Melexis MLX91208 Imc-hall current sensor (triaxistechnology) Datasheet

MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
Features and Benefits
Application Examples
 Programmable high speed current sensor
 Triais® Technology
 Very high sensitivity due to Integrated
Magnetic Concentrator (IMC-Hall®)
 Wideband: DC to 200kHz
 Very short response time: 3µs
 Programmable linear transfer characteristic
 Selectable analog ratiometric output
 SO-8 package, RoHS compliant
 Lead free component, suitable for lead free
soldering profile 260°C (target), MSL3






Inverter HEV and EV
BLDC motor current monitoring
Smart fuse (over-current detection)
AC/DC Converter
DC/AC Converter (Inverter)
DC/DC switched mode power supply
Ordering Information
Part No.
MLX91208
MLX91208
MLX91208
MLX91208
Temperature Code
L (-40°C to 150°C)
L (-40°C to 150°C)
L (-40°C to 150°C)
L (-40°C to 150°C)
Package
DC (SOIC)
DC (SOIC)
DC (SOIC)
DC (SOIC)
Option code
CAL-000 (low field)
CAH-000 (high field)
CAV-000 (v. high f.)
CAV-001 (v. high f.)
Packing Form
TU/RE (tube/reel)
TU/RE (tube/reel)
TU/RE (tube/reel)
TU/RE (tube/reel)
Sensitivity Range (Default)
100-700mV/mT (250mV/mT)
50-300mV/mT (100mV/mT)
30-200mV/mT (40mV/mT)
30-200mV/mT (60mV/mT)
Ordering example: MLX91208LDC-CAH-000-RE
1 Functional Diagram
Figure 1: Block diagram
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Data Sheet
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MLX91208
®
IMC-Hall Current Sensor (Triaxis Technology)
2 General Description
The MLX91208 is a monolithic sensor IC featuring the Triais Hall technology. Conventional planar Hall
technology is only sensitive to the flux density applied orthogonally to the IC surface. The IMC-Hall current
sensor is sensitive to the flux density applied parallel to the IC surface. This is obtained through an Integrated
Magneto-Concentrator (IMC-Hall) which is deposited on the CMOS die (as an additional back-end step).
The IMC-Hall technology is automotive qualified.
The product is a single chip Hall sensor which provides an output signal proportional to the flux density
applied horizontally and is therefore suitable for current measurement. It is ideally suited as an open loop
current sensor for PCB or bus bar mounting. It features small size application design and a simple
construction for various current ranges from few Amperes up to 1000 Amperes.
The transfer characteristic of the MLX91208 is programmable in terms of offset, gain or temperature
compensation. The linear analog output is designed for applications where a very fast response is required,
such as inverter applications.
Figure 2: Typical application of MLX91208 (magnetic field generated by the current).
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Data Sheet
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®
MLX91208
®
IMC-Hall Current Sensor (Triaxis Technology)
Table of Contents
1 Functional Diagram ........................................................................................................................................................................1
2 General Description .......................................................................................................................................................................2
3 Glossary of Terms .........................................................................................................................................................................4
4 Absolute Maximum Ratings ............................................................................................................................................................4
5 Pin Definitions and Descriptions......................................................................................................................................................4
6 General Electrical Specifications .....................................................................................................................................................5
7 Magnetic specification ....................................................................................................................................................................6
7.1 Low Field Version 10mT (marking xxL).....................................................................................................................................6
7.2 High Field Version 25mT (marking xxH) ...................................................................................................................................6
7.3 Very High Field Version 60mT (marking xxV)............................................................................................................................6
8 Analog output specification .............................................................................................................................................................7
8.1 Timing specification ................................................................................................................................................................7
8.2 Accuracy specification.............................................................................................................................................................8
8.3 Remarks to the achievable accuracy ........................................................................................................................................8
9 Programmable items ......................................................................................................................................................................9
9.1 Parameter table ......................................................................................................................................................................9
9.2 Sensitivity programming (RG, FG) ...........................................................................................................................................9
9.3 Offset / output quiescent volt age programming (VOQ) ...............................................................................................................9
9.4 Output ratiomet ry (ENRA TIO) ..................................................................................................................................................9
Sensitivity temperature drift programming (TC1S T, TC2ND_COLD, TC2ND_HOT) ........................................................................ 10
9.5 ............................................................................................................................................................................................ 10
9.6 Offset temperature drift programming (OFFDR2C, OFFDR2H) ................................................................................................ 10
9.7 Noise filter (NOISEFILT) ....................................................................................................................................................... 10
9.8 Identification code (ID) .......................................................................................................................................................... 10
10 Self diagnostic ........................................................................................................................................................................... 10
11 Application information ............................................................................................................................................................... 11
11.1 Low current measurement ±2-10A ....................................................................................................................................... 11
11.2 Medium current measurement up to ±50A ............................................................................................................................ 11
11.3 High current measurement up to ±1000A .............................................................................................................................. 11
12 Recommended Application Diagrams .......................................................................................................................................... 12
12.1 Resistor and capacitor values .............................................................................................................................................. 12
12.2 Pull down resistor for diagnostic low..................................................................................................................................... 12
12.3 Pull up resistor for diagnostic high ........................................................................................................................................ 12
13 Typical performance................................................................................................................................................................... 13
14 Standard information regarding manufacturability of Melexis products with different soldering processes ......................................... 14
15 ESD Precautions ....................................................................................................................................................................... 14
16 Package information .................................................................................................................................................................. 15
16.1 SOIC-8 Package Dimensions .............................................................................................................................................. 15
16.2 SOIC-8 Pinout and Marking ................................................................................................................................................. 15
16.3 SOIC-8 Hall plate position ................................................................................................................................................... 16
SOIC-8 IMC Position and sensor active measurement dimension ................................................................................................. 16
16.4........................................................................................................................................................................................... 16
Disclaimer ...................................................................................................................................................................................... 17
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Data Sheet
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MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
3 Glossary of Terms
ADC
DAC
DNL
IMC
INL
LSB
MSB
NC
PTC
TC
Tesla
Analog to Digital Converter
Digital to Analog Converter
Differential Non Linearity
Integrated Magneto Concentrator (IMC-Hall)
Integral Non Linearity
Least Significant Bit
Most Significant Bit
Not Connected
Programming Through Connector
Temperature Coefficient in ppm/°C
Units for the magnetic flux density, 1 mT = 10 Gauss
4 Absolute Maximum Ratings
Parameter
Positive Supply Voltage (overvoltage)
Symbol
Vdd
Value
+10
Units
V
Reverse Supply Voltage Protection
-0.3
V
Positive Output Voltage (1)
+10
V
±70
mA
Reverse Output Voltage
-0.3
V
Reverse Output Current
-50
mA
105
°C/W
Output Current
Iout
Package Thermal Resistance
Rth
Operating Ambient Temperature Range
TA
-40 to +150 °C
Storage Temperature Range
TS
-55 to +165 °C
Magnetic Flux Density
infinite
T
Table 1: Absolute maximum ratings
Exceeding the absolute maximum ratings may cause permanent damage. Exposure to absolute maximum
rated conditions for extended periods may affect device reliability.
(1) Valid for supply=10V or supply-pin floating
5 Pin Definitions and Descriptions
Pin #
1
Name
VDEC
Type
Digital
Function
Digital Supply Voltage
3
VSS
Ground
Supply Voltage
4
TEST/MUST
Digital
Test and Factory Calibration
5
VDD
Supply
Supply Voltage
6
OUT
Analog
Current Sensor Output
Table 2: Pin definition and description
It is recommended to connect unused pins to the Ground for optimal EMC results.
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Data Sheet
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MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
6 General Electrical Specifications
Operating Parameters: TA = -40°C to 125°C, Vdd = 4.5V to 5.5V, Iout = -2mA to +2mA, recommended
application diagram in section 1, unless otherwise specified. All mentioned component values can have a
±20% tolerance.
Parameter
Nominal Supply Voltage
Symbol
Vdd
Supply Current
Idd
DC Load Current
Maximum Output Current
(driving capability)
Test Conditions
Min
4.5
Typ
5
Max
5.5
Units
V
Without output load
In application mode
TA = -40°C to 150°C
7
12
14
mA
Iout
Rload in range [6kΩ, 100kΩ]
-2
2
mA
Imax
Inside this range, output voltage
reaches 3%Vdd and 97%Vdd
-2
2
mA
1
5

2
10
nF
Output Resistance
Vout = 50% Vdd, RL = 10kΩ
Output Capacitive Load
Cload
Capacitive load range for the stability
of the output amplifier.
Output amplifier optimized for the
typical capacitive load.
1
Output Resistive Load
Rload
Output resistive load for high linearity
(both pull-up and pull-down resistor)
6
Output Short Circuit Current
Ishort
Output shorted to Vdd (Permanent)
35
180
mA
Output shorted to Vss (Permanent)
35
180
mA
0.5
20
uA
k
Output Leakage current
Ileak
High impedance mode
T = 150°C
Output Voltage Swing
(Linear Range)
Vout_pd
pull down ≥ 10 kΩ
10
90
%Vdd
Vout_pu
pull up ≥ 10 kΩ
10
90
%Vdd
Vout_HiZ_pu
pull-up RL ≤ 25 kΩ, T≤125°C
95
Vout_HiZ_pd
pull-down RL ≤ 25 kΩ, T≤125°C
Vdd_uv d
Low to High Voltage
Vdd_uv h
High-impedance mode levels (1)
Under-voltage detection (2)
Over-voltage detection (2)
Ratiometry enable detection (2)
(1)
1.5
%Vdd
5
%Vdd
3
3.3
4
V
Hysteresis
0.25
0.3
0.4
V
Vdd_ov d2
Low to High Voltage
6.7
7.6
V
Vdd_ov h2
Hysteresis
0.05
0.7
V
Vratio_d
Low to High Voltage
4
4.45
V
Vratio_h
Hysteresis
0.05
0.5
V
Table 3: General electrical parameter
Vout
Hysteresis
(1) Refer to chapter Self diagnostic, Table 10.
(2) According to figure on the right:
Detected
Voltage
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Vdd
Data Sheet
September 2015
MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
7 Magnetic specification
Operating Parameters TA = -40°C to 125°C, Vdd = 4.5V to 5.5V, unless otherwise specified.
7.1 Low Field Version 10mT (marking xxL)
Parameter
Nominal Magnetic field range
Symbol
Bnom
Operational Field Range (1)
Bop
Linearity Error
NL
Hysteresis
Br
Programmable Sensitivity
S
Sensitivity programming Resolution
Sres
Test Conditions
Min
-7.5
Max
+7.5
Units
mT
-10
+10
mT
B in range Bop
Vout in [10%Vdd, 90%Vdd]
-0.7
+0.7
%FS
B = Bop
-10
+10
uT
700
mV/mT
100
Typ
250
0.1
%
Table 4: Magnetic specification for 10mT version (low field)
7.2 High Field Version 25mT (marking xxH)
Parameter
Nominal Magnetic field range
Symbol
Bnom
Operational Field Range (1)
Bop
Linearity Error
NL
Hysteresis
Br
Programmable Sensitivity
S
Sensitivity programming Resolution
Sres
Test Conditions
Min
-20
Max
+20
Units
mT
-25
+25
mT
B in range Bop
Vout in [10%Vdd, 90%Vdd]
-0.7
+0.7
%FS
B = Bop
-25
+25
uT
300
mV/mT
50
Typ
100
0.1
%
Table 5: Magnetic specification for 25mT version (high field)
7.3 Very High Field Version 60mT (marking xxV)
Parameter
Nominal Magnetic field range
Symbol
Bnom
Operational Field Range (1)
Bop
Linearity Error
NL
Hysteresis
Test Conditions
Min
-50
Typ
Max
+50
Units
mT
-60
+60
mT
B in range Bop
Vout in [10%Vdd, 90%Vdd]
-0.7
+0.7
%FS
Br
B = Bop
-50
+50
uT
Programmable Sensitivity
S
CAV-000
CAV-001
30
30
200
200
mV/mT
mV/mT
Sensitivity programming Resolution
Sres
40
60
0.1
%
Table 6: Magnetic specification for 60mT version (very high field)
(1) Outside Bop, the IMC progressively enters saturation, yielding to an increase of the linearity error.
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Data Sheet
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MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
8 Analog output specification
8.1 Timing specification
Operating Parameters TA = -40°C to 125°C, Vdd = 4.5V to 5.5V (unless otherwise specified).
Parameter
Refresh rate
Symbol
Trr
Test Conditions / Comments
Step Response Time
Tresp
Delay between the input signal
reaching 90% and the output signal
reaching 90%, (2V step at the
output, input rise time = 1µs)
-Noise filter OFF
-Noise filter ON
-Noise filter OFF
-Noise filter ON
Bandwidth
BW
Power on Delay
TPOD
Ratiometry Cut-off Frequency
Fratio
Min
0.8
Typ
1
Max
2
Units
μs
200
120
3
5
250
150
4
6
300
180
μs
μs
kHz
kHz
1
ms
Vout =100% of FS
Pull-down resistor ≤100kOhm
During the Power-on delay, the
output will remain within the 10%
fault band at all time.
250
Hz
Table 7: Timing specification for high speed analog output
in, Vout
100%
Response
time
90%
time
1 µs
Figure 4: Response time definition
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MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
8.2 Accuracy specification
Operating Parameters TA = -40°C to 125°C, Vdd = 4.5V to 5.5V (unless otherwise specified).
Parameter
Thermal Offset Drift
Symbol
Δ TVoq
Thermal Offset Drift Resolution
Δ TVoqRes
Thermal Sensitivity Drift
TC
Thermal Sensitivity Drift Resolution
TCres
RMS Output noise
Nrms
Test Conditions
Offset drift referred to 25°C
S=40mV/mT (xxV version)
S=100mV/mT (xxH version)
S=250mV/mT (xxL version)
Vdd=5V
TC=0150 ppm/°C
Voq=500.2 %Vdd
Min
-10
Typ
Max Units
+10 mV
0.075
-1.5
0
mV/°C
+1.5
40
S=40mV/mT (xxV version)
S=100mV/mT (xxH version)
S=250mV/mT (xxL version)
-Noise filter OFF
-Noise filter ON
% of S
ppm/°C
0.2
0.12
%Vdd
%Vdd
Ratiometry Error Offset
ΔVoq
Voq = 50%Vdd
ΔVdd = 10%Vdd
-0.4
+0.4
% of Voq
Ratiometry Error Sensitivity
ΔS
ΔVdd = 10%Vdd
-0.4
+0.4
% of S
Table 8: Accuracy-Specific Parameters
8.3 Remarks to the achievable accuracy
The achievable target accuracy depends on the user end of line calibration. The resolution for the offset and
offset drift calibration is better than 0.1%Vdd. Trimming capability is higher than measurement accuracy. End
user calibration can increase the accuracy of the system.
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Data Sheet
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MLX91208
®
IMC-Hall Current Sensor (Triaxis Technology)
9 Programmable items
9.1 Parameter table
Parameter
Bits
Comment
VOQ[11:0]
12
Quiescent output level (0 Gauss) adjustment
RG[2:0]
3
Rough gain adjustment
FG[9:0]
10
Fine gain adjustment
ENRATIO
1
Ratiometry enablement
TC1[7:0]
8
Adjustment of the first order temperature compensation of the magnetic sensitivity
TC2HOT[4:0]
5
Adjustment of the extra temperature compensation of the magnetic sensitivity at
high temperature
TC2COLD[4:0]
5
Adjustment of the extra temperature compensation of the magnetic sensitivity at
low temperature
OFFDR2C[5:0]
6
Adjustment of the offset drift at low temperature after the VGA
OFFDR2H[5:0]
6
Adjustment of the offset drift at high temperature after the VGA
NOISEFILT
1
Noise filter enablement
CRC[15:0]
16
16-bit CRC for the checksum calculation of the configuration register.
ID[47:0]
48
Customer identification code
Table 9: Customer programmable items
9.2 Sensitivity programming (RG, FG)
The sensitivity can be programmed from 50 to 300mV/mT (high field version) or 100 to 700mV/mT (low field
version), with the ROUGHGAIN (3 bits) and FINEGAIN (10 bits) parameters.
9.3 Offset / output quiescent voltage programming (VOQ)
The offset is programmable with 12 bits in 1.5 mV steps over the full output range. This corresponds to a
calibration resolution of 0.03 %VDD.
The typical step size would be 5V/4096 = 1.22 mV, but the actual step size can differ from the nominal value
because of internal gain tolerance. A maximum step size of 1.5 mV is guaranteed.
Note: for optimal performance over temperature, the VOQ should be programmed in the range from 2 to 3V.
9.4 Output ratiometry (ENRATIO)
The ratiometry of the output versus the supply can be disabled by setting this bit to 0.
Note: for optimal performance over temperature, the ratiometry setting should not be changed on customer
side. By default, this setting is enabled during final test calibration.
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Data Sheet
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MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
9.5 Sensitivity temperature drift programming (TC1ST, TC2ND_COLD, TC2ND_HOT)
First order sensitivity temperature drift can be trimmed with TC1. The programming resolution is 40ppm/K.
Second order sensitivity temperature drift can be trimmed with TC2COLD and TC2HOT. The programming
resolution is 2ppm/K2 for TC2COLD and 0.6ppm/K2 for TC2HOT.The second order can also be seen as third
order correction since cold and hot sides are independently adjusted.
Note: for optimal performance over temperature, the first order sensitivity drift compensation (TC1ST) should
not exceed ±250ppm/K.
9.6 Offset temperature drift programming (OFFDR2C, OFFDR2H)
Offset temperature drift caused by the output amplifier can be compensated with these two parameters. This
first order correction is done independently for temperatures over and below 25°C.
Note: Two additional parameters (OFFDR1C, OFFDR1H) are calibrated by Melexis to compensate for the
offset temperature drift caused by the Hall element (before the variable gain amplifier). These parameters
should not be adjusted on customer-side.
9.7 Noise filter (NOISEFILT)
Setting this bit to 1 enables the noise filter, reducing noise and increasing response time.
9.8 Identification code (ID)
48 bits programmable identification code.
10 Self diagnostic
The MLX91208 provides self diagnostic features to detect internal memory errors and over- / under-voltage.
Those features increase the robustness of the IC functionality, as they prevent the IC from providing
erroneous output signal in case of internal or external failure modes.
Error
Calibration Data CRC Error (at power up
and in normal working mode)
Action
Effect on Outputs
Fault mode
High Impedance mode
Power On delay
Undervoltage Mode
Overvoltage detection
High Impedance mode
IC is reset
IC is reset
High Impedance mode
High Impedance mode
Remarks
Pull down resistive load => Diag Low
Pull up resistive load => Diag High
5ms max in high impedance followed by
settling
300mV Hysteresis (typical)
100mV Hysteresis (typical)
Table 10: Self diagnostic
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MLX91208
®
IMC-Hall Current Sensor (Triaxis Technology)
11 Application information
Please refer to our current sensor reference design guide for more application information:
http://melexis.com/Assets/Current-Sensors-Reference-Designs-6187.aspx
11.1 Low current measurement ±2-10A
Low currents can be measured by either using a multi-turn/multi-layer PCB where the current is allowed to
flow several times under the sensor, or by adding a closed ferromagnetic shield around the current trace with
a small air gap to concentrate the magnetic flux above the sensor.
Figure 3: Low current applications with either multi-trace/multi-layer PCB (left) or closed shield (right).
11.2 Medium current measurement up to ±50A
For medium currents, a single PCB trace can be used. The
sizing of the PCB trace should take into account the current
handling capability and the total power dissipation. The PCB
trace should be thick and wide enough to handle the RMS
current continuously.
A simple “U-shaped” ferromagnetic shield is often required to
protect the sensor from cross-talk or external stray fields, if
they cannot be cancelled-out by other means (peak-peak
detection, etc.).
Figure 4: Medium current application on PCB
11.3 High current measurement up to ±1000A
For high currents flowing in a bus bar, MLX91208 is typically
assembled on a PCB lying immediately above the current
conductor.
A ferromagnetic shield is usually added to protect the sensor
from external fields and ensure good homogeneity of the
magnetic flux, for optimal robustness against vibrations and
mechanical tolerances.
Figure 5: High current application on bus bar
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MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
12 Recommended Application Diagrams
12.1 Resistor and capacitor values
Part
C1
Description
Supply capacitor, EMI, ESD
Value
100
Unit
nF
C2
Decoupling, EMI, ESD
2-10 (1)
nF
C3
Decoupling, EMI, ESD
47
nF
R1
Pull up or pull down resistor
6-100
kΩ
Table 11: Resistor and capacitor values
(1) 10nF is recommended for better EMC and ESD performance.
12.2 Pull down resistor for diagnostic low
1
8
VDEC
MLX91208
C3
2
7
3
VSS
OUT
6
Analog Output
4
TEST
VDD
5
Supply voltage
C1
C2
R1
GND
Figure 6: Diagnostic low
12.3 Pull up resistor for diagnostic high
1
8
VDEC
MLX91208
C3
2
3
7
VSS
OUT
6
Analog Output
R1
4
TEST
VDD
5
Supply voltage
C1
C2
GND
Figure 7: Diagnostic high
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MLX91208
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®
IMC-Hall Current Sensor (Triaxis Technology)
13 Typical performance
Figure 8: Thermal sensitivity drift.
Figure 9: Thermal offset drift.
Figure 10: Linearity error for all versions.
shunt
shunt
MLX91208
MLX91208
Figure 11: Response time with noise filter OFF.
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Figure 12: Response time with noise filter ON.
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Data Sheet
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MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
14 Standard information regarding manufacturability of Melexis
products with different soldering processes
Melexis devices are qualified using state-of-the-art practices in accordance with automotive and
environmental requirements.
Through qualifications, various soldering techniques are considered;
recommendations for Melexis products” for more information:
please refer
to “Soldering
(http://www.melexis.com/Asset/Soldering_Application_Note_and_Recommendations_DownloadLink_5446.aspx).
For components normally soldered using Surface Mounted Device techniques (eg: Reflow process), Melexis
has defined and qualified Moisture Sensitivity Level and Peak Temperature in accordance with the Jedec JSTD-020 standard. Delivered material is conditioned accordingly. Moisture Sensitivity Level and Peak
Temperature information can be found on the label identifying the material.
In case you intend to use a reflow soldering process for through hole devices (Melexis’ package codes: SA,
UA, VA, VK, VM), please contact Melexis to verify your soldering process compatibility.
The application of Wave Soldering for SMD’s is allowed only after consulting Melexis regarding assurance of
adhesive strength between device and board.
Based on Melexis commitment to environmental responsibility, Europe legislations (Direction on the
Restriction of the Use of Certain Hazardous substances, RoHS) and customer requests, Melexis has
deployed Pb free leadfinish (typically Matte Tin) on all ASSP products.
For through hole devices (Melexis’ package codes: SA, UA, VA, VK, VM) Trim&Form, please refer to “Trim &
Form recommendations for Melexis products” for more information:
(http://www.melexis.com/Assets/Trim_and_form_recommendations_DownloadLink_5565.aspx)
15 ESD Precautions
Electronic semiconductor products are sensitive to Electro Static Discharge (ESD).
Always observe Electro Static Discharge control procedures whenever handling semiconductor products.
ESD HBM robustness is 2kV on external pins according to AEC-Q100-002 REV-D.
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Data Sheet
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MLX91208
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®
IMC-Hall Current Sensor (Triaxis Technology)
16 Package information
16.1 SOIC-8 Package Dimensions
1.27 TYP
NOTES:
3.81
3.99**
4.80
4.98*
5.84
6.20**
All dimensions are in millimeters (anlges in degrees).
* Dimension does not include mold flash, protrusions or
gate burrs (shall not exceed 0.15 per side).
** Dimension does not include interleads flash or protrusion
(shall not exceed 0.25 per side).
*** Dimension does not include dambar protrusion.
Allowable dambar protrusion shall be 0.08 mm total in
excess of the dimension at maximum material condition.
Dambar cannot be located on the lower radius of the foot.
1.40
1.55
1.55
1.73
0.19
0.25
0°
8°
0.35
0.49***
0.127
0.250
0.41
0.89
Figure 13: SOIC-8 Package dimensions
16.2 SOIC-8 Pinout and Marking
Very high field version
YYWWVP
Figure 14: SOIC-8 Pinout and marking (Very High Field, High Field and Low Field version)
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Data Sheet
September 2015
MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
16.3 SOIC-8 Hall plate position
0.46 +/- 0.06
1.85
2.15
2.35
2.55
Figure 15: SOIC-8 Hall Plate positioning
16.4 SOIC-8 IMC Position and magnetic sensitive direction
B extern
B extern
Figure 16: IMC position and geometry for low-field version
B extern
B extern
Figure 17: IMC position and geometry high-field version
B extern
B extern
Figure 18: IMC position and geometry very high-field version
3901091208
REV004
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Data Sheet
September 2015
MLX91208
®
®
IMC-Hall Current Sensor (Triaxis Technology)
Disclaimer
Devices sold by Melexis are covered by the warranty and patent indemnification provisions appearing in its
Term of Sale. Melexis makes no warranty, express, statutory, implied, or by description regarding the
information set forth herein or regarding the freedom of the described devices from patent infringement.
Melexis reserves the right to change specifications and prices at any time and without notice. Therefore, prior
to designing this product into a system, it is necessary to check with Melexis for current information. This
product is intended for use in normal commercial applications. Applications requiring extended temperature
range, unusual environmental requirements, or high reliability applications, such as military, medical lifesupport or life-sustaining equipment are specifically not recommended without additional processing by
Melexis for each application.
The information furnished by Melexis is believed to be correct and accurate. However, Melexis shall not be
liable to recipient or any third party for any damages, including but not limited to personal injury, property
damage, loss of profits, loss of use, interrupt of business or indirect, special incidental or consequential
damages, of any kind, in connection with or arising out of the furnishing, performance or use of the technical
data herein. No obligation or liability to recipient or any third party shall arise or flow out of Melexis’ rendering
of technical or other services.
© 2009 Melexis NV. All rights reserved.
For the latest version of this document, go to our website at
www.melexis.com
Or for additional information contact Melexis Direct:
Europe, Africa, Asia:
Phone: +32 1367 0495
E-mail: [email protected]
America:
Phone: +1 603 223 2362
E-mail: [email protected]
ISO/TS 16949 and ISO14001 Certified
3901091208
REV004
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Data Sheet
September 2015
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