MLX91206LDCCAH-002RE [MELEXIS]
IMC-HallCurrent Sensor (TriaxisTechnology);型号: | MLX91206LDCCAH-002RE |
厂家: | Melexis Microelectronic Systems |
描述: | IMC-HallCurrent Sensor (TriaxisTechnology) |
文件: | 总25页 (文件大小:883K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
MLX91206
IMC-Hall®Current Sensor (Triaxis®Technology)
Features and Benefits
Application Examples
Triaxis® Technology
DC/AC (inverter) converter
Very high sensitivity due to Integrated
Magnetic Concentrator (IMC-Hall®)
Programmable high speed current sensor IC
Wideband: DC to 90kHz
DC/DC switched mode power supply
Battery Management
Smart fuse (over-current detection)
BLDC motor (phase current)
AC/DC Converters
Short response time
Programmable linear transfer characteristic
Selectable
analog ratiometric output
PWM output with 12 bit resolution
Thermometer output
17 bit ID Number
SOIC8 package RoHS compliant
Lead free component, suitable for lead free
soldering profile 260°C (target), MSL3
Ordering Information
Product
Code
Temperature
Code
Package
Code
Ordering
Option Code
Packing
form Code
Sensitivity Range
(Typ.)
MLX91206
MLX91206
MLX91206
MLX91206
MLX91206
MLX91206
MLX91206
MLX91206
MLX91206
L (-40°C to 150°C)
L (-40°C to 150°C)
L (-40°C to 150°C)
L (-40°C to 150°C)
L (-40°C to 150°C)
L (-40°C to 150°C)
L (-40°C to 150°C)
L (-40°C to 150°C)
L (-40°C to 150°C)
DC (SOIC)
DC (SOIC)
DC (SOIC)
DC (SOIC)
DC (SOIC)
DC (SOIC)
DC (SOIC)
DC (SOIC)
DC (SOIC)
CAL-001
CAL-002
CAL-003
CAH-001
CAH-002
CAH-003
CAH-004
CAH-021(1)
CAH-104(2)
460-700mV/mT (580mV/mT)
300-470mV/mT (380mV/mT)
200-310mV/mT (250mV/mT)
210-330mV/mT (270mV/mT)
130-220mV/mT (170mV/mT)
80-140mV/mT (110mV/mT)
60-110mV/mT (77.5mV/mT)
210-330mV/mT (270mV/mT)
0.5-5%DC/mT
TU (Tube) / RE (Reel)
(1) The MLX91206 sensor is in disabledratiometry mode by default for this version
(2) The MLX91206 sensor is in PWM mode by default for this version
Ordering example: MLX91206LDC-CAL-001-RE
1 Functional Diagram
3.3V
ana
Voltage
Regulator
&
Rev.Pol.
protection
3.3V core
VDIG
TEMPOUT
3.3V
dig
Thermometer
VDD
VSS
Oscillator
1 MHz
Clock
Generator
fi = 250kHz or 25kHz
Intermediate data rate
5V ratiometric
output
fs = 1MHz
Input data rate
fs = 1MHz
fo = 250 kHz or 25 kHz
Output data rate
4-
Phase
Switch
Box
Integrating
P2P
Output
Buffer
OUT
DIDO
Clamping
LPF
S&H
G = 15 … 239
G = 0.4 … 1
G = 4
ADC
Hall
Bias
PWM Logic
3 bits
10 bits
2 bits
6 bits
Digital
Ratiometry
12 bits
RG[2:0]
PLATEPOL
FILTCODE[1:0]
MUST0
TC1ST[6:0]
FG[9:0]
XA[11:0] CLAMPLOW[2:0]
CLAMPHIGH[2:0]
TC2ND_COLD[4:0]
TC2ND_HOT[4:0]
OFFSETDRIFT_HOT[5:0]
OFFSETDRIFT_COLD[5:0]
MUST1
DIGITAL + EEPROM
HallSensors
selection
Sensitivity
trimming
Offset
Polarity
TESTOUT
Bandwidth
Voq adjust
Rough Gain
Fine Gain
Compensation
selection
Figure 1: Block diagram
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Datasheet MLX91206
April 2016
MLX91206
IMC-Hall®Current Sensor (Triaxis®Technology)
2 General Description
The MLX91206 is a monolithic sensor IC featuring the Triais® 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® current sensor is automotive qualified.
The product is a single chip Hall sensor which provides an output signal which is proportional to the flux
density applied horizontally and is therefore suitable for current measurement. It is ideally used as an open
loop current sensor for PCB mounting. (see figure 2). It features small size application design and a simple
construction for various current ranges.
The transfer characteristic of the MLX91206 is programmable (offset, gain, clamping levels, diagnostic
functions…). The output is selectable between analog and PWM. The linear analog output is used for
application where a very fast response (<10 sec) is required, whereas the PWM output is used for
application where low speed but high output signal robustness is required.
Figure 2: Typical application of MLX91206
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Datasheet MLX91206
April 2016
MLX91206
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 25 mT version (marking xxH).......................................................................................................................................................... 6
7.2 10 mT version (marking xxL) ......................................................................................................................................................... 6
8 Analog output specification.................................................................................................................................................................... 7
8.1 Timing specification........................................................................................................................................................................ 7
8.2 Accuracy specification.................................................................................................................................................................... 7
8.3 Remarks to the achievable accuracy .............................................................................................................................................. 7
9 PWM output specification ...................................................................................................................................................................... 8
9.1 Timing specification for the PWM output......................................................................................................................................... 8
9.2 Magnetic specification for the PWM output..................................................................................................................................... 9
9.3 Accuracy specification transfer characteristic PWM........................................................................................................................ 9
10 Thermometer output specification........................................................................................................................................................ 9
11 Programmable items.......................................................................................................................................................................... 10
11.1 Parameter table.......................................................................................................................................................................... 10
11.2 Output mode configuration (DSPMODE, OUTMODE) ................................................................................................................ 11
11.3 Output impedance mode (DIAGINFAULT).................................................................................................................................. 11
11.4 Reference edge (REFEDGE) – only in PWM mode.................................................................................................................... 11
11.5 PWM/switch mode (SWITCH)..................................................................................................................................................... 11
11.6 Platepol (PLATEPOL)................................................................................................................................................................. 12
11.7 Sensitivity programming (ROUGHGAIN, FINEGAIN).................................................................................................................. 12
11.8 Offset / output quiescent voltage programming (XA, YA) ............................................................................................................ 13
11.9 Clamping level programming (CLAMPLOW, CLAMPHIGH)........................................................................................................ 13
11.10 Bandwidth and filter programming (FILTCODE)........................................................................................................................ 14
11.11 Power limitation / PWM rise and fall time (OUTSLOPE)............................................................................................................ 15
11.12 PWM Mode duty cycle definition (DCDEF) ............................................................................................................................... 16
11.13 Output ratiometry (RATIODIS).................................................................................................................................................. 16
11.14 Sensitivity and temperature drift programming (TC1ST, TC2ND_COLD, TC2ND_HOT)........................................................... 16
11.15 Offset temperature drift programming (OFFDRIFT_COLD, OFFDRIFT_HOT).......................................................................... 16
11.16 Product Identification (MLXID, CSTID)...................................................................................................................................... 17
12 Application information....................................................................................................................................................................... 18
12.1 Low current measurement up to ±2 A......................................................................................................................................... 18
12.2 Medium current up to ±30 A ....................................................................................................................................................... 18
12.3 High current measurement up to ±600 A .................................................................................................................................... 18
13 Recommended Application Diagrams ................................................................................................................................................ 19
13.1 Resistor and capacitor values..................................................................................................................................................... 19
13.2 Fast analog application, pull-down resistor for diagnostic low..................................................................................................... 19
13.3 Fast analog application, pull-up resistor for diagnostic high ........................................................................................................ 20
13.4 Robust PWM application, (pull-up load only) .............................................................................................................................. 20
14 Standard information regarding manufacturability of Melexis products with different soldering processes.......................................... 21
15 ESD Precautions ............................................................................................................................................................................... 21
16 Package Information.......................................................................................................................................................................... 22
16.1 SOIC8 Package dimensions....................................................................................................................................................... 22
16.2 SOIC8 Pinout and Marking......................................................................................................................................................... 22
16.3 SOIC8 Hall plate position............................................................................................................................................................ 23
16.4 IMC Position and sensors active measurement direction............................................................................................................ 23
17 Related documents and tools............................................................................................................................................................. 24
17.1 Related documents .................................................................................................................................................................... 24
17.2 Related software ........................................................................................................................................................................ 24
17.3 Related hardware....................................................................................................................................................................... 24
18 Disclaimer.......................................................................................................................................................................................... 25
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Datasheet MLX91206
April 2016
MLX91206
IMC-Hall®Current Sensor (Triaxis®Technology)
3 Glossary of Terms
Tesla
TC
Units for the magnetic flux density, 1 mT = 10 Gauss
Temperature Coefficient in ppm/deg C
NC
Not Connected
PWM
%DC
ADC
DAC
LSB
MSB
DNL
INL
Pulse Width Modulation
Duty Cycle of the output signal i.e. TON /(TON + TOFF
Analog to Digital Converter
Digital to Analog Converter
Least Significant Bit
Most Significant Bit
Differential Non Linearity
)
Integral Non Linearity
IMC
PTC
Integrated Magneto Concentrator (IMC)
Programming Through Connector
4 Absolute Maximum Ratings
Parameter
Symbol
Value
+20
Units
Positive Supply Voltage (overvoltage)
Reverse Supply Voltage Protection
Positive Output Voltage
Vdd
V
V
V
-10
+10
+14 (200 s max, TA = +25°C)
Output Current
Iout
±300
mA
V
Reverse Output Voltage
Reverse Output Current
Operating Ambient Temperature Range
Storage Temperature Range
Magnetic Flux Density
-0.3
-50
mA
°C
°C
T
TA
TS
-40 to +150
-55 to +165
±0.2
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.
5 Pin Definitions and Descriptions
Pin №
Name
VDD
Type
Function
1
2
3
4
5
6
7
8
Supply
Ground
Supply
Digital
Supply Voltage
VSS
Supply Voltage
VDIG
Digital supply voltage, 3.3 V, internal regulated
Test and Factory calibration
MUST1
OUT / PWM
TESTOUT
MUST0
TEMPOUT
Analog/Digital Current sensor output
Digital
Digital
Analog
Test and Factory calibration
Test and Factory calibration
Temperature Sensor Output
Table 2: Pin definition and description
It is recommended to connect the unused pins to the Ground (see section 16) for optimal EMC results.
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Datasheet MLX91206
April 2016
MLX91206
IMC-Hall®Current Sensor (Triaxis®Technology)
6 General Electrical Specifications
Operating Parameters : TA = -40 to 125degC, Vdd = 4.5 V to 5.5 V, Iout = -2 mA to +2 mA, recommended
application diagram in section 16, unless otherwise specified. All mentioned component values can have a
±20% tolerance
Parameter
Symbol
Vdd
Test Conditions
Min
Typ
Max
Units
Nominal Supply Voltage
Supply Current
4.5
5
5.5
V
Idd
W/o output load & TA = -40 to 150oC
- ROUGHGAIN ≤ 3
- ROUGHGAIN > 3
7
9
10
12
mA
mA
Output Current
Iout
Cload
Ishort
Ileak
-2
2
mA
Output Resistance
Output Capacitive Load
Vout = 50% Vdd, RL = 5kΩ
Analog Mode
1
5
nF
5
0
10
10
50
50
PWM Mode
nF
Output Short Circuit Current
Leakage current
Output shorted to Vdd- Permanent
Output shorted to Vss - Permanent
High impedance mode (2)
Not Destroyed
Not Destroyed
5
uA
Output Voltage Swing (Linear
Range)
Vout_pd
Vout_pu
pull down ≥ 10 kΩ
pull up ≥ 10 kΩ
5
95
%Vdd
%Vdd
%Vdd
%Vdd
%Vdd
5
95
High-impedance mode levels(2) Vout_HiZ_pu
pull-up RL ≤ 30 kΩ
pull-down RL ≤ 30 kΩ
97
Vout_HiZ_pd
OUT with pull-down RL ≤ 10 kΩ (3)
3
3
BrokenVss Output Levels(2)
OUT with pull-up RL ≤ 30 kΩ (3)
OUT with pull-down RL ≤ 30 kΩ (3)
OUT with pull-up RL ≤ 30 kΩ (3)
97
%Vdd
%Vdd
%Vdd
V
BrokenVdd Output Levels(2)
Under-voltage detection (2) (4)
3
97
Vdd_uvd
Detected Voltage (Low to High)
3.15
0.25
7.8
3.3
0.3
3.45
0.4
9.5
1.6
7.6
0.5
10
Vdd_uvh
Hysteresis
V
V
Over-voltage detection mode 1 Vdd_ovd1
Detected Voltage (Low to High)
(2) (4)
Vdd_ovh1
Hysteresis
0.8
V
Over-voltage detection mode 2 Vdd_ovd2
Detected Voltage (Low to High)
Hysteresis
6.7
V
(2) (4)
Vdd_ovh2
0.05
5 (1)
90
V
Clamped Output Level
Clamp_lo
Clamp_hi
Trimming Range
Trimming Range
%Vdd
%Vdd
95 (1)
Table 3: General electrical parameter
(1) Factory programmed clamping level
(2) Refer to chapter Self-diagnostic, table 21.
(3) Valid for TEMPOUT with pull-up (min. 30kΩ), pull-down (min. 30kΩ) or not connected
(4) According to the figure below
Vout
Hysteresis
Detected
Voltage
Vdd
Figure “Detected voltage and hysteresis definitions”
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Datasheet MLX91206
April 2016
MLX91206
IMC-Hall®Current Sensor (Triaxis®Technology)
7 Magnetic specification
7.1 25 mT version (marking xxH)
Operating Parameters TA = -40 to 125degC, Vdd = 4.5 V to 5.5 V, unless otherwise specified.
Parameter
Symbol Test Conditions
Min
Typ
Max
Units
Nominal Field Range
Bnom
-20
+20
mT
(1)
Operational Field Range
Linearity Error
Bop
-25
-0.5
+25
mT
NL
Nominal Field Range (25°C)
+0.5
+0.75
+25
%FS
%FS
uT
Operational Field Range (25°C) -0.75
Hysteresis, remanent Field
Programmable Sensitivity
Br
S
B = Bop
-25
80
(2)
B = Bop , Analog Mode
330
mV/mT
Sensitivity programming Resolution Sres
B = Bop
0.1
%
Table 4: Magnetic specification 25mT version (high-field version)
(1) Above 25 mT, the IMC starts saturating yielding to an increase of the linearity error.
(2) The specified programmable sensitivity range is covered by 5 different versions (option codes)
Option code (25mT)
CAH-001
Programmed Sensitivity
270mV/mT
Sensitivity Range
210 - 330mV/mT
130 - 220mV/mT
80 - 140mV/mT
60 - 110mV/mT
210 - 330mV/mT
CAH-002
CAH-003
CAH-004
CAH-021
170mV/mT
110mV/mT
77.5mV/mT
270mV/mT
7.2 10 mT version (marking xxL)
Operating Parameters TA = -40 to 125degC, Vdd = 4.5 V to 5.5 V (unless otherwise specified)
Parameter
Symbol Test Conditions
Min
Typ
Max
Units
Nominal Field Range
Bnom
-7.5
+7.5
mT
Operational Field Range (3)
Bop
-10
-0.5
+10
mT (2)
%FS
%FS
uT
Linearity Error
NL
Nominal Field Range (25°C)
+0.5
+0.75
+10
Operational Field Range (25°C) -0.75
Hysteresis, remanent Field
Programmable Sensitivity (4)
Br
S
B = Bop
-10
B = Bop , Analog Mode
B = Bop
200
700
mV/mT
%
Sensitivity programming Resolution Sres
0.1
Table 5: Magnetic specification 10mT version (low-field version)
(3) Above 10 mT, the IMC starts saturating yielding to an increase of the linearity error.
(4) The specified programmable sensitivity range is covered by 3 different versions (option codes)
Option code (10mT)
CAL-001
Programmed Sensitivity
580mV/mT
Sensitivity Range
460-700mV/mT
300-470mV/mT
200-310mV/mT
CAL-002
CAL-003
380mV/mT
250mV/mT
3901091206
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Datasheet MLX91206
April 2016
MLX91206
IMC-Hall®Current Sensor (Triaxis®Technology)
8 Analog output specification
8.1 Timing specification
Operating Parameters TA = -40 to 125degC, Vdd = 4.5 V to 5.5 V (unless otherwise specified)
Parameter
Symbol
Tresp
BW
Test Conditions
Voq ± 2 V
Min
Typ
8
Max
10
Units
μs
Step Response Time
Bandwidth
Full Range
50
70
90
kHz
Power on Delay
TPOD
Vout =100% of FS
(BW = 100 Hz)
(BW = 1000 Hz)
(BW = 10 kHz)
100
10
5
ms
ms
ms
ms
(BW = 100 kHz – No filter)
5
Ratiometry Cut-off Frequency
Fratio
250
Hz
Table 6: Timing specification high speed analog output
8.2 Accuracy specification
Operating Parameters TA = -40 to 125degC, Vdd = 4.5 V to 5.5 V (unless otherwise specified)
Parameter
Symbol
ΔTVoq
ΔTVoq
Test Conditions
Min
-0.4
-20
Typ
Max
+0.4
20
Units
%Vdd
mV
Thermal Offset Drift
Thermal Offset Drift(1)
Thermal Sensitivity Drift
RMS Output noise
TC
-1.5
+1.5
0.1
%S
Nrms
S = 6 %Vdd/mT (= 300 mV/mT @
Vdd=5V)
%Vdd
Voq Ratiometry
ΔVoq
ΔVoq
ΔS
Voq = 50%Vdd
ΔVdd = 10%Vdd
9.8
10.2
5
%
Voq Drift – Supply Related(1)
Sensitivity Ratiometry
Voq = 50%Vdd (Vdd Nominal = 5V) -5
ΔVdd = 10%Vdd
mV
%
ΔVdd = 10%Vdd
9.8
10.2
B = Bop
Clamped output accuracy
Clamp_lo
Clamp_hi
Trimming range: 5-10%Vdd
Trimming range: 90-95%Vdd
-1
1
%Vdd
Table 7: Accuracy specific parameter analog output
(1) Applies to CAH-021 version
8.3 Remarks to the achievable accuracy
The achievable target accuracy is dependent on user’s end-of-line calibration. The resolution for the offset
and offset drift calibration is better than 0.1%Vdd. Trimming capability is higher than the measurement
accuracy. End-user calibration can increase the accuracy of the system.
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Datasheet MLX91206
April 2016
MLX91206
IMC-Hall®Current Sensor (Triaxis®Technology)
9 PWM output specification
9.1 Timing specification for the PWM output
Operating Parameters TA = -40 to 125degC, Vdd = 4.5 V to 5.5 V (unless otherwise specified)
Parameter
Symbol
Test Conditions
Min
Typ
Max
Units
Main Oscillator Frequency
FOSC
900
1024
1100
kHz
Tolerance 10%
PWM Output Frequency
FPWM
tTICK
110
125
1
140
Hz
µs
Tick Time (resolution in time
domain)
PWM Output Resolution
PWM Jitter (1 Sigma)
R(PWM)
J (PWM)
12 Bit, Theoretical Jitter free
0.025
0.01
%DC
FILTCODE = 5
%DC
(70 Hz Digital LowPass Filter)
(1 Sigma)
Output Rise Time
(10%-90%)
tRISEOD
Push-pull mode
11
µs
RL = 4.7 k to 5 V, CL = 10 nF
OUTSLOPE = 0
OUTSLOPE = 1
OUTSLOPE = 2
OUTSLOPE = 3
7
μs
μs
μs
µs
4
2.5
14
Output Fall Time
(90%-10%)
TFALLOD
Push-pull or open-drain mode
RL = 4.7 k to 5 V, CL = 10 nF
OUTSLOPE = 0
OUTSLOPE = 1
OUTSLOPE = 2
OUTSLOPE = 3
Programmable
Programmable
8
μs
4.5
2.5
μs
μs
Clamped Output Level
Power-on delay
Clamp_lo
Clamp_hi
TPOD
1
10
99
11
%DC
%DC
ms
90
Table 8: Timing specification for the PWM output
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Datasheet MLX91206
April 2016
MLX91206
IMC-Hall®Current Sensor (Triaxis®Technology)
9.2 Magnetic specification for the PWM output
Operating Parameters TA = -40 to 125degC, Vdd = 4.5 V to 5.5 V, unless otherwise specified.
Parameter
Symbol Test Conditions
Min
Typ
Max
Units
Nominal Field Range
Bnom
-20
+20
mT
(1)
Operational Field Range
Linearity Error
Bop
-25
-0.5
+25
+0.5
+0.75
+25
5
mT
NL
Nominal Field Range (25°C)
%FS
%FS
uT
Operational Field Range (25°C) -0.75
Hysteresis, remanent Field
Programmable Sensitivity
Br
S
B = Bop
B = Bop
-25
0.5
%DC/mT
Sensitivity programming Resolution Sres
B = Bop
0.1
%
Table 9: Magnetic specification 25mT version (high-field version)
(1) Above 25 mT, the IMC starts saturating yielding to an increase of the linearity error.
9.3 Accuracy specification transfer characteristic PWM
Operating Parameters TA = -40 to 125degC, Vdd = 5.0 V (unless otherwise specified), S = 4%DC/mT
Parameter
Symbol
ΔTVoq
TC
Test Conditions
Min
-0.4
-150
Typ
Max
+0.4
Units
%DC
Thermal Offset Drift
Thermal Sensitivity Drift
+150
ppm/°C
Table 10: Accuracy specific parameter PWM output
10 Thermometer output specification
The thermometer output voltage is in the range from 367mV to 2930mV for temperatures ranging from -40 to
150degC. The accuracy is better than 5degC. The pin shall be able to sustain a low impedance connection to
maximum 14V. This output is not ratiometric.
Parameter
Offset
Symbol Test Conditions
Min
Typ
1.38
13.5
Max
Units
V
T35
Output voltage with T = 35degC
Slope
Tslope
mV/degC
degC
nF
Accuracy
Tacc
-5
5
Load capacitor
Output current
CloadTherm External through bonding wire
Iouttherm
1
50
+0.1
-0.1
mA
Table 11: Thermometer output specification
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Datasheet MLX91206
April 2016
MLX91206
IMC-Hall®Current Sensor (Triaxis®Technology)
11 Programmable items
11.1 Parameter table
Customers can re-program the parameters described in the table below by using the Melexis PTC-04
hardware and the Product Specific Functions (PSF) libraries provided by Melexis. We recommend using the
latest version of the PSF and the latest version of the firmware with a communication speed of 10kbps
(limited by a maximum output capacitor of 50nF). Software and firmware are available on the softdist platform
(see contact details on page 25 to request an account).
Parameter
DSPMODE
OUTMODE
Bits
Factory Setting Comment
1
1
0
1
Selection analog or PWM output
Capacitive load selection in analog mode
Push pull or open drain output drive in PWM mode
N/A
0
Output impedance setting
Not used in analog mode
DIAGINFAULT
REFEDGE
1
1
0
Diagnostic level & reference edge
Not used in analog mode
SWITCH
1
N/A
0
PWM or SWITCH output selection
Change of sensitivity sign
PLATEPOL(1)
ROUGHGAIN
FINEGAIN
1
0
3
Trimmed
Trimmed
Trimmed
Trimmed
Trimmed
N/A
Rough gain preamplifier
10
13
12
14
9
Fine gain from 0.4 to 1.0 in analog mode
Fine gain from -3.999 to +3.999 in PWM mode
Offset compensation VOQ in analog mode
Digital offset in PWM mode
XA
YA
Not used in analog mode
32
Rough offset compensation in PWM mode
Clamping low level in analog mode
CLAMPLOW
3
3
Trimmed
N/A
Not used in PWM mode
CLAMPHIGH
FILTCODE
OUTSLOPE
DCDEF
Trimmed
Clamping high level in analog mode
Clamping high and low level for PWM output
Analog filter in analog mode
2
0
2
3
3
4
2
Digital filter in PWM mode
Power limitation of the output driver on high frequencies in analog
Output slope control for PWM mode
1
1
0
1
Not used in analog mode
PWM duty cycle definition
RATIODIS(1)
0/1(2)
Enable/Disable ratiometry between output signal and supply
Not used in PWM mode
N/A
TC1ST
7
Trimmed
Trimmed
Trimmed
Trimmed
Trimmed
Programmed
N/A
Sensitivity temperature drift correction first order
Sensitivity temperature drift correction second order for cold
Sensitivity temperature drift correction second order for hot
Offset temperature drift correction for cold temperatures
Offset temperature drift correction for hot temperatures
MLX ID
TC2ND_COLD
TC2ND_HOT
OFFDRIFT_COLD
OFFDRIFT_HOT
MLXID
5
5
6
6
48
17
CSTID
Customer ID
Table 92: Customer programmable items
(1): Changing these parameters has an impact on temperature calibration. (2): Default value is 1 only for CAH-021 version.
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IMC-Hall®Current Sensor (Triaxis®Technology)
11.2 Output mode configuration (DSPMODE, OUTMODE)
DSPMODE activates the PWM or the analog mode for the output signal. OUTMODE configures the output
driver.
DSPMODE
OUTMODE
Output Driver
0
0
Fast analog mode, CL = 1nF..10nF(1) (2)(3)
(1) (2)(4)
0
1
1
1
0
1
Normal analog mode, CL = 5nF..50nF
PWM mode – Open drain
PWM mode – Push pull
Table 13: Output configuration
(1) See section 16, CL = C4.
(2) Factory setting: DSPMODE = 0, OUTMODE = 1.
(3) For applications directly integrated on a PCB, smaller capacitors are allowed at the output pins.
(4) For a standalone application where a cable is connected at the output of the sensor.
11.3 Output impedance mode (DIAGINFAULT)
DIAGINFAULT sets the output impedance mode.
DIAGINFAULT
Output impedance
0
Low impedance mode (normal mode)
1
High impedance mode (diagnostic level)
11.4 Reference edge (REFEDGE) – only in PWM mode
REFEDGE defines the diagnostic level and sets the reference edge.
REFEDGE
Reference edge
(PWM)
0
1
Falling edge
Rising edge
11.5 PWM/switch mode (SWITCH)
In PWM mode, the output can be configured to switch mode.
SWITCH
Operating mode
0
Disable switch mode
1
Enable switch mode
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IMC-Hall®Current Sensor (Triaxis®Technology)
11.6 Platepol (PLATEPOL)
The polarity of the Hall plate versus the output signal is programmable by the PLATEPOL parameter.
PLATEPOL
Polarity
Positive
0
1
Negative
Please note that the factory calibration is done with PLATEPOL=0 . Melexis cannot guarantee the magnetic
specifications if this parameter is changed during customer calibration.
11.7 Sensitivity programming (ROUGHGAIN, FINEGAIN)
The sensitivity is programmable with 3 bits for ROUGHGAIN and 10 bits for FINEGAIN in analog output
application from 60 to 330 V/T (91206-High-Field version) and from 200 to 700 V/T (Low-Field version).
The FINEGAIN resolution depends on the programmed ROUGHGAIN setting. It typically ranges from
0.25V/T (ROUGHGAIN=7) up to 0.01V/T (ROUGHGAIN=0).
Different option codes correspond to different sensitivity ranges:
Ordering
Option Code
CAL-001
IMC
Version
Typical
Sensitivity
580 mV/mT
Minimum
Sensitivity
460 mV/mT
Maximum
Sensitivity
700 mV/mT
380 mV/mT
250 mV/mT
270 mV/mT
170 mV/mT
110 mV/mT
77.5 mV/mT
270mV/mT
3 %DC/mT
300 mV/mT
200 mV/mT
210 mV/mT
130 mV/mT
80 mV/mT
CAL-002
CAL-003
CAH-001
CAH-002
CAH-003
CAH-004
CAH-021
CAH-104
Low field
High field
470 mV/mT
310 mV/mT
330 mV/mT
220 mV/mT
140 mV/mT
110 mV/mT
330mV/mT
5 %DC/mT
60 mV/mT
210 mV/mT
0.5 %DC/mT
In order to have a safety margin regarding mechanical tolerances Melexis recommends designing the
application in such a way that the typical sensitivity can be used with. If the target sensitivity of the module is
out of the defined range (see table above), the hardware and software tools provided by Melexis will not be
able to properly calibrate the sensor.
Different option codes correspond to different electric gains:rderi
Ordering
Option Code
CAL-001
IMC
Version
Typical
Rough Gain
7
Electrical
Gain
Typical
Voq drift [mV]
18
Typical
Noise [mV RMS]
240
5
6
5
7
7
6
5
155
100
240
240
155
100
CAL-002
CAL-003
CAH-001
CAH-021
CAH-002
CAH-003
Low field
High field
14
9
3.5
2.5
5
18
18
14
9
5
3.5
2.5
Since noise and offset drift of the sensor are proportional to the electric gain of the sensor, Melexis
recommends using the version with the smallest gain to optimize the performances.
Note: Power consumption is 2mA less if ROUGHGAIN ≤ 3
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IMC-Hall®Current Sensor (Triaxis®Technology)
11.8 Offset / output quiescent voltage programming (XA, YA)
XA
In analog mode
12-bit register
Offset compensation before gain
@ 0 Gauss w/o offset & @Vdd=5V Vout = 6.25 * (VOQ Code) / 4096 (clipping can occur!)
Programming resolution:1.5mV per LSB over the full output range. This corresponds to a calibration
resolution of 0.03%Vdd
In PWM mode
14-bit register – digital offset VOQ
Offset compensation before gain
YA
Not used in analog mode
In PWM mode
9-bit register
Rough offset compensation (after gain)
11.9 Clamping level programming (CLAMPLOW, CLAMPHIGH)
The clamping levels limit the maximum output levels. CLAMPLOW is not used in PWM application.
The clamping levels are ratiometric (if RATIODIS = 0)
CLAMPLOW
Minimal output
[%Vdd]
0
1
2
3
4
5
6
7
4.8
5.7
6.6
7.5
8.4
9.3
10.2
11.2
Table 14: Clamping low level table analog (typical values)
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IMC-Hall®Current Sensor (Triaxis®Technology)
CLAMPHIGH
Maximal output
[%Vdd]
0
1
2
3
4
5
6
7
90.6
91.4
92.4
93.3
94.3
95.2
96.1
97
Table 15: Clamping high level analog mode (typical values).
The clamping functionality can be disabled by programming CLAMPLOW=CLAMPHIGH=7
CLAMPHIGH
Minimal output Maximal output
[%DC]
[%DC]
0
1
2
3
4
5
6
7
1
99
4
5
96
95
94
93
92
91
90
6
7
8
9
10
Table 16: Clamping low and high duty-cycle in PWM mode.
The clamping functionality can be disabled by programming CLAMPLOW=CLAMPHIGH=7.
The clamping levels calibrated during final test are:
-
-
6%Vdd (+/- 0.5%Vdd) for CLAMPING LOW
94%Vdd (+/- 0.5%Vdd) for CLAMPING HIGH
11.10 Bandwidth and filter programming (FILTCODE)
FILTCODE allows adjusting the internal bandwidth of the sensor in order to optimize for speed or resolution.
FILTCODE
Typical Bandwidth [kHz]
0
1
2
3
4
5
6
7
90 (1)
9
40
2
9
0.9
4
0.2
Table 17: FILTCODE settings analog mode
(1) Factory settings: FILTCODE = 0.
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IMC-Hall®Current Sensor (Triaxis®Technology)
FILTCODE
Cut-off frequency [Hz]
Attenuation [dB]
Tau [ms]
0.29
2
3
4
5
6
7
8
9
557
279
139
70
35
17
9
-8.0
-11.2
-14.4
-18.1
-22.4
-27.1
-32.3
-38.1
0.57
1.14
2.29
4.57
9.14
18.29
36.57
4
Table 18: FILTCODE settings PWM mode
Note:
-
-
In analog mode values above 7 are not used
In PWM mode values below 2 and above 9 are not used
11.11 Power limitation / PWM rise and fall time (OUTSLOPE)
OUTSLOPE, in the analog mode case, defines the power limit above which the output driver turns off to
prevent damages to the IC.
The power dissipated in the IC output driver is measured by the IC itself. The power is obtained by multiplying
continuously the voltage across the conducting MOS driver by the output current Iout. When the power
reaches the power limit, the output driver is switched off and on such that, on average, the measured power
is maintained equal to the power limit. The power limitation is disabled when OUTSLOPE=3.
Value
Power limitation [mW]
0
1
2
3
50
100
200
DISABLED(1)
Table 19: Output power limitation in analog mode
(1) Factory settings: OUTSLOPE = 3.
OUTSLOPE, in the PWM mode case, defines the rise and fall times of the PWM transients.
Value
Typical Rise Time
11
Typical Fall Time
14
Current Limitation [mA]
0
1
2
3
5
7
7
4
8.5
4.5
2.5
13
22
2.5
Table 20: PWM rise and fall time, Cout = 10nF, Rpullup = 4.7kOhms
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IMC-Hall®Current Sensor (Triaxis®Technology)
11.12 PWM Mode duty cycle definition (DCDEF)
The PWM duty cycle definition is as follows.
DCDEF
PWM duty cycle definition
tLow / (tLow + tHigh)
0
1
tHigh / (tLow + tHigh)
Table 21: PWM duty cycle definition
11.13 Output ratiometry (RATIODIS)
In case of analog mode (DSPMODE=0) RATIODIS allows enabling and disabling the ratiometry of the output
in reference to the supply voltage by setting respectively 0 and 1 in the EEPROM.
RATIODIS
Ratiometry
0
Enabled
1
Disabled
Please note that the factory calibration is done with RATIODIS=0 excepted for the CAH-021 version where
RATIODIS=1. Melexis cannot guarantee the magnetic specifications if this parameter is changed during
customer calibration.
11.14 Sensitivity and temperature drift programming (TC1ST, TC2ND_COLD,
TC2ND_HOT)
First order sensitivity temperature drift can be trimmed from -2000 to 2000 ppm/degC with TC1ST. The
programming resolution is 40 ppm/degC.
Second order sensitivity temperature drift can be trimmed from -6 to 6 ppm/degC2 with TC2ND. The
programming resolution is 0.4/ppm/degC2.The second order can also be seen as third order correction since
cold and hot sides are independently adjusted.
11.15 Offset temperature drift programming (OFFDRIFT_COLD, OFFDRIFT_HOT)
Offset temperature drift can be trimmed from -2.25 to +2.25 mV/degC. The programming resolution is 0.075
mV/degC. This first order correction is done independently for temperatures over 25degC and below 25degC.
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IMC-Hall®Current Sensor (Triaxis®Technology)
11.16 Product Identification (MLXID, CSTID)
MLXID
A 48-bit MLX ID is used to guarantee MLX traceability (lotnumber, wafernumber, wafer position & option
code) and is split up in 3x a 16 bit register (MLXID1, MLXID2 & MLXID3)
The programmed option code is stored in MLXID3[2..0]:
PSF Option Code (1)
Ordering Option Code (2)
MLXID3[2..0]
7
CAL-001 / CAH-001 / CAH-021
CAL-002 / CAH-002
6
5
4
CAL-003 / CAH-003
CAH-004 / CAH-104
(1) The option code mentioned in all 91206 related documentation (application notes, PSF and User
Interface) refers to the PSF Option Code.
(2) The Ordering Option Code mentioned on the page 1 of this datasheet refers to the Ordering Code,
which defines the Chip version and the sensitivity range of the sensor
CSTID
A 17-bit customer ID is available to create a dedicated traceability system
Self-diagnostic
The MLX91206 provides numerous self-diagnostic features. Those features increase the robustness of the IC
functionality as it prevents the IC to provide erroneous output signal in case of internal or external failure
modes.
Error
Action
Effect on Outputs
Remarks
Calibration Data CRC Error (at power up
and in normal working mode)
Pull down resistive load => Diag Low
Pull up resistive load => Diag High
1 ms max in high impedance followed
by settling
Fault mode
High Impedance mode (1)
Power On delay
High Impedance mode (1)
Undervoltage Mode (4)
IC is reset (7)
High Impedance mode (1) 300mV Hysteresis
Overvoltage detection Mode 1 (5)
(Threshold : min 7.9 V – max 9.5 V)
Idd < 1mA
500 to 1500mV Hysteresis
IC is switched off
(internal supply)
High Impedance mode (1)
Overvoltage detection Mode 2 (6)
(Threshold : min 6.8V – max 7.5V)
IC is reset (7)
High Impedance mode (1) 100mV Hysteresis
With some restrictions on pull-up/pull-
down resistors on OUT and TEMPOUT,
see Chap. 6 ,Table 3
With some restrictions on pull-up/pull-
down resistors on OUT, see Chap. 6 ,
Table 3
Broken Vss
IC is switched off
High Impedance (2)
High Impedance (3)
Broken Vdd
IC is switched off
Table 22: Self diagnostic
(1) Refer to Table 3: General electrical parameter, parameter High-impedance modes levels
(2) Refer to Table 3: General electrical parameter, parameter BrokenVss Output Level
(3) Refer to Table 3: General electrical parameter, parameter BrokenVdd Output Level
(4) Refer to Table 3: General electrical parameter, parameter Under-voltage detection
(5) Refer to Table 3: General electrical parameter, parameter Over-voltage detection mode 1
(6) Refer to Table 3: General electrical parameter, parameter Over-voltage detection mode 2
(7) The internal supply is regulated but the digital sequencer (hall element spinning) is stopped
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IMC-Hall®Current Sensor (Triaxis®Technology)
12 Application information
12.1 Low current measurement up to ±2 A
Low currents can be measured with the MLX91206 by
increasing the magnetic field via a coil around the sensor.
The sensitivity (output voltage vs. current in coil) of the
measurement will depend on the size of coil and number
of turns. Additional sensitivity and increased immunity to
external fields can be gained by adding a shield around
the coil. The bobbin provides very high dielectric isolation
making this a suitable solution for high voltage power
supplies with relative low currents. The output should be
scaled to obtain the maximum voltage for the highest
current to be measured in order to obtain the best
accuracy and resolution.
Figure 3: Low current application
12.2 Medium current up to ±30 A
With a single conductor located on the PCB, currents in the
range of up to 30 amps can be measured. The sizing of the
PCB trace needs to take into account the current handling
capability and the total power dissipation. The PCB trace
needs to be thick enough and wide enough to handle the
RMS current continuously.
The differential output voltage for this configuration can be
approximated by the following equation:
Vout = 35 mV/A * I
For a current level of 30 A, the output will be approximately
1050 mV.
Figure 4: Medium current application
12.3 High current measurement up to ±600 A
Another method of measuring high currents on PCB’s is to use
a large thick gauge copper trace capable of carrying the
current on the opposite side of the PCB. The MLX91206
should be located near the centre of the trace, however
because the trace is wide, the output is less sensitive to
location on the PCB. This configuration also has less
sensitivity due to the distance and width of the conductor.
Figure 5: High current application
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IMC-Hall®Current Sensor (Triaxis®Technology)
13 Recommended Application Diagrams
13.1 Resistor and capacitor values
All mentioned component values can have a ±20% tolerance
Part
C1
Description
Value
10 - 220
10 - 220
5 - 50
Unit
nF
Supply capacitor, EMI, ESD
Regulator buffer capacitor, decoupling, EMI, ESD
Decoupling, EMI, ESD
C2
nF
C3
nF
C4
R1
Decoupling, EMI, ESD
5 – 50 (1)
nF
Pull up or pull down load resistor
10 - 30
kΩ
Table 23: Resistor and capacitor value
(1) When OUTMODE=0, which we do not advice in application, capacitor C4 should be 1nF or less.
13.2 Fast analog application, pull-down resistor for diagnostic low
MODULE
ECU
Supply voltage
VDD
TEMPOUT
MLX91206
1
2
3
4
8
7
6
5
Temperature Output
C1
C2
C3
VSS
MUST0
VDIG
MUST1
TESTOUT
OUT/PWM
Analog Output
GND
C4
R1
Figure 6: Fast analog application, Pull-down resistor
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IMC-Hall®Current Sensor (Triaxis®Technology)
13.3 Fast analog application, pull-up resistor for diagnostic high
MODULE
ECU
Supply voltage
VDD
TEMPOUT
MLX91206
1
2
3
4
8
7
6
5
Temperature Output
C1
C2
C3
VSS
MUST0
R1
VDIG
MUST1
TESTOUT
OUT/PWM
Analog Output
GND
C4
Figure 7: Fast analog application, Pull-up resistor
13.4 Robust PWM application, (pull-up load only)
MODULE
ECU
Supply voltage
VDD
TEMPOUT
MLX91206
1
2
3
4
8
7
6
5
Temperature Output
C1
C2
C3
VSS
MUST0
R1
VDIG
MUST1
TESTOUT
OUT/PWM
Analog Output
GND
C4
Figure 8: Robust PWM application with pull-up resistor
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IMC-Hall®Current Sensor (Triaxis®Technology)
14 Standard information regarding manufacturability of Melexis
products with different soldering processes
Our products are classified and qualified regarding soldering technology, solderability and moisture sensitivity
level according to following test methods:
Reflow Soldering SMD’s (Surface Mount Devices)
IPC/JEDEC J-STD-020
Moisture/Reflow Sensitivity Classification for Nonhermetic Solid State Surface Mount Devices
(classification reflow profiles according to table 5-2)
EIA/JEDEC JESD22-A113
Preconditioning of Nonhermetic Surface Mount Devices Prior to Reliability Testing
(reflow profiles according to table 2)
Wave Soldering SMD’s (Surface Mount Devices) and THD’s (Through Hole Devices)
EN60749-20
Resistance of plastic- encapsulated SMD’s to combined effect of moisture and soldering heat
EIA/JEDEC JESD22-B106 and EN60749-15
Resistance to soldering temperature for through-hole mounted devices
Iron Soldering THD’s (Through Hole Devices)
EN60749-15
Resistance to soldering temperature for through-hole mounted devices
Solderability SMD’s (Surface Mount Devices) and THD’s (Through Hole Devices)
EIA/JEDEC JESD22-B102 and EN60749-21
Solderability
For all soldering technologies deviating from above mentioned standard conditions (regarding peak
temperature, temperature gradient, temperature profile etc) additional classification and qualification tests
have to be agreed upon with Melexis.
The application of Wave Soldering for SMD’s is allowed only after consulting Melexis regarding assurance of
adhesive strength between device and board.
Melexis is contributing to global environmental conservation by promoting lead free solutions. For more
information on qualifications of RoHS compliant products (RoHS = European directive on the Restriction Of
the use of certain Hazardous Substances) please visit the quality page on our website:
http://www.melexis.com/quality.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.
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16 Package Information
16.1 SOIC8 Package dimensions
1.27 TYP
NOTES:
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.
3.81
3.99** 6.20**
5.84
4.80
4.98*
1.40
1.55
0.19
0.25
1.55
1.73
0°
8°
0.127
0.250
0.41
0.89
0.35
0.49***
Figure 9: Package dimensions
16.2 SOIC8 Pinout and Marking
Marking :
Part Number MLX91206 (3 digits)
Die Version (2 digits)
8
5
L: Low field (10 mT)
H: High field (25 mT)
206 CA
123456
L
206CAL
123456
YYWW
Lot number (6 digits)
YY
WW
Week Date code (2 digits)
Year Date code (2 digits)
1
4
Figure 10: Pinout and marking
Note: the option code is not marked on the package. It can be found back in the EEPROM (see chapter
11.12) and on the tape-on-reel label information.
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IMC-Hall®Current Sensor (Triaxis®Technology)
16.3 SOIC8 Hall plate position
0.46 +/- 0.06
1.85
2.15
2.35
2.55
Figure 11: Hall Plate positioning
16.4 IMC Position and sensors active measurement direction
B extern
B extern
Figure 12: IMC position and geometry Low-Field version
B extern
B extern
Figure 13: IMC position and geometry High-Field version
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IMC-Hall®Current Sensor (Triaxis®Technology)
17 Related documents and tools
17.1 Related documents
User Interface UI MLX91206 Description
Product Specific Functions PSF MLX91206 Description
PTC-04 Daughter Board DB-HALL-03 Data Sheet
The latest version of these documents is available on the Melexis Softdist platform. Please contact your local
sales office to request an account (see contact details on page 25).
Non intrusive current sensing with MLX91206 application note
MLX91206 for PDU solutions application note
Calibrating the MLX91206/MLX91207 application note
Shielding for Triaxis current sensors application note
The latest version of these documents is available on the MLX91206 page on the Melexis website:
http://www.melexis.com/Hall-Effect-Sensor-ICs/Special-Purpose-Hall-ICs/MLX91206-755.aspx
17.2 Related software
MLX91206 Firmware
MLX91206 Product Specific Functions (PSF)
MLX91206 User Interface
MLX PTC-04 Product Specific Functions
MLX PTC-04 User Interface
The latest version of these pieces of software is available on the Melexis Softdist platform. Please contact
your local sales office to request an account (see contact details on page 25).
17.3 Related hardware
PTC-04 Programmer for Melexis PTC devices
PTC-04 Daughter Board DB-HALL-03 for MLX91206
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IMC-Hall®Current Sensor (Triaxis®Technology)
18 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 life-
support 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.
© 2012 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: sales_europe@melexis.com
America:
Phone: +1 248 306 5400
E-mail: sales_usa@melexis.com
ISO/TS 16949 and ISO14001 Certified
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相关型号:
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