Melexis MLX90366LVSADU251RX Triaxisã position sensor ic feat. sent Datasheet

MLX90366

Triaxis Position Sensor IC feat. SENT
Features and Benefits
Triaxis Hall Technology
On Chip Signal Processing for Robust Absolute Position Sensing
Simple Magnetic Design
Programmable Measurement Range
Programmable Linear Transfer Characteristic (Multi-points)
SENT output (according to SAE J2716-2010)
12 bit Resolution - 10 bit Thermal Accuracy
48 bit ID Number option
Single Die – SOIC-8 Package RoHS Compliant
Dual Die (Full Redundant) – TSSOP-16 Package RoHS Compliant
Applications
Absolute Rotary Position Sensor
Pedal Position Sensor
Throttle Position Sensor
Ride Height Position Sensor
Absolute Linear Position Sensor
Steering Wheel Position Sensor
Float-Level Sensor
Non-Contacting Potentiometer
Ordering Information1
Part No.
MLX90366
MLX90366
MLX90366
MLX90366
MLX90366
MLX90366
MLX90366
MLX90366
MLX90366
Temperature Suffix
Package 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)
L (− 40°C to + 125°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)
VS
VS
VS
VS
VS
VS
VS
VS
VS
Die Revision
ADU
ADU
ADU
ADU
ADU
ADU
ADU
ADU
ADU
Option code
250
250
250
251
251
251
253
253
253
Packing
RE
RX
SP
RE
RX
SP
RE
RX
SP
Legend:
Temperature Code:
Package Code:
Option Code:
Packing Form:
Ordering example:
1
E for Temperature Range -40°C to 85°C
K for Temperature Range -40°C to 125°C
L for Temperature Range -40°C to 150°C
VS for DMP-4 Package
AAA-123:
AAA: die version
1: IMC placement
23: Trim and form option:
•
50: Standard (straight leads) see section 20.1
•
51: Trim and Form STD1 2.54 see section 20.2
•
53: Trim and Form STD2 2.54 see section 20.3
RE for Reel (face-up)
RX for Reel (face-down)
SP for sample pack
MLX90366LVS-ADU-250-RE
See your sales representative for more details.
MLX90366
Rev 1.2
Page 1 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
1. Functional Diagram
VDIG
DSP
Reg
VX
-
VY
VZ
M
U
X
G
Rev.Pol.
&
OverVolt.
VDD
VSS
A
D
µC
R
O
M
F/W
RAM
Out (SENT)
EEP
ROM
Figure 1 - MLX 90366 Block Diagram
MLX90366
Rev 1.2
Page 2 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
2. Description
The MLX90366 Triaxis® Position Sensor Assembly is a high accuracy linear and angular position sensor
which eliminates need for inclusion of a printed circuit board (PCB) within sensing modules.
This device is based on a Dual Mold Package (DMP) construction, which integrates a Triaxis position
sensing die together with the decoupling capacitors necessary to meet the strenuous ESD and EMC
requirements. No PCB is needed.
The Triaxis position sensing die is nothing but the one used for the MLX90367 in conventional surfacemount packages (SOIC-8 – single die & TSSOP-16 – dual die).
The decoupling capacitors are X8R capacitors well suited for package integration and the target operating
temperature range.
The MLX90366 is sensitive to the three components of the flux density applied to the IC (i.e. BX, BY and
BZ). This allows the MLX90366 with the correct magnetic circuit to decode the absolute position of any
moving magnet (e.g. rotary position from 0 to 360 Degrees or linear displacement, stroke - Figure 2). It
enables the design of novel generation of non-contacting position sensors that are frequently required for
both automotive and industrial applications.
MLX90366 provides SENT Frames encoded according the Secure Sensor format.
The circuit delivers enhanced serial messages providing error codes, and user-defined values.
MLX90366 Triaxis® Position Sensor Assembly enables the realization of position sensor modules for
which a PCB is no longer needed: this yield to an increase of the electrical, mechanical and environmental
robustness of the final application.
MLX90366
Rev 1.2
Page 3 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
TABLE of CONTENTS
FEATURES AND BENEFITS ....................................................................................................................... 1
APPLICATIONS ............................................................................................................................................ 1
ORDERING INFORMATION......................................................................................................................... 1
1.
FUNCTIONAL DIAGRAM ...................................................................................................................... 2
2.
DESCRIPTION ....................................................................................................................................... 3
3.
GLOSSARY OF TERMS − ABBREVIATIONS − ACRONYMS ............................................................ 6
4.
PINOUT .................................................................................................................................................. 6
5.
ABSOLUTE MAXIMUM RATINGS ....................................................................................................... 6
6.
DESCRIPTION ....................................................................................................................................... 7
7.
MLX90366 ELECTRICAL SPECIFICATION ......................................................................................... 8
8.
MLX90366 TIMING SPECIFICATION ................................................................................................... 9
8.1.
8.2.
9.
TIMING DIAGRAMS ........................................................................................................................................ 10
APPLICATION DIAGRAM USED FOR RISE AND FALL TIME MEASUREMENT....................................................... 11
MLX90366 ACCURACY SPECIFICATION ......................................................................................... 12
10. MLX90366 MAGNETIC SPECIFICATION .......................................................................................... 13
11. MLX90366 CPU & MEMORY SPECIFICATION ................................................................................. 13
12. MLX90366 END-USER PROGRAMMABLE ITEMS ........................................................................... 14
13. SENT OUTPUT PROTOCOL .............................................................................................................. 15
13.1.
GENERALITY ............................................................................................................................................. 15
13.2.
THROTTLE POSITION / SINGLE SECURE FAST CHANNEL ............................................................................ 15
13.2.1. Frame Content...................................................................................................................................... 15
13.2.2. Diagnostic Reporting through the fast channel .................................................................................... 15
13.2.3. Pause pulse........................................................................................................................................... 16
13.2.4. Fast Channel CRC................................................................................................................................ 16
13.3.
SLOW CHANNEL ........................................................................................................................................ 16
13.3.1. Enhanced Serial Message .................................................................................................................... 16
13.3.2. Serial Message Sequence ..................................................................................................................... 17
13.3.3. Serial message sequence period ........................................................................................................... 18
13.3.4. Serial Message Error Code .................................................................................................................. 18
13.4.
START-UP .................................................................................................................................................. 19
13.5.
FIELD SENSING (A2D CONVERSIONS) AND THE FRAME SYNCHRONIZATION PULSE ................................... 19
14. DESCRIPTION OF END-USER PROGRAMMABLE ITEMS .............................................................. 20
14.1.
OUTPUT TRANSFER CHARACTERISTIC....................................................................................................... 20
14.1.1. CLOCKWISE Parameter ...................................................................................................................... 20
14.1.2. Discontinuity Point (or Zero Degree Point) ......................................................................................... 21
14.1.3. 3-Pts LNR Parameters.......................................................................................................................... 21
14.1.4. CLAMPING Parameters ...................................................................................................................... 22
14.2.
IDENTIFICATION ........................................................................................................................................ 22
14.3.
SENSOR FRONT-END ................................................................................................................................. 22
14.3.1. MAPXYZ ............................................................................................................................................... 22
14.3.2. SMISM, k and SEL_k Parameters ........................................................................................................ 23
14.3.3. GAINMIN and GAINMAX Parameters ................................................................................................ 23
14.4.
FILTER ...................................................................................................................................................... 24
MLX90366
Rev 1.2
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Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
14.5.
14.6.
DIAGNOSTIC FEATURES ............................................................................................................................ 24
EEPROM ENDURANCE ............................................................................................................................. 24
15. MLX90366 SELF DIAGNOSTIC .......................................................................................................... 25
16. BUILT-IN CAPACITORS AND RECOMMENDED APPLICATION DIAGRAMS ................................ 27
17. STANDARD INFORMATION REGARDING MANUFACTURABILITY OF MELEXIS PRODUCTS
WITH DIFFERENT LEAD PRE-FORMING AND SOLDERING/WELDING PROCESSES ....................... 27
18. ESD PRECAUTIONS ........................................................................................................................... 27
19. PACKAGE INFORMATION ................................................................................................................. 28
19.1.
19.2.
19.3.
19.4.
19.5.
DMP-4 – PACKAGE OUTLINE DIMENSIONS (POD) – STRAIGHT LEADS .................................................... 28
DMP-4 – PACKAGE OUTLINE DIMENSIONS (POD) – TRIMMED & FORMED LEADS [1] ............................. 29
DMP-4 – PACKAGE OUTLINE DIMENSIONS (POD) – TRIMMED & FORMED LEADS [2] ............................. 30
DMP-4 - MARKING ................................................................................................................................... 31
DMP-4 - SENSITIVE SPOT POSITIONING & SENSE DIRECTION ................................................................... 32
20. DISCLAIMER ....................................................................................................................................... 34
REVISIONS ................................................................................................................................................. 35
MLX90366
Rev 1.2
Page 5 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
3. Glossary of Terms − Abbreviations − Acronyms
Gauss (G), Tesla (T): Units for the magnetic flux density − 1 mT = 10 G
TC: Temperature Coefficient (in ppm/Deg.C.)
NC: Not Connected
SENT: Single Edge Nibble Transmission
ADC: Analog-to-Digital Converter
LSB: Least Significant Bit
MSB: Most Significant Bit
DNL: Differential Non-Linearity
INL: Integral Non-Linearity
RISC: Reduced Instruction Set Computer
ASP: Analog Signal Processing
DSP: Digital Signal Processing
CoRDiC: Coordinate Rotation Digital Computer (i.e. iterative rectangular-to-polar transform)
EMC: Electro-Magnetic Compatibility
4. Pinout
Pin #
1
VSS (Ground)
2
VDD
3
OUT
4
VSS (Ground)
5. Absolute Maximum Ratings
Parameter
Value
Supply Voltage, VDD (overvoltage)
+ 24 V
Reverse Voltage Protection
− 12 V (breakdown at -14 V)
Positive Output Voltage
+ 18 V (breakdown at 24 V)
Output Current (IOUT)
+ 30 mA (in breakdown)
Reverse Output Voltage
− 0.3 V
Reverse Output Current
− 50 mA (in breakdown)
Operating Ambient Temperature Range, TA
− 40°C … + 150°C
Storage Temperature Range, TS
− 40°C … + 150°C
Magnetic Flux Density
±1T
Exceeding the absolute maximum ratings may cause permanent damage.
maximum rated conditions for extended periods may affect device reliability.
MLX90366
Rev 1.2
Page 6 of 34
Exposure to absolute
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
6. Description
As described on the block diagram the three vector components of the magnetic flux density (BX, BY and
BZ) applied to the IC are sensed through the sensor front-end. The respective Hall signals (VX, VY and VZ)
are generated at the Hall plates and amplified.
The analog signal processing is based on a fully differential analog chain featuring the classic offset
cancellation technique (Hall plate 2-Phases spinning and chopper-stabilized amplifier).
The conditioned analog signals are converted through an ADC (15 bits) and provided to a DSP block for
further processing. The DSP stage is based on a 16 bit RISC micro-controller whose primary function is
the extraction of the position from two (out of three) raw signals (after so-called front-end compensation
steps) through the following function:
α = ∠(V1 , k ⋅V2 )
where alpha is the magnetic angle <(B1, B2), V1 = VX or VY or VZ , V2 = VX or VY or VZ and k is a
programmable factor to match the amplitude of V1 and k V2.
The DSP functionality is governed by the micro-code (firmware − F/W) of the micro-controller which is
stored into the ROM (mask programmable). In addition to the magnetic angle extraction, the F/W controls
the whole analog chain, the output transfer characteristic, the output protocol, the programming/calibration
and also the self-diagnostic modes.
The magnetic angular information is intrinsically self-compensated vs. flux density variations. This feature
allows therefore an improved thermal accuracy vs position sensor based on conventional linear Hall
sensors.
In addition to the improved thermal accuracy, the realized position sensor features excellent linearity
performances taking into account typical manufacturing tolerances (e.g. relative placement between the
Hall IC and the magnet).
Once the position (angular or linear stroke) information is computed, it is further conditioned (mapped) vs.
the target transfer characteristic and it is provided at the output(s) as SENT output.
The linear part of the transfer curve can be adjusted through a multi-point calibration:
This back-end step consists in a Piece-Wise-Linear (PWL) output transfer characteristics – 3 reference
points & 4 slopes w/ programmable origin.
The calibration parameters are stored in EEPROM featuring a Hamming Error Correction Coding (ECC).
The programming steps do not require any dedicated pins. The operation is done using the supply and
output nodes of the IC. The programming of the MLX90366 is handled at both engineering lab and
production line levels by the Melexis Programming Unit PTC-04 with the dedicated MLX90366
daughterboard and MLX90366 software tools (DLL − User Interface).
MLX90366
Rev 1.2
Page 7 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
7. MLX90366 Electrical Specification
DC Operating Parameters at Nominal supply voltage (unless otherwise specified) and for TA as specified
by the Temperature suffix (E or K or L).
Parameter
Symbol
Test Conditions
Min
Typ
Max
Units
4.5
5
5.5
V
Nominal Supply Voltage
VDD
Supply
Current(
Idd
10
mA
Isurge
Current(2)
Isurge
20
mA
Power-On reset ( rising )
HPOR_LH
2.5
V
Power-On reset Hysteresis
HPOR_Hyst
50
200
mV
Start-up Level ( rising )
MT4V LH
3.8
4.2
V
Start-up Hysteresis
MT4V Hyst
50
200
mV
PTC Entry Level ( rising )
MT7V_LH
5.8
6.6
V
MT7V_Hyst
50
200
mV
15
15
18
mA
mA
mA
∞
∞
kΩ
kΩ
PTC Entry Level Hysteresis
Refer to internal voltage Vdig
Output Short Circuit Current
Ishort
Vout = 0 V
Vout = 5 V
Vout = 18 V (TA = 25°C)
Output Load
RL
Pull-down to Ground
Pull-up to 5V
Active Diagnostic Output Level
Digital Saturation Output Level
Passive Diagnostic Output
Level
(Broken Track Diagnostic) (3)
Digital output Ron
Dsat_lo
2
4.7
4.7
4.0
6.2
10
10
0.5
2
Pull-up load RL ≥ 10 kΩ to 5 V
Pull-up load RL ≥ 5 kΩ to 18V
Pull-down load RL ≥ 5 kΩ
Pull-down load RL ≥ 10 kΩ
95
97.5
BVSSPD
Broken VSS &
Pull-down load RL ≥ 10 kΩ
97.5
BVSSPU
Broken VSS &
Pull-up load RL ≥ 4.7kΩ
99.5
BVDDPD
Broken VDD &
Pull-down load RL ≥ 4.7kΩ
BVDDPU
Broken VDD &
Pull-up load RL ≥ 5kΩ
Ron
Diag_low
Diag_hi
Dsat_hi
2.25
2
3
97
98.5
%VDD
%VDD
100
0
15
120
%VDD
%VDD
0.5
%VDD
2
%VDD
30
300
Ohms
The specified value is valid during early start-up time only; the current might dynamically exceed the specified value, shortly,
during the Start-up phase.
3 The SENT output signal will no longer be reported. For detailed information, see also section 15.
2
MLX90366
Rev 1.2
Page 8 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
8. MLX90366 Timing Specification
DC Operating Parameters at Nominal supply voltage (unless otherwise specified) and for TA as specified
by the Temperature suffix (L).
Parameter
Main Clock Frequency
Main Clock Frequency Thermal
Drift
Symbol
Test Conditions
Min
Typ
Max
Ck
All contributors (trimming accuracy,
supply voltage, thermal and ageing)
12.6
13.3
14
MHz
± 3%
CkNOM
∆TCk
Tick time
Default EEPROM setting
Low pulse tick count
SENT Frame Period
tframe
Exact value for Ck = 13.3 MHz
The typical value will be affected
by any variation of the clock
4
Units
3
µs
5
ticks
882
µs
441
µs
Internal Angle Measurement
Period
tper
First Angle Measurement to
Sync Pulse latency
ta1
1084
µs
Second Angle Measurement to
Sync Pulse latency
ta2
643
µs
Field Change to SENT Data :
Average Latency
Latency
SENT Frame Tick Count
Watchdog
twd
Start-up Time (up to first sync
pulse)
tsu1
Start-up Time (up to first data
received)
tsu2
FILTER = 1 (recommended)
SENT Transmission Included
1745
1745
Default EEPROM setting
294
294
114.5
118
121.5
1.8
Last pause pulse not included
Serial Message
Extended sequence ( 40 frames )
Short sequence ( 24 frames )
Rise Time @ Cable
Thresholds : 0.5V and 4.5V
See section 9.2
5.9
µs
ms
ms
6.3
35.28
21.168
ms
ms
µs
2.97
5.31
Rise Time @ Receiver
5.07
6.84
µs
Fall Time @ Cable
2.65
2.82
µs
Fall Time @ Receiver
4.84
4.9
µs
MLX90366
Rev 1.2
Page 9 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
8.1. Timing diagrams
Figure 7 – Start-up phase timings
latency
ta1
half
Field Component
Sensing
B1
half
B2
tframe
ta2
B1
B2
B1
B2
B1
B2
B1
B2
B1
Field Average & angle calculation
Pause
Sync
Data
Pause
Sync
Data
Pause
Sync
SENT Signal
Figure 8a – Latencies (acquisition to output delays) – FILTER = 1 (recommended)
Field Component
Sensing
B1
B2
B1
B2
B1
B2
B1
B2
B1
B2
B1
angle calculation
Pause
Sync
Data
Pause
Sync
Data
Pause
Sync
SENT Signal
Figure 8b – Latency - Case FILTER = 0 (not recommended)
Field Component
Sensing
B1
B2
B1
B2
B1
B2
B1
B2
B1
B2
B1
Field Average & angle calculation
Pause
Sync
Data
Pause
Sync
Data
Pause
Sync
SENT Signal
Figure 8C – Latency - Case FILTER = 2
MLX90366
Rev 1.2
Page 10 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
8.2. Application diagram used for rise and fall time measurement
Figure 9 –Schematic used for rise and fall time measurements (ref: J2716 Rev Jan 2010 Fig. 6.3.4)
Compoment
C01
C02
R01
Cinput
CTau
Cf
RTau
Rf
RPU
RV
Value
10 ± 25% (internal in DMP)
not mounted
not mounted
68
2.2
100
568
10
14.7
not mounted
Unit
nF
nF
Ohms
pF
nF
pF
Ohms
kOhms
kOhms
Ohms
Component values used for rise and fall time measurements (ref: J2716 Rev Jan 2010 Fig. 6.3.4)
MLX90366
Rev 1.2
Page 11 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
9. MLX90366 Accuracy Specification
DC Operating Parameters at VDD = 5V (unless otherwise specified) and for TA as specified by the
Temperature suffix (E or K or L).
Parameter
Symbol
ADC Resolution on the raw
signals sine and cosine(4)
Thermal Offset Drift #1(5)
at the DSP input (excl. DAC and
output stage)
RADC
Magnetic Angle phase error
Min
TA = 25°C – XY axis
TA = 25°C – XZ axis
TA = 25°C – YZ axis
XY axis, XZ (YZ) axis
-60
-60
-90
- 0.3
- 0.5
-1
-1
-0.3
-2
-2
TA = 25°C – factory trim. “SMISM”
Le
TA = 25°C – “k” trimmed for XZ
-2.5
YZ - Intrinsic Lin. Error(11)
Le
TA = 25°C – “k” trimmed for YZ
FILTER = 0, 40mT
FILTER = 1 (recommended) , 30mT
FILTER = 2, 20mT
-2.5
Units
bits
+60
+60
+90
+ 0.3
+ 0.5
+1
+1
0.3
2
2
-1
Le
Noise pk-pk(8)
Max
0.01
Error(11)
XZ - Intrinsic Lin.
Typ
15
Temperature suffix E
Temperature suffix K
Temperature suffix L
XY axis – Temp. suffix E
XY axis – Temp.suffix K & L
XZ (YZ) axis – Temp. suffix E
XZ (YZ) axis – Temp. suffix K & L
Thermal Drift of Sensitivity
Mismatch(6)
Thermal Drift of Magnetic Angle
phase error
XY – Intrinsic Linearity Error(7)
Test Conditions
LSB15
%
Deg.
Deg.
1
Deg
±1.25
2.5
Deg
±1.25
0.10
0.10
0.1
2.5
Deg
0.2
0.2
0.2
Deg
4
16 bits corresponds to 15 bits + sign. Internal computation is performed using 16 bits.
instance, in case of a rotary position sensor application, Thermal Offset Drift #1 equal ± 60LSB15 yields to max. ± 0.3 Deg.
angular error for the computed angular information (output of the DSP). This is only valid if k = 1. “MLX90365 Front-End
Application Note” will be released for more details.
6
For instance, in case of a rotary position sensor application, Thermal Drift of Sensitivity Mismatch equal ± 0.5% yields to max. ±
0.15 Deg. angular error for the computed angular information (output of the DSP). See “MLX90365 Front-End Application Note”
for more details.
7
The Intrinsic Linearity Error refers to the IC itself (offset, sensitivity mismatch, orthogonality) taking into account an ideal rotating
field for BX and BY. Once associated to a practical magnetic construction and the associated mechanical and magnetic
tolerances, the output linearity error increases. However, it can be improved with the multi-point end-user calibration. The intrinsic
Linearity Error for Magnetic angle ∠XZ and ∠YZ can be reduced through the programming of the k factor.
8
Noise pk-pk (peak-to-peak) is here intended as 6 times the Noise standard Deviation. The application diagram used is
described in the recommended wiring. For detailed information, refer to section Filter in application mode (Section 14.4).
5 For
MLX90366
Rev 1.2
Page 12 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
10.
MLX90366 Magnetic Specification
DC Operating Parameters at VDD = 5V (unless otherwise specified) and for TA as specified by the
Temperature suffix (E or K or L).
Parameter
Symbol
BX, BY(9)
Test Conditions
Min
GainIMC
1.15
Magnet Temperature Coefficient
TCm
-2400
126
BZ(11)
Norm
Max
√[ BX + BY +
2
Units
70(10) mT
√[ BX 2 + BY 2 ]
Magnetic Flux Density
Magnetic Flux Density
Magnetic Flux Norm
IMC Gain(12)
11.
Typ
2
(Bz/1.2)2
]
20(12)
1.3
mT
mT
1.4
0
ppm/°C
MLX90366 CPU & Memory Specification
The DSP is based on a 16 bit RISC µController. This CPU provides 2.5 Mips while running at 10 MHz.
Parameter
Symbol
Test Conditions
Min
Typ
Max
Units
ROM
10
kB
RAM
384
B
EEPROM
128
B
9
The condition must be fulfilled for at least one field BX or BY.
Above 70 mT, the IMC starts saturating yielding to an increase of the linearity error.
11
Below 20 mT, the performances slightly degrade due to a reduction of the signal-to-noise ratio, signal-to-offset ratio.
12
This is the magnetic gain linked to the Integrated Magneto Concentrator (IMC) structure. It applies to BX and BY and not to BZ.
This is the overall variation. Within one lot, the part to part variation is typically ± 10% versus the average value of the IMC gain
of that lot
10
MLX90366
Rev 1.2
Page 13 of 34
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
12.
MLX90366 End-User Programmable Items
Parameter
Comments
Standard
Comments
MAPXYZ
CLAMP_HIGH
CLAMP_LOW
SMISM
K
Sel_K
GAINMIN
GAINMAX
GAINSATURATION
DP
CW
MELEXISID1
MELEXISID2
MELEXISID3
LNR_Ax, LNR_Ay, LNR_As
LNR_Bx, LNR_By, LNR_Bs
LNR_Cx, LNR_Cy, LNR_Cs
DIAG Settings
CRC_DISABLE
SERIALERROR
FILTER
SERIAL_X1
SERIAL_X2
SERIAL_Y1
SERIAL_Y2
EE_SENT_SERIAL
EE_SERIAL_OEM#1
EE_SERIAL_OEM#2
EE_SERIAL_OEM#8
EE_SENT Man Code
EE_SENT Sensor Type
EE_User ID1
EE_User ID2
EE_User ID3
EE_SENSOR ID#1
EE_SENSOR ID#2
EE_SENSOR ID#3
EE_SENSOR ID#4
SENT_Dis_Serialmessage
SENT_Dis_PausePulse
SENT_CRC2007
SENT_DATA MODE
Memlock
Mapping fields for output angle
Clamping High (50%)
Clamping Low (50%)
Sensitivity mismatch factor X,Y
Sensitivity mismatch factor X (Y) , Z
Location for for K – correction
Low threshold for virtual gain
High threshold for virtual gain
Gain Saturates on GAINMIX and GAINMAX
Discontinuity point
Clock Wise
Melexis identification reference
Melexis identification reference
Melexis identification reference
Coordinate For point A
Coordinate For point B
Coordinate For point C
16 Bit Diagnostics enabling
Enable EEPROM CRC check ( 3131h= disable)
Diagnostic reporting through fast channel
FIR Filter
Serial Message
Serial Message
Serial Message
Serial Message
Serial Message
Serial Message
Serial Message
Serial Message
Serial Message
Serial Message
Cust identification reference : Default = Bin1
Cust identification reference : Default Rev nr
Cust identification reference ; Default Sens.
Serial Message
Serial Message
Serial Message
Serial Message
Disable Serial message
Disable pause pulse
Enable CRC calculation according SAE2007
Select SENT DATA Channel nibble order
EEprom memory lock
0
0%
100%
MLX
MLX
0
00h
28h
0h
0h
0h
MLX
MLX
MLX
Tbd
Tbd
Tbd
FDFFh
0h
0
0
0
0
0
0
0
0
0
0
0
0
1
305h
MLX
0
0
0
0
0
0
0
0
2
16
16
15
15
1
8
8
1
15
1
16
16
16
16
16
16
16
16
2
2
12
12
12
12
12
12
12
12
12
12
16
16
16
12
12
12
12
1
1
1
1
2
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Triaxis Position Sensor IC feat. SENT
13.
SENT output Protocol
13.1. Generality
The MLX90366 complies with the sub-set of the norm J2716 Revised JAN2010, “A.1 A.1 Throttle
Position” or “A.3 Single Secure Sensors”
13.2. Throttle position / Single Secure Fast Channel
MLX90366 delivers SENT frames according the Throttle position or Single Secure format.
This format is explicitly described in this section.
13.2.1. Frame Content
The 90366 SENT frames have 6 data nibbles, and are formatted according the below table
Single Secure
SENT Frame :
Nibble 0
Nibble 1
Nibble 2
Nibble 3
Nibble 4
Nibble 5
Nibble 6
Nibble 7
Status
CH1-MSN
CH1-MidN
CH1-LSN
RC-MSN
RC-LSN
CCH1-MSN
CRC
optional error code
F
F
Status[0]
Channel 1 indicator ( "1" = error, "0" otherwise )
Status[1]
0
Status[2]
Enhanced Serial Message ( dissable option)
Status[3]
Enhanced Serial Message ( dissable option)
CRC
Enhanced CRC (the legacy CRC is optional)
Ch1
12 bit angle
RC
8 bit rolling counter
CCH1
Inverted Copy Ch1
8+EE_REPORT
Optional Pause
0
Throttle position
SENT Frame :
Nibble 0
Nibble 1
Nibble 2
Nibble 3
Nibble 4
Nibble 5
Nibble 6
Nibble 7
Status
CH1-MSN
CH1-MidN
CH1-LSN
CH2-LSN
CH2-MidN
CH2-MSN
CRC
optional error code
F
F
Status[0]
Channel 1 indicator ( "1" = error, "0" otherwise )
Status[1]
Channel 2 indicator ( "1" = error, "0" otherwise )
Status[2]
Enhanced Serial Message ( dissable option)
Status[3]
Enhanced Serial Message ( dissable option)
8+EE_REPORT
CRC
Enhanced CRC (the legacy CRC is optional)
Ch1
12 bit angle
Ch2
12 bit angle = Inverted CH1 ( optional : FFF-CH1 or FF9-CH1 )
F
F
8+EE_REPORT
13.2.2. Diagnostic Reporting through the fast channel
13.2.2.1. Diagnostic Reporting, bit Status[0]
The bit Status[0] is high whenever the three following conditions are met:
1. A diagnostic (analog/environmental) detects an error *
2. The reporting of the above error is enabled **
3. The debouncing time has elapsed.
* A diagnostic of type digital cause the circuit to switch in fail-safe-mode
** See EEPROM bits EE_DIAG_SETTINGS
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Optional Pause
MLX90366

Triaxis Position Sensor IC feat. SENT
13.2.2.2. Diagnostic Reporting, Channel 1
The diagnostic can be reported through the 12 bit payload of channel 1, and not only through the status
bit Status[0].
The EEPROM parameters SERIALERROR controls the diagnostic reporting through channel 1 as follow:
If SERIALERROR =0, the channel 1 reports the angle, and not the diagnostic, as if no diagnostic.
The error is reported only thanks to the Status bits.
If SERIALERROR >0, the channel1 payload contains the value Channel1 = (4088 + SERIALERROR])
13.2.2.3. Diagnostic Reporting Time
The Diagnostic Reporting Time is programmable (defined as multiple of a macro-cycle unit time).
A macro-cycle is a sequence of 20 angle acquisitions, and has a duration of approximately 6 ms.
13.2.2.4. Diagnostic Debouncing
The Diagnostic Reporting is Debounced. The debouncing paramater are user-programmable, by steps of
approximately 6 ms.
13.2.3. Pause pulse
A pause pulse, as defined by the standard, is present at the end of every frame.
The pause pulse mode can be disabled.
The pause pulse lenght is adjusted by the circuit so that the frame period is constant.
The field sensing and the frame synchro pulse are in sync.
13.2.4. Fast Channel CRC
The 90366 features the new recommended implementation and optional the legacy implementation
13.3. Slow Channel
13.3.1. Enhanced Serial Message
The circuit encodes the slow messages according the Enhanced Serial Message Format as specified at
Chapter 5.2.4.3 of the SENT norm, except for the following restriction:
The configuration bit is always 0, meaning that the payload consists in 12-bit data and 8-bit message ID.
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Triaxis Position Sensor IC feat. SENT
13.3.2. Serial Message Sequence
The circuit complies with the following sub-set specifications of the norm for pressure sensors
(The norm for the angular sensor case does not specify the serial message format)
#
8bit ID
12 bit data
Comments
Item
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
01
06
01
05
01
03
01
07
01
08
01
09
01
0A
01
23
01
29
01
2A
01
2B
01
2C
25
26
27
28
29
30
31
32
33
34
01
90
01
91
01
92
01
93
01
94
Diagnostic Error Codes
OEM Code #1
Diagnostic Error Codes
OEM Code #2
Diagnostic Error Codes
OEM Code #3
Diagnostic Error Codes
OEM Code #4
Diagnostic Error Codes
OEM Code #5
RAM
Prog.
RAM
Prog.
RAM
Prog.
RAM
Prog.
RAM
Prog.
35
36
01
95
Diagnostic Error Codes
OEM Code #6
RAM
Prog.
EE_SENT OEM CODE6
37
38
01
96
Diagnostic Error Codes
OEM Code #7
RAM
Prog.
EE_SENT OEM CODE7
Diagnostic Error Codes
OEM Code #8
RAM
Prog.
EE_SENT OEM CODE8
39
40
01
97
RAM
Diagnostic Error Codes
Prog.
SENT standard revision
RAM
Diagnostic Error Codes
Prog.
Manufacturer code
RAM
Diagnostic Error Codes
Prog.
Channel 1 / 2 Sensor type
RAM
Diagnostic Error Codes
Prog.
Fast channel 1 -X1
RAM
Diagnostic Error Codes
Prog.
Fast channel 1 -X2
RAM
Diagnostic Error Codes
Prog.
Fast channel 1 -Y1
RAM
Diagnostic Error Codes
Prog.
Fast channel 1 -Y2
RAM
Diagnostic Error Codes
RAM
TEMP Sensor
RAM
Diagnostic Error Codes
Prog.
Sensor ID #1
RAM
Diagnostic Error Codes
Prog.
Sensor ID #2
RAM
Diagnostic Error Codes
Prog.
Sensor ID #3
RAM
Diagnostic Error Codes
Prog.
Sensor ID #4
Optional Part ( EE_ExtendedSequence = 1 )
Described at next chapter
EE_SENT rev
EE_SENT Man Code
EE_SENT Sensor type
EE_SENTChannel X1
EE_SENTChannel X2
EE_SENTChannel Y1
EE_SENTChannel Y2
EE_SENT Sensor ID1
EE_SENT Sensor ID2
EE_SENT Sensor ID3
EE_SENT Sensor ID4
Described at next chapter
EE_SENT OEM CODE1
EE_SENT OEM CODE2
EE_SENT OEM CODE3
EE_SENT OEM CODE4
EE_SENT OEM CODE5
Table. Serial Message Sequence
MLX90366
Rev 1.2
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
Triaxis Position Sensor IC feat. SENT
The first part (positions 1 to 24) provides the Error Code and the Sensor ID alternatively.
The second part (positions 24 to 40) is optional as a whole enabled with EEPROM bit
EE_ExtendedSequence.
This second part consists of the error code (8 occurences), 8 OEM -defined Code
The temperature can be derived from SENT ID 23, TEMP sensor, with the following equation:
SENT@ ID 23 = 8 * (T[C] – 35[C]) + 865 lsb12
The accuracy of the actual Temperature is = ± 10 DegC.
13.3.3. Serial message sequence period
Sequence Length
(serial message count)
Sequence Length
(frame count)
Sequence Period
(ms, typical)
24
432
381
40
720
635
13.3.3.1. Error Code Rate
The Error Code are on purpose transmitted every second message, to maximize the rate, which equals
then 36 SENT frames.
13.3.4. Serial Message Error Code
The list of error and status messages transmitted in the 12-bit Enhanced Serial Message data field when
Enhance Serial Message ID is $01 is given in the following Table.
12 Bit Data
Diagnostic
$000
No error
$801
GainOOS
Comments
Front-end Gain code Out-of-spec (too low, too high)
$808
ADCSatura
Diag
$810
ADCMonitor
ADC monitor
$820
VanaMoni
Analog Internal Supply Too Low
$840
VddMoni
External Supply Too Low
$880
Rough Offset
Front-end Rough Offset too low, too high
$900
TempMonitor
Temperature Sensor monitor
In case multiple errors occur, then the resulting 12 bit enhanced serial message data will be the OR-operation of the
individual data values. Example $809 = GainOOS + ADCsatura
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Rev 1.2
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Triaxis Position Sensor IC feat. SENT
13.4. Start-up
During the chip initialization, the output remains high until the circuit emits four initialization frames (all 6
data nibble zero). The fifth frame is not an initialization frame but a valid frame containing a measured
angle. See also section 9 “Timing specifications”.
13.5. Field sensing (A2D conversions) and the frame Synchronization pulse
By default setting of the Timer period and Filter =1 , the digital angle (fast channel payload) results of the
average of two angles.
These angles are themselves computed from 4 ADCs values.
The time between the ADCs and the frame synchronization pulse is constant.
As a result, the phase delay between the magnetic field angle and the SENT synchronization pulse is
constant, allowing filtering at the ECU side.
See also section 8 “Timing specifications”.
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14.
Description of End-User Programmable Items
14.1. Output Transfer Characteristic
To define the transfer function (LNR):
Parameter
Value
Unit
CounterClockWise
1
ClockWise
LSB
DP
0 … 359.9999
deg
LNR_A_X
LNR_B_X
LNR_C_X
0 … 359.9999
deg
LNR_A_Y
LNR_B_Y
LNR_C_Y
0 … 100
%
LNR_S0
LNR_A_S
LNR_B_S
LNR_C_S
-17… 0 … 17
%/deg
CLAMP_LOW
0 … 100
%
CLAMP_HIGH
0 … 100
%
CLOCKWISE
0
14.1.1. CLOCKWISE Parameter
The CLOCKWISE parameter defines the magnet rotation direction.
•
•
CCW is the defined by the 1-4-5-8 pin order direction for the SOIC8 package and 1-8-9-16 pin
order direction for the TSSOP16 package.
CW is defined by the reverse direction: 8-5-4-1 pin order direction for the SOIC8 and 16-9-8-1 pin
order direction for the TSSOP16 package.
Refer to the drawing in the sensitive spot positioning sections (Section 19.5)
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14.1.2. Discontinuity Point (or Zero Degree Point)
The Discontinuity Point defines the 0° point on the circle. The discontinuity point places the origin at any
location of the trigonometric circle. The DP is used as reference for all the angular measurements.
360°
0°
The placement of the discontinuity
point (0 point) is programmable.
Figure 10 - Discontinuity Point Positioning
14.1.3. 3-Pts LNR Parameters
The LNR parameters, together with the clamping values, fully define the relation (the transfer function)
between the digital angle and the output signal.
The shape of the MLX90366 transfer function from the digital angle value to the output voltage is
described by the drawing below. Six segments can be programmed but the clamping levels are
necessarily flat.
Two, three, or even five calibration points are then available, reducing the overall non-linearity of the IC by
almost an order of magnitude each time. Three or five point calibration will be preferred by customers
looking for excellent non-linearity figures. Two-point calibrations will be preferred by customers looking for
a cheaper calibration set-up and shorter calibration time.
4095
Clamping
High
CLAMPHIGH
C
Slope
LNR_C_S
LNR_C_Y
B
Slope
LNR_B_S
LNR_B_Y
A
Slope
LNR_A_S
LNR_A_Y
Slope
LNR_S0
Clamping
Low
CLAMPLOW
0
0
MLX90366
Rev 1.2
LNR_A_X
LNR_B_X
Page 21 of 34
LNR_C_X
360
(Deg.)
Datasheet
09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
14.1.4. CLAMPING Parameters
The clamping levels are two independent values to limit the output voltage range. The CLAMPLOW
parameter adjusts the minimum output code. The CLAMPHIGH parameter sets the maximum output
code. Both parameters have 16 bits of adjustment and are available for both LNR modes.
14.2. Identification
Parameter
Value
MELEXISID1
MELEXISID2
MELEXISID3
CUSTOMERID1
CUSTOMERID2
CUSTOMERID3
0 … 65535
0 … 65535
0 … 65535
0 … 65535
0 … 65535
0 … 65535
Identification number: 48 bits (3 words) freely useable by Customer for traceability purpose.
14.3. Sensor Front-End
Parameter
Value
MAPXYZ
0 .. 3
SMISM
0 .. 32768
K
0 .. 32768
SEL_k
0 or 1
GAINMIN
GAINMAX
GAINSATURATION
0 … 41
0 … 41
0.. 1
14.3.1. MAPXYZ
The MAPXYZ parameter defines which fields are used to calculate the angle. The different possibilities
are described in the tables below.
This 2 bits value selects the first (B1) and second (B2) field components according the table below.
MAPXYZ
0 – 00b
1 – 01b
2 – 10b
3 – 11b
B1
X
Zx
Y
Y
B2
Y
X
Zx
Zy
Angular
XY mode
XZx mode
YZx mode
YZy mode
MAPXYZ = 3 is not recommended.
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Rev 1.2
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Triaxis Position Sensor IC feat. SENT
14.3.2. SMISM, k and SEL_k Parameters
(i) SMISM
When the mapping (B1=X, B2=Y) is selected, SMSIM defines the sensitivity mismatch factor that is
applied on B1, B2; When another B1, B2 mapping is selected, this parameter is “don’t care”.
This parameter is trimmed at factory; Melexis strongly recommends TO NOT overwrite it for optimal
performances.
(ii) k
When the mapping (B1=X, B2=Y) is NOT selected, k defines the sensitivity mismatch factor that is applied
on B1or B2 (according to parameter SEL_k – see below). When the mapping (B1=X, B2=Y) is selected,
this parameter is “don’t care”.
This parameter is trimmed at factory for mapping (B1=Z, B2=X). Melexis recommends to fine trim it when
a smaller linearity error (Le) is required and a different mapping than (B1=X, B2=Y) is selected.
(iii) SEL_k
When the mapping (B1=X, B2=Y) is NOT selected, SEL_k defines the component on which the sensitivity
mismatch factor k (see above): SEL_k = 0 means B1→ k ⋅ B1 and SEL_k = 1 means B2 → k ⋅ B2.
14.3.3. GAINMIN and GAINMAX Parameters
GAINMIN and GAINMAX define the thresholds on the gain code outside which the fault “GAIN out of
Spec.” is set;
If GAINSATURATION is set, then the virtual gain code is saturated at GAINMIN and GAINMAX, and no
Diagnostic fault is set since the saturations applies before the Diag. check.
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14.4. Filter
Parameter
Value
FILTER
0, 1, 2
The MLX90366 features a filter that is enabled when FILTER = 1 or 2.
The filter is of type “moving average”. It averages the two most recent internal angle values in case
FILTER=1 and the four most recent internal angle values in case FILTER=1
When the filter is enabled, the SENT data holds the average of the two or 4 most recent internal angles.
We recommend to enable the filter, in order to benefit from a noise reduction of 30% compared to the
case FILTER = 0. Given that two angle values are computed per each SENT frame, the latency increases
in this case only marginally.
Filter = 0 corresponds to no filtering, and may be selected to optimize the latency (by about 10%),
whenever the latter is system-critical (e.g. stability of a close-loop system).
14.5. Diagnostic Features
Refer to Application_note_Diagnostic_Behavior_90366 for EE_CRC_Enable function description and for
Diagnostic features which can be enabled at user.
14.6. EEPROM endurance
Although the EEPROM is used for Calibration Data Storage (similarly to an OTPROM), the MLX90366
embedded EEPROM is qualified to guarantee an endurance of minimum 1000 write cycles at 125˚C for
(engineering/calibration purpose).
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Rev 1.2
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Triaxis Position Sensor IC feat. SENT
15.
MLX90366 Self Diagnostic
The MLX90366 provides numerous self-diagnostic features. Those features increase potentially the
functional safety of safety-related systems as it reduces the risk of erroneous angle reporting in case of
internal or external failure modes (“fail-safe”).
Diagnostic Item
Start-up phase Diagnostics
Action
Effect on Output
Type
Monitoring Rate
Reporting Rate
Fail-safe mode **
** CPU reset after 120ms
Fail-safe mode **
** CPU reset after 120ms
Start-up on Hold **
** CPU reset after 120ms
Diagnostic low/ high
Reporting (optional)
Diagnostic low/ high
Reporting (optional)
Diagnostic low/high
Digi HW
n/applicable (startup only)
n/applicable (startup only)
n/applicable (startup only)
n/applicable (start-up only)
PTC entry
Output in HighImpedance
Environ
n/applicable (startup only)
n/applicable (start-up only)
Fail-safe mode **
** CPU reset after 120ms
Fail-safe mode **
** CPU reset after 120ms
CPU reset
Diagnostic low//high
Reporting (optional)
Diagnostic low/high
Reporting (optional)
--
Digi HW
800ms
800ms
Digi HW
10ms
10ms
Digi HW
120ms
n/a
Debouncing (programmable
SENT Status bit0 = 1
(optional)
Environ
&Analog
5/DSP
Debouncing (programmable)
SENT Status bit0 = 1
(optional)
Environ
&Analog
1/DSP
Saturation (optional)
Gain Saturated @
GAINMIN-GAINMAX
Environ
&Analog
n/applicable
Not a diagnostic
Debouncing (programmable)
SENT Status bit0 = 1
(optional)
Analog
HW
1/DSP
Supply Debouncing
(programmable)
SENT Status bit0 = 1
(optional)
Environ
&Analog
1/DSP
PTC entry after PTC
Debouncing
Output in HighImpedance
Environ
2ms
6ms
x
Diag_Debounce_Thresh
Diag_Debounce_Stepup
6ms
x
Diag_Debounce_Thresh
Diag_Debounce_Stepup
n/applicable
Not a diagnostic
6ms
x
Diag_Debounce_Thresh
Diag_Debounce_Stepup
6ms
x
Diag_Debounce_Thresh
Diag_Debounce_Stepup
2ms
Debouncing (programmable)
SENT Status bit0 = 1
(optional)
Analog
1/DSP
Saturate value used for the
No effect
Temperature > 170degC (± 20)
compensation to -40degC and
Temperature < -60degC (± 20)
+150degC resp.
Hardware Diagnostics ( continuously checked by dedicated Logic )
Read/Write Access out of
Fail-safe mode **
Diagnostic Low/High
physical memory
** CPU reset after 120ms
Write Access to protected area
Fail-safe mode **
Diagnostic low/high
(IO and RAM Words)
** CPU reset after 120ms
Fail-safe mode **
Diagnostic low/high
Unauthorized Mode Entry
** CPU reset after 120ms
EEPROM Error Correcting
(Transparent) Error
no effect
Code ( Hamming correction )
Correction
Environ
&Analog
6ms
x
Diag_Debounce_Thresh
Diag_Debounce_Stepup
n/applicable
Not a diagnostic
n/a immediate
Diagnostic
n/a immediate
Diagnostic
n/a immediate
Diagnostic
n/a.
n/a
immediate Diagnostic
n/a
immediate Diagnostic
n/a
immediate Diagnostic
n/a
RAM March C- 10N Test
Watchdog BIST
Under Voltage Monitoring
SUPPLYMONI =
(MT3VB) OR (MT4VB)
Over Voltage Monitoring
MT7V
BG Loop Diagnostics
ROM 16bit checksum
( continuous )
EEPROM 8 bit CRC Check
(continuous)
Watchdog
( continuous )
DSP Loop Diagnostics
ADC Clipping
ADCCLIP
Virtual Gain Code Out-of-spec
GAINOOS
Virtual Gain Code Saturation
[GAINMIN..GAINMAX]
ADC Monitor (Analog to Digital
Converter)
ADCMONI
Under Voltage Monitoring
SUPPLYMONI =
(MT3VB) OR (MT4VB)
Over Voltage Monitoring
MT7V
Temperature Sensor Monitor
TEMPMONI
MLX90366
Rev 1.2
Digi HW
Environ
&Analog
Digi HW
Digi HW
Digi HW
Digi HW
Page 25 of 34
n/applicable (start-up only)
n/applicable (start-up only)
Datasheet
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MLX90366

Triaxis Position Sensor IC feat. SENT
Hardware Diagnostics ( continuously checked by dedicated Analog circuits )
CPU Reset
Pull down load =>
on recovery
Diagnostic High
Broken VSS
Pull up load =>
Diagnostic High
CPU Reset
Pull down load =>
on recovery
Diagnostic Low
Broken VDD
Pull up load =>
Diagnostic Low
Start-up on Hold
Diagnostic low/high
Resistive Cable Test
MLX90366
Rev 1.2
Page 26 of 34
Environ
n/a immediate
Diagnostic
n/a
immediate Diagnostic
Environ
n/a immediate
Diagnostic
n/a
immediate Diagnostic
Environ
n/a immediate
Diagnostic
n/a
immediate Diagnostic
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09/11/2015
MLX90366

Triaxis Position Sensor IC feat. SENT
16.
Built-in Capacitors and recommended Application Diagrams
Either Vss pin can be used for grounding, but always leave 1 floating.
Built-in capacitors are ceramic multilayer type X8R. The capacitors are specifically suited for high
temperature applications with stable capacitance value (+/- 15%) up to 150 DegC.
The capacitors are assembled using a gluing method instead of soldering to be more reliable towards
thermal/mechanical stress. The maximum rated voltage is 25V.
17. Standard information regarding manufacturability of Melexis
products with different lead pre-forming and soldering/welding
processes
For Dual Mold Package, please refer to the following document (available upon request):
Application Note Hall Sensors in Dual Mold Packages – (Doc#: 390110000001)
For more information on the lead free topic please see quality page at our website:
http://www.melexis.com/quality.aspx
18.
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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19.
Package Information
19.1. DMP-4 – Package Outline Dimensions (POD) – Straight Leads
MLX90366LVS-xxx-250
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19.2. DMP-4 – Package Outline Dimensions (POD) – Trimmed & Formed Leads [1]
MLX90366LVS-xxx-251
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19.3. DMP-4 – Package Outline Dimensions (POD) – Trimmed & Formed Leads [2]
MLX90366LVS-xxx-253
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19.4. DMP-4 - Marking
366ADU2
Mxxxxx
XyXz
yyww
Line 1: MLX project code (e.g. 366ADU2 for
MLX90366LVS-ADU-2xx)
Line 2: Lotnumber
Line 3: Last 4 characters assembly lotnumber
Line 4: 2 digit year code – 2 digit week code
3x 100nF
1x 10nF
Pin 4
Pin 1
MLX90366
Rev 1.2
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19.5. DMP-4 - Sensitive Spot Positioning & Sense direction
MLX90366
Rev 1.2
Magnetic center position
MLX90366LVS-xxx-2xx
Xc
0.23
Yc
3.67
Zc
0.495
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MLX90366 – Reference Angle
The MLX90366 is an absolute angular position sensor but the linearity error (See section 9) does not
include the error linked to the absolute reference 0 Deg (which can be fixed in the application through the
discontinuity point).
MLX90366
Rev 1.2
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20.
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.
© 2015 Melexis N.V. 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:
America:
Phone: +32 1367 0495
E-mail: [email protected]
Phone: +1 248 306 5400
E-mail: [email protected]
ISO/TS 16949 and ISO14001 Certified
Melexis internal document number
Doc# 390109036601 rev.002
MLX90366
Rev 1.2
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09/11/2015