Not to scale
The ACS70331 is Allegro’s first integrated, high sensitivity,
current sensor IC for <5 A current sensing applications. It
incorporates giant magneto-resistive (GMR) technology that
is 25 times more sensitive than traditional Hall-effect sensors
to sense the magnetic field generated by the current flowing
through the low resistance, integrated primary conductor.
The analog output provides a low noise high-speed signal,
which is proportional to the current flowing through the
primary. The response time of the part is typically 535 ns. The
ACS70331 is offered in four factory-programmed sensitivity
and offset levels to optimize performance over the desired
current measurement range.
The differential configuration of the GMR elements, relative to
the integrated current conductor, provides significant rejection
of stray magnetic fields, resulting in stable operation even in
magnetically noisy environments.
The ACS70331 operates from a single 3.3 V power supply
and is qualified over the full commercial temperature range
of –40°C to 85°C. It is offered in a low-profile, space-saving
surface mount QFN-12 and SOIC-8 packages.
ACS70331-DS, Rev. 3
MCO-0000343
• High sensitivity current sensor IC for sensing
up to 5 A (DC or AC)
• 1 MHz bandwidth with response time <550 ns
• Low noise: 8 mA(rms) at 1 MHz
• Non-ratiometric, analog output proportional to AC and
DC current
• Single 3.3 V supply operation
• High DC PSRR enables use with low accuracy
power supplies or batteries (3 to 4.5 V operation)
• 1.1 mΩ primary conductor resistance results in
low power loss
• Small surface mount QFN-12 and SOIC-8 packages for
space-constrained applications
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
TYPICAL APPLICATION
CBYPASS
0.1 µF
ACS70331
CLOAD
1
2
3
4
10
9
8
5
IP+
IP+
IP–
IP–
VCC
VIOUT
GND
12
6
7
11
NC
NC
NC
NC
NC
IP
ACS70331
VCC
VIOUT
NC
GNDIP -
IP -
IP+
IP+
1
2
3
4
8
7
6
5
CBYPAS
S
0.1 µF
IP
SOIC-8QFN-12
The output, VIOUT, of the ACS70331 responds
proportionally to the current owing through IP.
FEATURES AND BENEFITS DESCRIPTION
PACKAGES
12-contact QFN
3 mm × 3 mm × 0.75 mm
(ES package)
ACS70331
May 17, 2019
8-contact SOIC
(OL package)
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
2
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
SELECTION GUIDE
Part Number Current Sensing
Range, IPR (A)
Sens (Typ)
(mV/A)
TA
(°C) Package Packing [1]
ACS70331EESATR-2P5U3 0 to 2.5 800
–40 to 85
12-contact
QFN with fused
current loop
1500 pieces per reel
ACS70331EESATR-2P5B3 ±2.5 400
ACS70331EESATR-005U3 0 to 5 400
ACS70331EESATR-005B3 ±5 200
ACS70331EOLCTR-2P5U3 0 to 2.5 800
–40 to 85 8-lead SOIC 3000 pieces per reel
ACS70331EOLCTR-2P5B3 ±2.5 400
ACS70331EOLCTR-005U3 0 to 5 400
ACS70331EOLCTR-005B3 ±5 200
[1] Contact Allegro for additional packing options.
ABSOLUTE MAXIMUM RATINGS
Characteristic Symbol Notes Rating Units
Supply Voltage VCC 7 V
Reverse Supply Voltage VRCC –0.1 V
Output Voltage VIOUT 6 V
Reverse Output Voltage VRIOUT –0.1 V
Working Voltage VWORKING
Voltage applied between pins 1 to 4 and pins 5 to 12 (QFN)
or pins 1 to 4 and pins 5 to 8 (SOIC) 100 V
Maximum Continuous Current [2] IP(max) ±10 A
Maximum Continuous External Field [3] B ±50 G
Nominal Operating Ambient Temperature TARange E –40 to 85 °C
Maximum Junction Temperature [2] TJ(max) 100 °C
Storage Temperature Tstg –65 to 125 °C
[2] Continuous currents above this may result in changes in performance. See lifetime drift section for sensor drift under dierent temperature and current conditions. Also,
see Thermal Performance and Overcurrent Capability section for allowable constant and transient currents.
[3] Continuous magnetic elds above this may result in changes in performance.
[4] The ACS70331 should be soldered using Allegro’s recommended soldering prole in (http://www.allegromicro.com/en/Design-Center/Technical-Documents/Semicon-
ductor-Packaging-Publications/Soldering-Methods-for-Allegro-Products.aspx). Standard soldering tips will over-stress the device, resulting in shifts in performance. For
rework, it is recommended to use hot plates and heat guns/pencils, keeping the temperature of the device below the Maximum Soldering Temperature.
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
3
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
Terminal List Table
Number Name Description
1, 2 IP+ Terminals for current being sensed; fused internally
3, 4 IP– Terminals for current being sensed; fused internally
5 GND Device ground terminal
6, 8, 9, 11 NC No connection, ground for the best ESD performance
7 NC This pin should be left unconnected during normal operation
10 VIOUT Analog output representing the current flowing through IP
12 VCC Device power supply terminal
Package ES, 12-Pin QFN
Pinout Diagram
PINOUT DIAGRAM AND TERMINAL LIST TABLE
10
9
8
7
1
2
3
4
5
6
12
11
VCC
NC
GND
NC
VIOUT
NC
NC
NC
IP+
IP+
IP–
IP–
Terminal List Table
Number Name Description
1, 2 IP+ Terminals for current being sensed; fused internally
3, 4 IP– Terminals for current being sensed; fused internally
5 GND Device fround terminal
6 NC This pin should be left unconnected during normal operation
7 VIOUT Analog output representing the current flowing through IP
8 VCC Device power supply terminal
Package OL, 8-Pin SOIC
Pinout Diagram
8
7
6
5
1
2
3
4
VCC
VIOUT
NC
GND
IP+
IP+
IP–
IP–
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
4
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
VCC
IP+
IP+
IP–
IP–
VIOUT
GND
Voltage
Regulator Coarse
Gain Trim
Offset
Trim & TC
Sensitivity TC
& Fine Trim
FUNCTIONAL BLOCK DIAGRAM
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
5
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
Characteristic Symbol Test Conditions Min. Typ. Max. Unit
ELECTRICAL CHARACTERISTICS
Supply Voltage VCC 3.0 3.3 4.5 V
Supply Current
ICC
VCC(min) ≤ VCC ≤ VCC(max), no load on
VIOUT, fuses powered down – 4.5 6 mA
ICC_START_UP
VCC(min) ≤ VCC ≤ VCC(max), no load on
VIOUT, fuses powered (from time when
VCC rises above VCC(min) to tFPD)
– – 7.5 mA
Primary Conductor Resistance RIP
QFN-12 package, TA = 25°C – 1.1 – mΩ
SOIC-8 package, TA = 25°C – 1.7 – mΩ
Primary Conductor Inductance LIP
QFN-12 package – 1.7 – nH
SOIC-8 package – 4 – nH
Power On Time tPO TA = 25°C – 5 – µs
Fuse Power Down Time [2] tFPD TA = 25°C – 80 120 [3] µs
OUTPUT CHARACTERISTICS
Output Resistive Load RLVIOUT to GND or VIOUT to VCC 22 – – kΩ
Output Capacitive Load CL
VIOUT to GND, output is stable, slew
rate and bandwidth are reduced – – 100 pF
VIOUT to GND, maintains BW – – 50 pF
Source Current ISOURCE TA = 25°C – 0.4 – mA
Sink Current ISINK TA = 25°C – 0.5 – mA
Saturation Voltage [4]
VSAT_HIGH
VCC(min) < VCC < VCC(max);
RL = 22 kΩ to GND 2.8 VCC – 0.15 – V
VSAT_LOW
VCC(min) < VCC < VCC(max);
RL = 22 kΩ to VIOUT – 20 200 mV
Bandwidth BW –3 dB bandwidth – 1 – MHz
Response Time tRESPONSE 1 V swing on VIOUT, 80% to 80% – 535 – ns
Rise Time tr1 V swing on VIOUT, 10% to 90% – 460 – ns
Propagation Delay tpd 1 V swing on VIOUT, 20% to 20% – 220 – ns
Noise Density IND Input referred noise density – 8 – µARMS/
√(Hz)
Noise IN
Input reference noise; TA = 25°C,
Bandwidth = 1 MHz –8 – mARMS
Hysteresis IH
TA = 25°C; change in the output at zero
current after a ±10 A pulse of current
through the sensor
– 10 20 mA
TA = 25°C; change in the output at zero
current after a ±100 A pulse (~20 ms in
duration) of current through the sensor
– 20 – mA
COMMON ELECTRICAL CHARACTERISTICS [1]: Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Continued on next page...
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
6
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
COMMON ELECTRICAL CHARACTERISTICS [1] (continued): Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Characteristic Symbol Test Conditions Min. Typ. Max. Unit
Stray Field Sensitivity Error Ratio [5] STERSENS
Measured at 20 G, worst case field
orientation – 0.2 – %/G
Stray Field Offset Error Ratio [5] STEROFF
Measured at 20 G, worst case field
orientation – 3.8 – mA/G
Power Supply Rejection Ratio PSRR
DC to 100 Hz, 100 mV pk-pk on VCC – 40 – dB
100 Hz to 100 kHz, 100 mV pk-pk on
VCC – 30 – dB
Power Supply Offset Error VOE(PS)
Change in offset voltage over
3.0 V < VCC < 4.5 V – ±10 – mV
Power Supply Sensitivity Error ESENS(PS)
Change in sensitivity over
3.0 V < VCC < 4.5 V – ±0.5 – %
Nonlinearity ELIN – ±0.2 – %
[1] Device may be operated at higher ambient, TA, and internal leadframe temperatures, TA, provided that the Maximum Junction Temperature, TJ(max), is not exceeded.
[2] The internal fuses (non-volatile memory used for factory programming) will be powered for tFPD after VCC goes above VCC(min). After this time, the fuse states will have
been saved to volatile memory, and the fuses will be powered down to save power. This means that for tFPD after powering the device, ICC will be around 1 mA higher
than specied (ICC).
[3] This limit is based on simulation and is not tested in production.
[4] See Ideal Output Transfer Curve section.
[5] See Current Sensing Method using GMR and Stray Field Immunity section.
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
7
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
ACS70331EESA-2P5U3 PERFORMANCE CHARACTERISTICS: Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Characteristic Symbol Test Conditions Min. Typ. [1] Max. Unit
NOMINAL PERFORMANCE [2]
Current Sensing Range IPR 0 – 2.5 A
Sensitivity Sens IPR(min) < IP < IPR(max) – 800 – mV/A
Zero Current Output Voltage VIOUT(Q) IP = 0 mA, TA = 25°C – 0.25 – V
ACCURACY PERFORMANCE
Total Output Error
[3] ETOT
Measured at IP = IPR(max), TA = 25°C – ±2 – %
Measured at IP = IPR(max), TA = –40°C to 85°C – ±5 – %
TOTAL OUTPUT ERROR COMPONENTS [4] ETOT = ESENS + 100 × VOE/(Sens × IP)
Sensitivity Error Esens
Measured at IP = IPR(max), TA = 25°C – ±1.5 – %
Measured at IP = IPR(max), TA = –40°C to 85°C – ±3 – %
Offset Voltage VOE
IP = 0 A, TA = 25°C – ±15 – mV
IP = 0 A, TA = –40°C to 85°C – ±55 – mV
[1] Typical values with +/- are 3 sigma values.
[2] See Ideal Output Transfer Curve section.
[3] Percentage of IP
, with IP = IPR(max).
[4] See Lifetime Drift section for accuracy drift under dierent application temperatures, currents, and elds.
ACS70331EESA-2P5B3 PERFORMANCE CHARACTERISTICS: Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Characteristic Symbol Test Conditions Min. Typ. [1] Max. Unit
NOMINAL PERFORMANCE [2]
Current Sensing Range IPR –2.5 – 2.5 A
Sensitivity Sens IPR(min) < IP < IPR(max) – 400 – mV/A
Zero Current Output Voltage VIOUT(Q) IP = 0 mA, TA = 25°C – 1.5 – V
ACCURACY PERFORMANCE
Total Output Error
[3] ETOT
Measured at IP = IPR(max), TA = 25°C – ±2 – %
Measured at IP = IPR(max), TA = –40°C to 85°C – ±3 – %
TOTAL OUTPUT ERROR COMPONENTS [4] ETOT = ESENS + 100 × VOE/(Sens × IP)
Sensitivity Error Esens
Measured at IP = IPR(max), TA = 25°C – ±1.5 – %
Measured at IP = IPR(max), TA = –40°C to 85°C – ±3 – %
Offset Voltage VOE
IP = 0 A, TA = 25°C – ±10 – mV
IP = 0 A, TA = –40°C to 85°C – ±40 – mV
[1] Typical values with +/- are 3 sigma values.
[2] See Ideal Output Transfer Curve section.
[3] Percentage of IP
, with IP = IPR(max).
[4] See Lifetime Drift section for accuracy drift under dierent application temperatures, currents, and elds.
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
8
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
ACS70331EESA-005U3 PERFORMANCE CHARACTERISTICS: Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Characteristic Symbol Test Conditions Min. Typ. [1] Max. Unit
NOMINAL PERFORMANCE [2]
Current Sensing Range IPR 0 – 5 A
Sensitivity Sens IPR(min) < IP < IPR(max) – 400 – mV/A
Zero Current Output Voltage VIOUT(Q) IP = 0 mA, TA = 25°C – 0.25 – V
ACCURACY PERFORMANCE
Total Output Error
[3] ETOT
Measured at IP = IPR(max), TA = 25°C – ±2 – %
Measured at IP = IPR(max), TA = –40°C to 85°C – ±3 – %
TOTAL OUTPUT ERROR COMPONENTS [4] ETOT = ESENS + 100 × VOE/(Sens × IP)
Sensitivity Error Esens
Measured at IP = IPR(max), TA = 25°C – ±1.5 – %
Measured at IP = IPR(max), TA = –40°C to 85°C – ±3 – %
Offset Voltage VOE
IP = 0 A, TA = 25°C – ±10 – mV
IP = 0 A, TA = –40°C to 85°C – ±45 – mV
[1] Typical values with +/- are 3 sigma values.
[2] See Ideal Output Transfer Curve section.
[3] Percentage of IP
, with IP = IPR(max).
[4] See Lifetime Drift section for accuracy drift under dierent application temperatures, currents, and elds.
ACS70331EESA-005B3 PERFORMANCE CHARACTERISTICS: Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Characteristic Symbol Test Conditions Min. Typ. [1] Max. Unit
NOMINAL PERFORMANCE [2]
Current Sensing Range IPR –5 – 5 A
Sensitivity Sens IPR(min) < IP < IPR(max) – 200 – mV/A
Zero Current Output Voltage VIOUT(Q) IP = 0 mA, TA = 25°C – 1.5 – V
ACCURACY PERFORMANCE
Total Output Error
[3] ETOT
Measured at IP = IPR(max), TA = 25°C – ±2 – %
Measured at IP = IPR(max), TA = –40°C to 85°C – ±3 – %
TOTAL OUTPUT ERROR COMPONENTS [4] ETOT = ESENS + 100 × VOE/(Sens × IP)
Sensitivity Error Esens
Measured at IP = IPR(max), TA = 25°C – ±1.5 – %
Measured at IP = IPR(max), TA = –40°C to 85°C – ±2.5 – %
Offset Voltage VOE
IP = 0 A, TA = 25°C – ±8 – mV
IP = 0 A, TA = –40°C to 85°C – ±45 – mV
[1] Typical values with +/- are 3 sigma values.
[2] See Ideal Output Transfer Curve section.
[3] Percentage of IP
, with IP = IPR(max).
[4] See Lifetime Drift section for accuracy drift under dierent application temperatures, currents, and elds.
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
9
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
ACS70331EOLC-2P5U3 PERFORMANCE CHARACTERISTICS: Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Characteristic Symbol Test Conditions Min. Typ. [1] Max. Unit
NOMINAL PERFORMANCE [2]
Current Sensing Range IPR 0 – 2.5 A
Sensitivity Sens IPR(min) < IP < IPR(max) – 800 – mV/A
Zero Current Output Voltage VIOUT(Q) IP = 0 mA, TA = 25°C – 0.25 – V
ACCURACY PERFORMANCE
Total Output Error
[3] ETOT
Measured at IP = IPR(max), TA = 25°C – ±2 – %
Measured at IP = IPR(max), TA = 25°C to 85°C – ±4 – %
Measured at IP = IPR(max), TA = –40°C to 25°C – ±6.5 – %
TOTAL OUTPUT ERROR COMPONENTS [4] ETOT = ESENS + 100 × VOE/(Sens × IP)
Sensitivity Error Esens
Measured at IP = IPR(max), TA = 25°C – ±1.2 – %
Measured at IP = IPR(max), TA = 25°C to 85°C – ±4 – %
Measured at IP = IPR(max), TA = –40°C to 25°C – ±3 – %
Offset Voltage VOE
IP = 0 A, TA = 25°C – ±37 – mV
IP = 0 A, TA = 25°C to 85°C – ±44 – mV
IP = 0 A, TA = –40°C to 25°C – ±100 – mV
[1] Typical values with +/- are 3 sigma values.
[2] See Ideal Output Transfer Curve section.
[3] Percentage of IP
, with IP = IPR(max).
[4] See Lifetime Drift section for accuracy drift under dierent application temperatures, currents, and elds.
ACS70331EOLC-2P5B3 PERFORMANCE CHARACTERISTICS: Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Characteristic Symbol Test Conditions Min. Typ. [1] Max. Unit
NOMINAL PERFORMANCE [2]
Current Sensing Range IPR –2.5 – 2.5 A
Sensitivity Sens IPR(min) < IP < IPR(max) – 400 – mV/A
Zero Current Output Voltage VIOUT(Q) IP = 0 mA, TA = 25°C – 1.5 – V
ACCURACY PERFORMANCE
Total Output Error
[3] ETOT
Measured at IP = IPR(max), TA = 25°C – ±3 – %
Measured at IP = IPR(max), TA = 25°C to 85°C – ±4.5 – %
Measured at IP = IPR(max), TA = –40°C to 25°C – ±9 – %
TOTAL OUTPUT ERROR COMPONENTS [4] ETOT = ESENS + 100 × VOE/(Sens × IP)
Sensitivity Error Esens
Measured at IP = IPR(max), TA = 25°C – ±1.1 – %
Measured at IP = IPR(max), TA = 25°C to 85°C – ±3 – %
Measured at IP = IPR(max), TA = –40°C to 25°C – ±5.5 – %
Offset Voltage VOE
IP = 0 A, TA = 25°C – ±30 – mV
IP = 0 A, TA = 25°C to 85°C – ±40 – mV
IP = 0 A, TA = –40°C to 25°C – ±70 – mV
[1] Typical values with +/- are 3 sigma values.
[2] See Ideal Output Transfer Curve section.
[3] Percentage of IP
, with IP = IPR(max).
[4] See Lifetime Drift section for accuracy drift under dierent application temperatures, currents, and elds.
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
10
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
ACS70331EOLC-005U3 PERFORMANCE CHARACTERISTICS: Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Characteristic Symbol Test Conditions Min. Typ. [1] Max. Unit
NOMINAL PERFORMANCE [2]
Current Sensing Range IPR 0 – 5 A
Sensitivity Sens IPR(min) < IP < IPR(max) – 400 – mV/A
Zero Current Output Voltage VIOUT(Q) IP = 0 mA, TA = 25°C – 0.25 – V
ACCURACY PERFORMANCE
Total Output Error
[3] ETOT
Measured at IP = IPR(max), TA = 25°C – ±2.2 – %
Measured at IP = IPR(max), TA = 25°C to 85°C – ±3.5 – %
Measured at IP = IPR(max), TA = –40°C to 25°C – ±6.5 – %
TOTAL OUTPUT ERROR COMPONENTS [4] ETOT = ESENS + 100 × VOE/(Sens × IP)
Sensitivity Error Esens
Measured at IP = IPR(max), TA = 25°C – ±1.5 – %
Measured at IP = IPR(max), TA = 25°C to 85°C – ±3 – %
Measured at IP = IPR(max), TA = –40°C to 25°C – ±5 – %
Offset Voltage VOE
IP = 0 A, TA = 25°C – ±40 – mV
IP = 0 A, TA = 25°C to 85°C – ±45 – mV
IP = 0 A, TA = –40°C to 25°C – ±100 – mV
[1] Typical values with +/- are 3 sigma values.
[2] See Ideal Output Transfer Curve section.
[3] Percentage of IP
, with IP = IPR(max).
[4] See Lifetime Drift section for accuracy drift under dierent application temperatures, currents, and elds.
ACS70331EOLC-005B3 PERFORMANCE CHARACTERISTICS: Valid over full range of TA, and VCC = 3.3 V, unless otherwise specied
Characteristic Symbol Test Conditions Min. Typ. [1] Max. Unit
NOMINAL PERFORMANCE [2]
Current Sensing Range IPR –5 – 5 A
Sensitivity Sens IPR(min) < IP < IPR(max) – 200 – mV/A
Zero Current Output Voltage VIOUT(Q) IP = 0 mA, TA = 25°C – 1.5 – V
ACCURACY PERFORMANCE
Total Output Error
[3] ETOT
Measured at IP = IPR(max), TA = 25°C – ±3 – %
Measured at IP = IPR(max), TA = 25°C to 85°C – ±3 – %
Measured at IP = IPR(max), TA = –40°C to 25°C – ±6.5 – %
TOTAL OUTPUT ERROR COMPONENTS [4] ETOT = ESENS + 100 × VOE/(Sens × IP)
Sensitivity Error Esens
Measured at IP = IPR(max), TA = 25°C – ±1.3 – %
Measured at IP = IPR(max), TA = 25°C to 85°C – ±2.3 – %
Measured at IP = IPR(max), TA = –40°C to 25°C – ±5.5 – %
Offset Voltage VOE
IP = 0 A, TA = 25°C – ±23 – mV
IP = 0 A, TA = 25°C to 85°C – ±23 – mV
IP = 0 A, TA = –40°C to 25°C – ±50 – mV
[1] Typical values with +/- are 3 sigma values.
[2] See Ideal Output Transfer Curve section.
[3] Percentage of IP
, with IP = IPR(max).
[4] See Lifetime Drift section for accuracy drift under dierent application temperatures, currents, and elds.
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
11
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
THEORY OF OPERATION
GMR Sensing Elements
The ACS70331 uses GMR (giant magneto-resistive) elements
to indirectly measure the current flowing through the package
by measuring the field produced by the current. These elements
operate differently than the Hall-effect sensors used in the major-
ity of Allegro’s current sensors. The main advantage of GMR is
that it is much more sensitive than the Hall-effect, making it ideal
for measuring small currents. This is what enables the ACS70331
to have over 25 times lower input-referred noise than Allegro’s
lowest noise Hall-effect based current sensors. GMR elements are
essentially resistors which change resistance with applied field. A
typical representative response curve for the GMR elements used
in the ACS70331 is shown in Figure 1. It is important to note that
the applied field is parallel to the surface of the sensor instead of
perpendicular to the sensor plane as with planar Hall sensors.
GMR
B
1040
1030
1020
1010
1000
990
980
970
960
-500 -400 -300 -200 -100 0 100 200 300 400 500
Field Applied (G)
R (Ω)
The equation describing this curve is:
() .sin tanRB B
1000 1004 100
1
=- -
b
bl
l
;E
This GMR element has a base resistance of around 1000 Ω that
increases and decreases with field. It is important to note that a
big difference between GMR and the Hall-effect is that GMR
sensors saturate at relatively low fields, limiting the linear operat-
ing region. The linear region of the GMR elements used in the
ACS70331 is around ±50 G.
Figure 1: Typical Response Curve for GMR Elements
High Sensitivity, 1 MHz, GMR-Based Current Sensor IC
in Space-Saving, Low Resistance QFN and SOIC-8 Packages
ACS70331
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Allegro MicroSystems
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Current Sensing Method using GMR and
Stray Field Immunity
The internal construction of the ACS70331 QFN package is
shown in Figure 2, and the internal construction of the SOIC-8
package is similar. The die sits above the primary current path
such that magnetic field is produced in plane with the GMR ele-
ments on the die. GMR elements 1 and 2 sense field in the +X
direction for positive IP current flow, and GMR elements 3 and 4
sense field in the –X direction for positive IP current flow. This
enables differential measurement of the current and rejection of
external stray fields.
The four GMR elements are arranged in a Wheatstone bridge
configuration as shown in Figure 3 such that the output of the
bridge is proportional to the differential field sensed by the four
elements, rejecting common fields.
Figure 2: ACS70331 Internal Construction
Figure 3: Wheatstone Bridge Conguration
VCC
IP+
IP+
IP–
IP–
VIOUT
GND
Voltage
Regulator Coarse
Gain Trim
Offset
Trim & TC
Sensitivity TC
& Fine Trim
VREG
GMR3
GMR2
GMR4
GMR1
VBRIDGE
+
–
The output of the bridge will be:
VBRIDGE ∝ VREG × IP × Cf
Here, Cf is the coupling factor from the primary current path to
the GMR elements, which is around 4 G/A.
Theoretically, the bridge configuration will perfectly cancel out all
external common-mode fields that could interfere with the sensor;
however, the performance is limited by non-idealities, such as mis-
match. Typical stray field rejection performance is given in Table
1 for stray fields of 20 G, which is much higher than what will be
seen in most applications. Stray fields in the X direction result in
minimal sensitivity error but some offset error. Stray fields in the
Y direction result in more sensitivity error and less offset error.
Finally, stray fields in the Z direction result in essentially no error,
as the GMR are not sensitive to fields in this dimension.
Table 1: Typical Stray Field Rejection Performance
Field Level (G) Field
Orientation
Typical Sensitivity
Error (%)
Typical Offset
Error (mA)
20 ±X ±4.2 ±76
20 ±Y ±3 15
20 ±Z 0 0
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Gain and Offset Trim
The bridge configuration of the GMR elements in the ACS70331
make the gain and offset trim for the sensor relatively simple. As
the bridge output voltage is proportional to the voltage driving it,
that voltage is trimmed to compensate for all other nominal gain
errors, as well as errors over temperature. Then, offset is trimmed
out after the bridge voltage has been amplified. All trim codes are
stored using fuses that are programmed at final test before lock-
ing the part.
Ideal Output Transfer Curve
The ideal output of the ACS70331 is:
VIOUT = Sens × IP + VIOUT(Q)
Different versions of the ACS70331 have different sensitivity
(Sens) and zero current output voltage (VIOUT(Q)) values in order
to give different current measurement ranges. Unidirectional
sensors start at 0.25 V with zero current through the primary and
swing +2 V for full-scale current. Bidirectional sensors start at
1.5 V with zero current through the primary and swing ±1 V for
full-scale current. Figure 4 shows the ideal output transfer curves
for each version of the ACS70331. The output curves show the
typical saturation levels; however, the saturation could occur
anywhere beyond the min/max saturation limits shown by the
dashed lines. The stated accuracy of the sensor is only valid over
the given current sensing range (IPR).
3
2.5
2
1.5
1
0.5
0-6 -4 -2 0 2 4 6
IP (A)
VIOUT (V)
2.5 Unidirectional
2.5 Bidirectional
5 Unidirectional
5 Bidirectional
Vsat-high
Vsat-low
Figure 4: Ideal Output Tranfer Curves
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Power-On Behavior
The power-on behavior of the ACS70331 is shown in Figure 5.
Once VCC goes above VCC(min), it takes tPO for the internal cir-
cuitry to fully power on and bring the output to the correct value.
After tFPD, the ACS70331 has saved the fuse values containing
configuration and trim information to volatile registers and pow-
ered down the fuses to save power. During tFPD, the ACS70331
uses the direct outputs from the fuses, meaning there is no change
in configuration or trim when the fuses are powered down.
VCC
ICC
VIOUT
ICC(typ)
ICC_START_UP
tFPD
tPO
VCC(typ)
VCC(min)
90% VIOUT
Figure 5: Power-On Behavior
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Frequency and Step Response
The ACS70331 has a bandwidth of approximately 1 MHz.
However, there are a number of poles in the signal path of the
ACS70331, leading to 115 degrees of phase shift at the –3 dB
frequency. The measured frequency response with a 500 mA sine
wave input is shown below.
CHARACTERISTIC PERFORMANCE
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The typical step response is shown in the scope capture below.
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Isolation and Transient Voltage Performance
The ACS70331 uses a non-conductive die attach to isolate it from
the primary conductor. This does not provide any level of safety
isolation, as it only passes a hi-pot test of around 500 Vrms. It is
recommended to keep the voltage from the primary to the signal
leads below 100 V during operation.
The construction of the ACS70331 results in there being a
capacitance from the primary conductor to the substrate of the
die. When the voltage on the primary conductor changes rapidly,
this can lead to a perturbation on the output of the sensor. The
scope capture below shows the response of the ACS70331 to a
fast transient voltage on the primary conductor. While the sensor
does get disturbed significantly, it recovers within 0.5 µs due to
the high bandwidth of the sensor.
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Power Supply Rejection Ratio
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THERMAL PERFORMANCE AND OVERCURRENT CAPABILITY
The ACS70331 has a small primary conductor resistance of
1.1 mΩ (ES) and 1.7 mΩ (OL), resulting in low power dissipa-
tion and consequently low temperature rise due to current flow
through the sensor. Figure 6 shows the steady-state die temperature
rise versus current of the ACS70331 on the Allegro demo board
(ASEK70331), which has two layers of 1-oz. copper. At 5 A, the
die temperature only rises around 4°C. At 10 A, the die temperature
increases by around 16°C, meaning that at the maximum ambient
temperature of 85°C with the maximum rated continuous current of
10 A flowing, the die would be around its maximum rated junction
temperature of 100°C.
The ACS70331 can also survive higher levels of current that only
last for a short time. Figure 7 shows a curve of the time to fuse
(primary loop fuses open) versus current, which one needs to
operate below.
Figure 6: Change in die temperature versus current
of the ACS70331 on the ASEK70331 demo board (1-
oz. copper) with 22 gauge connectors to the power
supply
Figure 7: Time to fuse versus current of the
ACS70331 on the ASEK70331 demo board (1-oz. cop-
per) and 22 gauge connectors to the power supply
0
2
4
6
8
10
12
14
16
18
20
012345678910 11
Change in Die Temperature (°C)
Current (A)
QFN (ES)
SOIC-8 (OL)
10
100
1000
10000
40 60 80 100 120 140 160 180 200
Time To Fuse (ms)
Current (A)
QFN (ES)
SOIC-8 (OL)
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GMR elements are made up of thin layers of magnetic material,
and as such, high temperature and magnetic fields can cause
small shifts in the magnetization of those layers, resulting in drift
in the sensor performance. The GMR elements in the ACS70331
are made up of magnetic materials which are relatively immune
to the temperatures and fields seen in most commercial applica-
tions. However, extended times near the maximum rated junction
temperature with applied current or field can cause the gain and
offset of the sensor to shift. These shifts are dependent on the
application temperature, current, and stray field, and typical drift
under various application cases are given in the table below, as
well as a description of the physics behind each drift.
LIFETIME DRIFT
Test Condition Typical Drift (Average + 3 sigma)
Junction
Temperature Current Common Mode
Field Offset Sensitivity
125°C
(408 hours) 0 A 0 G ±140 mA ±0.9%
100°C
(408 hours) 1 A (DC) 0 G ±170 mA ±2.3%
100°C
(408 hours) 2.5 A (DC) 0 G ±210 mA ±1.5%
100°C
(500 hours) 5 A (DC) 0 G ±540 mA ±2.8%
100°C
(408 hours) 5 A (AC) 0 G ±150 mA ±1%
125°C
(48 hours) 0 A 50 G ±150 mA ±1%
C1 Qualification Highest Drift Stress
(Temperature Cycling –40°C to 150°C,
500 cycles)
0 A 0 G ±90 mA ±5%
CASE 1: CONTINUOUS CURRENT AT HIGH
TEMPERATURE
In general, this is the worst case configuration for drift. High
temperature and constant field will slightly rotate some of the
GMR layers. Here, the field seen by two of the GMR elements in
the bridge is in one direction, and the field seen by the other two
GMR elements in the bridge is in the other direction. This results
in two of the elements drifting in one direction and two of them
drifting in the other direction, which causes an offset shift on the
output of the sensor. Typically, at a given temperature and current
there is a maximum amount of shift, and the time constant for
the shift is around 24 hours. If one reverses the current, the shift
will be in the opposite direction. Essentially, at a given tempera-
ture and current level, there is a hysteresis curve for the shift.
The higher the temperature and current, the wider the hysteresis
curve.
CASE 2: AC CURRENT AT HIGH TEMPERATURE
As noted in Case 1, the time constant for the offset shift in
the sensor is around 24 hours, and the shift direction switches
with the current direction. Because of this, AC current tends to
cause little to no shift in the sensor, as the average torque on the
magnetic layers is zero. This is evident in the plot below, which
shows the drift when applying high DC and AC currents at
100°C.
CASE 3: STRAY FIELD AT HIGH TEMPERATURE
When stray field is applied to the sensor at high temperature, all
four resistors in the bridge shift in the same direction, theoreti-
cally cancelling any drift on the output. However, due to mis-
match in the elements, there is still some drift, but it is signifi-
cantly less than what is seen in Case 1 or even Case 2.
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Hysteresis (IH). The change in the sensor IC zero current output
voltage after being subjected to a large current for a short dura-
tion. Hysteresis is due to slight magnetization of some of the
ferromagnetic layers in GMR. Pulses of current in opposite direc-
tions will result in hysteresis in opposite directions. The GMR
stack in the ACS70331 is optimized to have low hysteresis in
comparison with more traditional stacks.
Common Mode Field Sensitivity Error Ratio (CMFRSENS).
The ratio of the shift in sensitivity due to an external stray field
on the sensor relative to the field strength (%/G). This is mea-
sured in the worst case stray field configuration.
Common Mode Field Offset Voltage Ratio (CMFROFF). The
ratio of the shift in the offset voltage due to stray field on the sen-
sor relative to the field strength (mV/G). This is measured in the
worst case stray field configuration.
Power Supply Rejection Ratio (PSRR). The ratio of the shift
in VIOUT due to supply voltage variation, expressed in dB. The
PSRR is a small signal parameter, measured with 100 mV pk-pk
over frequency. logPSRR
V
V
20
CC
IOUT
10
D
D
=
Power Supply Offset Error (VOE(PS)). The large signal PSRR,
expressed in absolute millivolts. The power supply offset error is
the variation of the offset voltage over the full supply range of the
ACS70331.
Power Supply Sensitivity Error (ESENS(PS)). The variation in
sensitivity over the full supply range of the ACS70331.
Nonlinearity (ELIN). The nonlinearity is a measure of how linear
the output of the sensor IC is over the full current measurement
range. The nonlinearity is calculated as:
E=
LIN
1–
V(I)–V
IOUT PR(max) IOUT(Q )
2×V(I)–V
IOUT PR(max/2) IOUT(Q )
×100(%)
where VIOUT(IPR(max)) is the output of the sensor IC with the
maximum measurement current flowing through it and
VIOUT(IPR(max/2)) is the output of the sensor IC with half of the
maximum measurement current flowing through it.
Sensitivity (Sens). The change in sensor IC output in response to
a 1 A change through the primary conductor. The sensitivity is the
product of the magnetic circuit sensitivity (G / A) (1 G = 0.1 mT)
and the linear IC amplifier gain (mV/G). The linear IC ampli-
fier gain is programmed at the factory to optimize the sensitivity
(mV/A) for the full-scale current of the device.
DEFINITIONS OF ACCURACY CHARACTERISTICS
Figure 8: Output Voltage versus Sensed Current
Figure 9: Total Output Error versus Sensed Current
0 A
Decreasing
V
IOUT
(V)
Accuracy Across
Temperature
Accuracy Across
Temperature
Accuracy Across
Temperature
Accuracy at
25°C Only
Accuracy at
25°C Only
Accuracy at
25°C Only
Increasing
V
IOUT
(V)
Ideal V
IOUT
I
PR
(min)
I
PR
(max)
+I
P
(A)
–I
P
(A)
V
IOUT(Q)
Full Scale I
P
+IP
–IP
+ETOT
–ETOT
Across Temperature
25°C Only
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Sensitivity Error (ESENS). The variation of the sensitivity from
its ideal, nominal value, Sens, expressed in percent. Sensitivity
error contributes directly to the Total Output Error, percent for
percent.
Zero-Current Output Voltage (VIOUT(Q)). The output of the
sensor when the primary current is zero. For a bidirectional
device (measures current in both directions), it is nominally 1.5 V,
and for a unidirectional device, it is nominally 0.25 V.
Offset Voltage (VOE). The deviation of the device output from its
ideal quiescent value of 1.5 V (bidirectional) or 0.25 V (unidirec-
tional). To convert this voltage to amperes, divide by the device
sensitivity, Sens.
Total Output Error (ETOT). The difference between the cur-
rent measurement from the sensor IC and the actual current (IP),
relative to the actual current. This is equivalent to the difference
between the ideal output voltage and the actual output voltage,
divided by the ideal sensitivity, relative to the current flowing
through the primary conduction path:
E(I)
TOTP
V(I)–V (I )
IOUT_ideal PIOUTP
Sens (I )×I
idealP P
× 100 (%)
=
The Total Output Error incorporates all sources of error and is a
function of IP . At relatively high currents, ETOT will be mostly
due to sensitivity error, and at relatively low currents, ETOT will
be mostly due to Offset Voltage (VOE
). In fact, at IP = 0, ETOT
approaches infinity due to the offset. This is illustrated in Figure
8 and Figure 9. Figure 8 shows a distribution of output voltages
versus IP at 25°C and across temperature. Figure 9 shows the cor-
responding ETOT versus IP .
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DEFINITIONS OF DYNAMIC RESPONSE CHARACTERISTICS
Power-On Time (tPO). When the supply is ramped to its operat-
ing voltage, the device requires a finite time to power its internal
components before responding to an input magnetic field.
Power-On Time, tPO , is defined as the time it takes for the output
voltage to settle within ±10% of its steady-state value under an
applied magnetic field, after the power supply has reached its
minimum specified operating voltage, VCC(min), as shown in the
chart at right.
Rise Time (tr). The time interval between a) when the sensor IC
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 IC, in which ƒ(–3 dB)
= 0.35 / tr. Both tr and tRESPONSE are detrimentally affected by
eddy-current losses observed in the conductive IC ground plane.
Response Time (tRESPONSE). The time interval between a) when
the primary current signal reaches 90% of its final value, and b)
when the device reaches 90% of its output corresponding to the
applied current.
Propagation Delay (tpd
). The propagation delay is measured
as the time interval a) when the primary current signal reaches
20% of its final value, and b) when the device reaches 20% of its
output corresponding to the applied current.
VIOUT
V
t
VCC
VCC(min.)
90% VIOUT
0
t1= time at which power supply reaches
minimum specified operating voltage
t2=
time at which output voltage settles
within ±10% of its steady state value
under an applied magnetic field
t1t2
tPO
V
CC
(typ.)
Primary Current
VIOUT
90
0
(%)
Response Time, tRESPONSE
t
Primary Current
VIOUT
90
10
20
0
(%)
Propagation Delay, tpd
Rise Time, tr
t
Figure 10: Power-On Time (tPO)
Figure 11: Rise Time (tr) and Propagation Delay (tpd)
Figure 12: Response Time (tRESPONSE)
Fuse Power Down Time (tFPD). The time interval between a)
when VCC goes above VCC(min) and b) when the sensor powers
down the internal fuses.
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Figure 13: Package ES, 12-Contact QFN
With Fused Sensed Current Loop
PACKAGE OUTLINE DRAWINGS
12
2
1
A
12
1
2
1.79
0.6024
0.8598
3.00 BSC
3.00 BSC
0.75 ±0.05
0.50 BSC
0.25
0.60
0.60 0.40 ±0.10
0.20 ×4
0.75
+0.07
-0.05
0.05 MAX
0.00 MIN
0.08 C
For Reference Only – Not for Tooling Use
(Reference DWG-0000222)
Dimensions in millimeters
NOT TO SCALE
Dimensions exclusive of moldflash, gate burrs, and dambar protrusions
Exact case and lead configuration at supplier discretion within limits shown
0.30
1.00
1
12
0.50
0.70
0.85
1.27
MIN
0.80
MIN
2.90
2.05 REF
2.70
C
DCoplanarity includes exposed current path and terminals
ATerminal #1 mark area
BFused sensed current path
CReference land pattern layout (reference IPC7351
QFN50P300X300X80-17W4M);
All pads a minimum of 0.20 mm from all adjacent pads; adjust as
necessary to meet application process requirements and PCB layout
tolerances; when mounting on a multilayer PCB, thermal vias at the
exposed thermal pad land can improve thermal dissipation (reference
EIA/JEDEC Standard JESD51-5)
PCB Layout Reference View
Branding scale and appearance at supplier discretion
E
EStandard Branding Reference View
Lines 1, 2, 3 = 4 characters
Line 1: Part Number
Line 2: 4 digit Date Code
Line 3: Characters 5, 6, 7, 8 of
Assembly Lot Number.
XXXX
Date Code
Lot Number
1
D
B
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Figure 14: Package OL, 8-Lead SOIC
A
B
D
C
Branding scale and appearance at supplier discretion
C
SEATING
PLANE
2
1
1
8
1.27 BSC
B
C
21
8
C
0.65 1.27
5.60
1.75
C0.10
8X 0.25 BSC
1.04 REF
1.75 MAX
4.90 ±0.10
3.90 ±0.10 6.00 ±0.20
0.51
0.31
0.25
0.10
0.25
0.17
1.27
0.40
8°
0°
A
Standard Branding Reference View
D
Branded Face
SEATING PLANE
GAUGE PLANE
PCB Layout Reference View
XXXXXXX
Date Code
Lot Number
Lines 1, 2 = 7 characters.
Line 3 = 5 characters.
Line 1: Part Number
Line 2: Logo A, 4 digit Date Code
Line 3: Characters 5, 6, 7, 8 of Lot Number
For Reference Only – Not for Tooling Use
(Reference DWG-9204)
Dimensions in millimeters
NOT TO SCALE
Dimensions exclusive of mold flash, gate burrs, and dambar protrusions
Exact case and lead configuration at supplier discretion within limits shown
Terminal #1 mark area
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
Active Area Depth 0.40 NOM
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For the latest version of this document, visit our website:
www.allegromicro.com
Revision History
Number Date Description
– September 12, 2017 Initial release
1 March 1, 2018 Added SOIC-8 package; updated Selection Guide (p. 2), Lifetime Drift table (p. 20) and package
drawings (p. 24-25)
2 May 23, 2018 Updated Features and Benefits (p. 1), step response plot (p. 16)
3 May 17, 2019 Removed footnote 4 from Performance Characteristics tables (p. 7-10)
Copyright 2019, Allegro MicroSystems.
Allegro MicroSystems 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 any devices or systems, including but not limited to life support devices or systems, in which a failure of
Allegro’s product can reasonably be expected to cause bodily harm.
The information included herein is believed to be accurate and reliable. However, Allegro MicroSystems assumes no responsibility for its use; nor
for any infringement of patents or other rights of third parties which may result from its use.
Copies of this document are considered uncontrolled documents.
