–

%

X12CB CHARACTERISTICS

Optimized Accuracy Range¹

Linear Sensing Range

Noise²

I_POA

I_R

–12.5

–

12.5

A

–37.5

37.5

–

V_NOISE(rms)T_A= 25°C, Sens = 56 mV/A, C_f= 0, C_LOAD= 4.7 nF, R_LOADopen

I_P= 12.5 A, T_A= 25°C

–

1.50

56

mV

mV/A

mV

%

–

Sensitivity³

Sens

I_P= 12.5 A, T_A= 25°C to 125°C

56

–

I_P= 12.5 A, T_A= –40°C to 25°C

57

–

I_P= 0 A, T_A= 25°C

±4

–

Electrical Offset Voltage

Variation Relative to

V_OE

I_P= 0 A, T_A= 25°C to 125°C

±14

±23

±2.2

±3.9

–

4

V_OUT(QBI)

I_P= 0 A, T_A= –40°C to 25°C

–

Over full scale of I_POA, I_Papplied for 5 ms, T_A= 25°C to 125°C

Over full scale of I_POA, I_Papplied for 5 ms, T_A= –40°C to 25°C

–

Total Output Error⁵

E_TOT

–

%

Continued on the next page…

Allegro MicroSystems, LLC

115 Northeast Cutoff

8

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

PERFORMANCE CHARACTERISTICS (continued), T_ARange K, valid at T_A= –40°C to 125°C, V_CC= 5 V, unless otherwise specified

X25CB CHARACTERISTICS

Optimized Accuracy Range¹

Linear Sensing Range

Noise²

I_POA

–25

–75

–

25

75

–

A

I_R

V_NOISE(rms)T_A= 25°C, Sens = 28 mV/A, C_f= 0, C_LOAD= 4.7 nF, R_LOADopen

I_P= 25 A, T_A= 25°C

1

mV

mV/A

mV

%

–

28

–

Sensitivity³

Sens

I_P= 25 A, T_A= 25°C to 125°C

–

27.9

28.5

±3

–

I_P= 25 A, T_A= –40°C to 25°C

–

I_P= 0 A, T_A= 25°C

–

Electrical Offset Voltage

Variation Relative to

V_OE

I_P= 0 A, T_A= 25°C to 125°C

–

±12

±18

±2.9

±5.2

–

4

V_OUT(QBI)

I_P= 0 A, T_A= –40°C to 25°C

–

Over full scale of I_POA, I_Papplied for 5 ms, T_A= 25°C to 125°C

Over full scale of I_POA, I_Papplied for 5 ms, T_A= –40°C to 25°C

–

Total Output Error⁵

E_TOT

–

%

¹Although the device is accurate over the entire linear range, the device is programmed for maximum accuracy over the range defined by I_POA

.

The reason for this is that in many applications, such as motor control, the start-up current of the motor is approximately three times higher than the

running current.

²V_pk-pknoise (6 sigma noise) is equal to 6 × V_NOISE(rms). Lower noise levels than this can be achieved by using C_ffor applications requiring narrower

bandwidth. See Characteristic Performance page for graphs of noise versus C_fand bandwidth versus C_f.

³This parameter can drift by as much as 2.4% over the lifetime of this product.

⁴This parameter can drift by as much as 13 mV over the lifetime of this product.

⁵This parameter can drift by as much as 2.5% over the lifetime of this product.

Allegro MicroSystems, LLC

115 Northeast Cutoff

9

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Characteristic Performance

ACS710 Bandwidth versus External Capacitor Value, C_F

Capacitor connected between FILTER pin and GND

1000

100

10

1

0.1

0.01

0.1

1

10

100

1000

Capacitance (nF)

ACS710 Noise versus External Capacitor Value, C_F

Capacitor connected between FILTER pin and GND

ACS710x-25C

= 3.3 V

V

= 5 V

V

CC

900

800

700

600

500

400

300

1000

900

800

700

600

500

400

0

10

20

30

40

50

0

10

20

30

40

50

Capacitance (nF)

ACS710x-12C

V

= 5 V

V

= 3.3 V

CC

1600

1400

1200

1000

800

600

400

200

0

1600

1400

1200

1000

800

600

400

200

0

10

20

30

40

50

0

10

20

30

40

50

Capacitance (nF)

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Characteristic Performance Data

Data taken using the ACS710-6BB

Accuracy Data

Electrical Offset Voltage versus Ambient Temperature

Sensitivity versus Ambient Temperature

50

40

160.0

157.5

155.0

152.5

150.0

147.5

145.0

142.5

140.0

30

20

10

0

-10

-20

-30

-40

-50

–50

-25

0

25

50

75

100

125

150

–50

-25

0

25

50

75

100

125

150

T_A(°C)

Nonlinearity versus Ambient Temperature

Symmetry versus Ambient Temperature

101.00

100.75

100.50

100.25

100.00

99.75

0.4

0.3

0.2

0.1

0

-0.1

-0.2

-0.3

-0.4

99.50

99.25

99.00

–50

-25

0

25

50

75

100

125

150

–50

-25

0

25

50

75

100

125

150

T_A(°C)

Total Output Error versus Ambient Temperature

6.0

4.5

3.0

1.5

0

-1.5

-3.0

-4.5

-6.0

–50

-25

0

25

50

75

100

125

150

T_A(°C)

Typical Maximum Limit

Typical Minimum Limit

Mean

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Characteristic Performance Data

Data taken using the ACS710-12CB

Accuracy Data

Electrical Offset Voltage versus Ambient Temperature

Sensitivity versus Ambient Temperature

58.5

58.0

57.5

57.0

56.5

56.0

55.5

55.0

25

20

15

10

5

0

-5

-10

-15

-20

-25

–50

-25

0

25

50

75

100

125

150

–50

-25

0

25

50

75

100

125

150

T_A(°C)

Nonlinearity versus Ambient Temperature

Symmetry versus Ambient Temperature

0.10

100.1

100.0

99.9

99.8

99.7

99.6

99.5

0.05

0

-0.05

-0.10

-0.15

-0.20

-0.25

-0.30

-0.35

-0.40

-0.45

–50

-25

0

25

50

75

100

125

150

–50

-25

0

25

50

75

100

125

150

T_A(°C)

Total Output Error versus Ambient Temperature

6

5

4

3

2

1

0

-1

-2

-3

–50

-25

0

25

50

75

100

125

150

T_A(°C)

Typical Maximum Limit

Typical Minimum Limit

Mean

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Characteristic Performance Data

Data taken using the ACS710-25CB

Accuracy Data

Electrical Offset Voltage versus Ambient Temperature

Sensitivity versus Ambient Temperature

29.6

29.4

29.2

29.0

28.8

28.6

28.4

28.2

28.0

27.8

27.6

25

20

15

10

5

0

-5

-10

-15

-20

-25

–50

-25

0

25

50

75

100

125

150

–50

-25

0

25

50

75

100

125

150

T_A(°C)

Nonlinearity versus Ambient Temperature

Symmetry versus Ambient Temperature

0.10

100.1

100.0

99.9

99.8

99.7

99.6

99.5

0.05

0

-0.05

-0.10

-0.15

-0.20

-0.25

-0.30

-0.35

–50

-25

0

25

50

75

100

125

150

–50

-25

0

25

50

75

100

125

150

T_A(°C)

Total Output Error versus Ambient Temperature

6

5

4

3

2

1

0

-1

-2

-3

–50

-25

0

25

50

75

100

125

150

T_A(°C)

Typical Maximum Limit

Typical Minimum Limit

Mean

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Setting Overcurrent Fault Switchpoint

|Ioc | is the overcurrent fault switchpoint for a bi-

directional (AC) current, which means a bi-directional

sensor will have two symmetrical overcurrent fault

Setting 12CB and 25CB Versions

The V_OCneeded for setting the overcurrent fault

switchpoint can be calculated as follows:

V

_OC= Sens × |I_OC| ,

switchpoints, +I_OCand –I_OC

.

where V_OCis in mV, Sens in mV/A, and I_OC(overcur-

rent fault switchpoint) in A.

See the following graph for I_OCand V_OCranges.

I_OCversus V_OC

(12CB and 25CB Versions)

I_OC

0.4 V_CC/ Sens

Not Valid Range

Valid Range

0.25 V_CC/ Sens

0

V_OC

0. 25 V_CC

0. 4 V_CC

– 0.25 V_CC/ Sens

– 0.4 V_CC/ Sens

Example: For ACS710KLATR-25CB-T, if required overcurrent fault switchpoint is 50 A, and V_CC= 5 V, then the

required V_OCcan be calculated as follows:

V_OC= Sens × I_OC= 28 × 50 = 1400 (mV)

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

|Ioc | is the overcurrent fault switchpoint for a bi-

Setting 6BB Versions

The V_OCneeded for setting the overcurrent fault

switchpoint can be calculated as follows:

directional (AC) current, which means a bi-directional

sensor will have two symmetrical overcurrent fault

V

_OC= 1.17 × Sens × |I_OC| ,

switchpoints, +I_OCand –I_OC

.

where V_OCis in mV, Sens in mV/A, and I_OC(overcur-

rent fault switchpoint) in A.

See the following graph for I_OCand V_OCranges.

I_OCversus V_OC

(6BB Versions)

I_OC

0.4 V_CC/(1.17 × Sens)

Not Valid Range

Valid Range

0.25 V_CC/(1.17 × Sens)

0

V_OC

0.25 V_CC

0.4 V_CC

–0.25 V_CC/(1.17 × Sens)

– 0.4 V_CC/ (1.17 × Sens)

Example: For ACS710KLATR-6BB-T, if required overcurrent fault switchpoint is 10 A, and V_CC= 5 V, then the

required V_OCcan be calculated as follows:

V_OC= 1.17 × Sens × I_OC= 1.17 × 151 × 10 = 1767 (mV)

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Functional Description (Latching Versions)

internal NMOS pull-down turns off and an internal PMOS pull-

Overcurrent Fault Operation

The primary concern with high-speed fault detection is that noise

may cause false tripping. Various applications have or need to

be able to ignore certain faults that are due to switching noise or

other parasitic phenomena, which are application dependant. The

problem with simply trying to filter out this noise in the main

signal path is that in high-speed applications, with asymmetric

noise, the act of filtering introduces an error into the measure-

ment. To get around this issue, and allow the user to prevent the

fault signal from being latched by noise, a circuit was designed to

up turns on (see [7] if the OC fault condition still exists).

4. The slope, and thus the delay to latch the fault is controlled by

¯¯¯¯¯¯¯¯¯

the capacitor, C_OC, placed on the FAULT pin to ground. Dur-

¯¯¯¯¯¯¯¯¯

ing this portion of the fault (when the FAULT pin is between

V_CCand 2 V), there is a 3 mA constant current sink, which

discharges C_OC. The length of the fault delay, t, is equal to:

C_OC( V_CC– 2 V )

t

=

(1)

3 mA

¯¯¯¯¯¯¯¯¯

where V_CCis the device power supply voltage in volts, t is in

seconds and C_OCis in Farads. This formula is valid for R_PU

equal to or greater than 330 kꢀ. For lower-value resistors,

the current flowing through the R_PUresistor during a fault

event, I_PU, will be larger. Therefore, the current discharging

the capacitor would be 3 mA – I_PUand equation 1 may not be

valid.

slew the FAULT pin voltage based on the value of the capacitor

from that pin to ground. Once the voltage on the pin falls below

2 V, as established by an internal reference, the fault output is

latched and pulled to ground quickly with an internal N-channel

MOSFET.

Fault Walk-through

The following walk-through references various sections and

attributes in the figure below. This figure shows different

fault set/reset scenarios and how they relate to the voltages on

¯¯¯¯¯¯¯¯¯

5. The FAULT pin did not reach the 2 V latch point before the

OC fault condition cleared. Because of this, the fixed 3 mA

current sink turns off, and the internal PMOS pull-up turns on

¯¯¯¯¯¯¯¯¯

the FAULT pin, FAULT_EN pin, and the internal Overcurrent

¯¯¯¯¯¯¯¯¯

to recharge C_OCthrough the FAULT pin.

(OC) Fault node, which is invisible to the customer.

6. This curve shows V_CCcharging external capacitor C_OC

through the internal PMOS pull-up. The slope is determined

1. Because the device is enabled (FAULT_EN is high for a

minimum period of time, the Fault Enable Delay, t_FED, 15 ꢁs

by C_OC

.

¯¯¯¯¯¯¯¯¯

typical) and there is an OC fault condition, the device FAULT

pin starts discharging.

7. When the FAULT_EN pin is brought low, if the fault condition

¯¯¯¯¯¯¯¯¯

still exists, the latched FAULT pin will be pulled low by the

¯¯¯¯¯¯¯¯¯

2. When the FAULT pin voltage reaches approximately 2 V, the

internal 3mA current source. When fault condition is removed

then the Fault pin charges as shown in step 6.

¯¯¯¯¯¯¯¯¯

fault is latched, and an internal NMOS device pulls the FAULT

¯¯¯¯¯¯¯¯¯

pin voltage to approximately 0 V. The rate at which the FAULT

pin slews downward (see [4] in the figure) is dependent on the

8. At this point there is a fault condition, and the part is enabled

¯¯¯¯¯¯¯¯¯

external capacitor, C_OC, on the FAULT pin.

¯¯¯¯¯¯¯¯¯

before the FAULT pin can charge to V_CC. This shortens the

¯¯¯¯¯¯¯¯¯

user-set delay, so the fault is latched earlier. The new delay

time can be calculated by equation 1, after substituting the

3. When the FAULT_EN pin is brought low, the FAULT

pin starts resetting if no OC fault condition exists, and if

FAULT_EN is low for a time period greater than t_OCH. The

¯¯¯¯¯¯¯¯¯

voltage seen on the FAULT pin for V_CC

.

1

V_CC

4

6

t_FED

8

4

FAULT

(Output)

6

5

4

2

6

2 V

7

3

0 V

Time

FAULT_EN

(Input)

OC Fault

Condition

(Active High)

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Functional Description (Non-Latching Versions)

than t_OCH. The internal NMOS pull-down turns off and an

Overcurrent Fault Operation

The primary concern with high-speed fault detection is that noise

may cause false tripping. Various applications have or need to

be able to ignore certain faults that are due to switching noise or

other parasitic phenomena, which are application dependant. The

problem with simply trying to filter out this noise in the main sig-

nal path is that in high-speed applications, with asymmetric noise,

the act of filtering introduces an error into the measurement.

To get around this issue, and allow the user to prevent the fault

signal from going low due to noise, a circuit was designed to slew

internal PMOS pull-up turns on.

4. The slope, and thus the delay to pull the fault low is controlled

¯¯¯¯¯¯¯¯¯

by the capacitor, C_OC, placed on the FAULT pin to ground.

During this portion of the fault (when the FAULT pin is

between V_CCand 2 V), there is a 3 mA constant current sink,

which discharges C_OC. The length of the fault delay, t, is equal

to:

¯¯¯¯¯¯¯¯¯

C_OC( V_CC– 2 V )

t

=

(2)

3 mA

¯¯¯¯¯¯¯¯¯

the FAULT pin voltage based on the value of the capacitor from

that pin to ground. Once the voltage on the pin falls below 2 V, as

established by an internal reference, the fault output is pulled to

ground quickly with an internal N-channel MOSFET.

where V_CCis the device power supply voltage in volts, t is in

seconds and C_OCis in Farads. This formula is valid for R_PU

equal to or greater than 330 kꢀ. For lower-value resistors,

the current flowing through the R_PUresistor during a fault

event, I_PU, will be larger. Therefore, the current discharging

the capacitor would be 3 mA – I_PUand equation 1 may not be

valid.

Fault Walk-through

The following walk-through references various sections and

attributes in the figure below. This figure shows different

fault set/reset scenarios and how they relate to the voltages on

¯¯¯¯¯¯¯¯¯

the FAULT pin, FAULT_EN pin, and the internal Overcurrent

¯¯¯¯¯¯¯¯¯

5. The FAULT pin did not reach the 2 V latch point before the

(OC) Fault node, which is invisible to the customer.

OC fault condition cleared. Because of this, the fixed 3 mA

current sink turns off, and the internal PMOS pull-up turns on

¯¯¯¯¯¯¯¯¯

to recharge C_OCthrough the FAULT pin.

1. Because the device is enabled (FAULT_EN is high for a mini-

mum period of time, the Fault Enable Delay, t_FED, and there is

¯¯¯¯¯¯¯¯¯

an OC fault condition, the device FAULT pin starts discharging. 6. This curve shows V_CCcharging external capacitor C_OC

through the internal PMOS pull-up. The slope is determined

by C_OC

7. At this point there is a fault condition, and the part is enabled

¯¯¯¯¯¯¯¯¯

2. When the FAULT pin voltage reaches approximately 2 V, an

.

¯¯¯¯¯¯¯¯¯

internal NMOS device pulls the FAULT pin voltage to approx-

¯¯¯¯¯¯¯¯¯

imately 0 V. The rate at which the FAULT pin slews downward

(see [4] in the figure) is dependent on the external capacitor,

¯¯¯¯¯¯¯¯¯

before the FAULT pin can charge to V_CC. This shortens the

¯¯¯¯¯¯¯¯¯

C_OC, on the FAULT pin.

user-set delay, so the fault gets pulled low earlier. The new

delay time can be calculated by equation 1, after substituting

the voltage seen on the FAULT pin for V_CC

¯¯¯¯¯¯¯¯¯

3. When the FAULT_EN pin is brought low, the FAULT pin

starts resetting if FAULT_EN is low for a time period greater

¯¯¯¯¯¯¯¯¯

.

1

V_CC

4

6

t_FED

7

4

FAULT

(Output)

6

5

4

2

6

2 V

3

0 V

Time

FAULT_EN

(Input)

OC Fault

Condition

(Active High)

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Chopper Stabilization Technique

Chopper Stabilization is an innovative circuit technique that is

used to minimize the offset voltage of a Hall element and an asso-

ciated on-chip amplifier. Allegro patented a Chopper Stabiliza-

tion technique that nearly eliminates Hall IC output drift induced

by temperature or package stress effects. This offset reduction

technique is based on a signal modulation-demodulation process.

Modulation is used to separate the undesired dc offset signal from

the magnetically induced signal in the frequency domain. Then,

using a low-pass filter, the modulated DC offset is suppressed

while the magnetically induced signal passes through the filter.

As a result of this chopper stabilization approach, the output

voltage from the Hall IC is desensitized to the effects of tempera-

ture and mechanical stress. This technique produces devices that

have an extremely stable Electrical Offset Voltage, are immune to

thermal stress, and have precise recoverability after temperature

cycling.

This technique is made possible through the use of a BiCMOS

process that allows the use of low-offset and low-noise amplifiers

in combination with high-density logic integration and sample

and hold circuits.

Regulator

Clock/Logic

Low-Pass

Filter

Hall Element

Amp

Concept of Chopper Stabilization Technique

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Definitions of Accuracy Characteristics

Sensitivity (Sens). The change in sensor output in response to a

1A change through the primary conductor. The sensitivity is the

product of the magnetic circuit sensitivity (G/A) and the linear

IC amplifier gain (mV/G). The linear IC amplifier gain is pro-

grammed at the factory to optimize the sensitivity (mV/A) for the

full-scale current of the device.

Accuracy is divided into four areas:

 0 A at 25°C. Accuracy of sensing zero current flow at 25°C,

without the effects of temperature.

 0 A over Δ temperature. Accuracy of sensing zero current

flow including temperature effects.

 Full-scale current at 25°C. Accuracy of sensing the full-scale

current at 25°C, without the effects of temperature.

Noise (V_NOISE). The product of the linear IC amplifier gain

(mV/G) and the noise floor for the Allegro Hall effect linear

IC. The noise floor is derived from the thermal and shot noise

observed in Hall elements. Dividing the noise (mV) by the sensi-

tivity (mV/A) provides the smallest current that the device is able

to resolve.

 Full-scale current over Δ temperature. Accuracy of sensing full-

scale current flow including temperature effects.

Ratiometry. The ratiometric feature means that its 0 A output,

V_IOUT(Q), (nominally equal to V_CC/2) and sensitivity, Sens, are

Linearity (E_LIN). The degree to which the voltage output from

the sensor varies in direct proportion to the primary current

through its full-scale amplitude. Nonlinearity in the output can be

attributed to the saturation of the flux concentrator approaching

the full-scale current. The following equation is used to derive the

linearity:

proportional to its supply voltage, V_CC.The following formula is

used to derive the ratiometric change in 0 A output voltage,

V_IOUT(Q)RAT(%).

V

_IOUT(Q)VCC/ V_IOUT(Q)5V

100

V_CC

/

5 V





V_{IOUT_full-scale amperes}– V_IOUT(Q)

2 (V_{IOUT_1/2 full-scale amperes}– V_IOUT(Q)

100

1–

The ratiometric change in sensitivity, Sens_RAT(%), is defined as:

{

[

₎[ {

^Sens^VCC^{/ Sens}^5V

where V_{IOUT_full-scale amperes}= the output voltage (V) when the

sensed current approximates full-scale ±I_P.

100

V_CC

/

5 V



Symmetry (E_SYM). The degree to which the absolute voltage

output from the sensor varies in proportion to either a positive

or negative full-scale primary current. The following formula is

used to derive symmetry:

Output Voltage versus Sensed Current

Accuracy at 0 A and at Full-Scale Current

Increasing V_IOUT(V)

Accuracy

Over $Temp erature

V_{IOUT_+ full-scale amperes}– V_IOUT(Q)

100

V

_IOUT(Q)– V_{IOUT_–full-scale amperes}

Accuracy





25°C Only

Quiescent output voltage (V_IOUT(Q)). The output of the sensor

when the primary current is zero. For a unipolar supply voltage,

it nominally remains at 0.5×V_CC. For example, in the case of a

Average

V

IOUT

Accuracy

Over $Temp erature

bidirectional output device, V_CC= 5 V translates into V_IOUT(Q)

=

2.5 V. Variation in V_IOUT(Q)can be attributed to the resolution of

the Allegro linear IC quiescent voltage trim and thermal drift.

Accuracy

25°C Only

I_P(min)

Electrical offset voltage (V_OE). The deviation of the device out-

put from its ideal quiescent voltage due to nonmagnetic causes.

To convert this voltage to amperes, divide by the device sensitiv-

ity, Sens.

–I_P(A)

+I_P(A)

Full Scale

I_P(max)

0 A

Accuracy (E_TOT). The accuracy represents the maximum devia-

tion of the actual output from its ideal value. This is also known

as the total ouput error. The accuracy is illustrated graphically in

the output voltage versus current chart at right. Note that error is

directly measured during final test at Allegro.

Accuracy

25°C Only

Accuracy

Over $Temp erature

Decreasing V_IOUT(V)

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Definitions of Dynamic Response Characteristics

Primary Current

I (%)

90

Propagation delay (t_PROP). The time required for the sensor

output to reflect a change in the primary current signal. Propaga-

tion delay is attributed to inductive loading within the linear IC

package, as well as in the inductive loop formed by the primary

conductor geometry. Propagation delay can be considered as a

fixed time offset and may be compensated.

Transducer Output

0

t

Propagation Time, t_PROP

Primary Current

I (%)

90

Response time (t_RESPONSE). The time interval between

a) when the primary current signal reaches 90% of its final

value, and b) when the sensor reaches 90% of its output

corresponding to the applied current.

Transducer Output

0

Response Time, t

RESPONSE

Primary Current

I (%)

90

Rise time (t_r). The time interval between a) when the sensor

reaches 10% of its full scale value, and b) when it reaches 90%

of its full scale value. The rise time to a step response is used to

derive the bandwidth of the current sensor, in which ƒ(–3 dB) =

0.35/t_r. Both t_rand t_RESPONSEare detrimentally affected by eddy

current losses observed in the conductive IC ground plane.

Transducer Output

10

0

Rise Time, t

r

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Package LA, 16-pin SOICW

10.30 ±0.20

8°

0°

1.27

0.65

16

2.25

0.33

0.20

7.50 ±0.10 10.30 ±0.33

9.50

A

1.40 REF

1

2

1.27

0.40

1

2

Branded Face

0.25 BSC

PCB Layout Reference View

C

SEATING PLANE

GAUGE PLANE

16X

C

SEATING

PLANE

0.10

C

1.27 BSC

2.65 MAX

0.51

0.31

0.30

0.10

NNNNNNNNNNN

TTT-TTT

LLLLLLLLL

For Reference Only; not for tooling use (reference MS-013AA)

Dimensions in millimeters

1

Dimensions exclusive of mold flash, gate burrs, and dambar protrusions

Exact case and lead configuration at supplier discretion within limits shown

Standard Branding Reference View

B

Terminal #1 mark area

A

B

Branding scale and appearance at supplier discretion

N = Device part number

T = Temperature range, package - amperage

L = Lot number

C

Reference land pattern layout (reference IPC7351

SOIC127P600X175-8M); all pads a minimum of 0.20 mm from all

adjacent pads; adjust as necessary to meet application process

requirements and PCB layout tolerances

Allegro MicroSystems, LLC

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120 kHz Bandwidth, High Voltage Isolation

Current Sensor with Integrated Overcurrent Detection

ACS710

Revision History

Revision

Revision Date

Description of Revision

Add non-latching variants, update isolation

specifications

Rev. 8

January 15, 2013

The products described herein are protected by U.S. patents: 7,166,807; 7,425,821; 7,573,393; and 7,598,601.

Allegro MicroSystems, LLC reserves the right to make, from time to time, such departures from the detail specifications as may be required to

permit improvements in the performance, reliability, or manufacturability of its products. Before placing an order, the user is cautioned to verify that

the information being relied upon is current.

Allegro’s products are not to be used in life support devices or systems, if a failure of an Allegro product can reasonably be expected to cause the

failure of that life support device or system, or to affect the safety or effectiveness of that device or system.

The information included herein is believed to be accurate and reliable. However, Allegro MicroSystems, LLC assumes no responsibility for its

use; nor for any infringement of patents or other rights of third parties which may result from its use.

For the latest version of this document, visit our website:

www.allegromicro.com

Allegro MicroSystems, LLC

115 Northeast Cutoff

22

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com


型号：	ACS710
厂家：	ALLEGRO MICROSYSTEMS
描述：	120 kHz Bandwidth, High Voltage Isolation Current Sensor with Integrated Overcurrent Detection 120 kHz带宽，高电压隔离电流传感器，集成了过流检测传感器
文件：	总22页 (文件大小：459K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

ACS710 [ALLEGRO]

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